This document discusses activated carbon and its use in purifying alcohol. It describes activated carbon as a porous substance used to absorb impurities. There are three types of pores in activated carbon: micro pores, meso pores, and macro pores. The document explains that the effectiveness of activated carbon for purifying alcohol depends on the combination and distribution of these pore types, as different pore sizes absorb different impurities. It provides guidance on selecting the right activated carbon based on the pore structure.
Pulp and Paper Manufacturing and Treatment Of Waste Water
is About:
What is Fiber?
Lignin?Hemicellouse?
Real Explanation of Photosynthesis?
SEM (Scanning Electronic Microscope) Pictures of Trees
Can Plants Survive in Green Light?
How the Pulp is Produced from The Trees (Video) ?
Can We Use Other Than Trees for Pulp Preparation?
Some Information about Locally Located oldest Paper Mills
How the Waste Water Treated from Industries?
Styrene butadiene rubber (SBR) is a synthetic rubber derived from styrene and butadiene monomers. It can be produced through emulsion polymerization or solution polymerization. SBR has good abrasion resistance and aging stability when protected by additives. Approximately 50% of car tires are made from various types of SBR. It finds applications in tires, shoe soles, gaskets, and chewing gum due to its properties.
Determination of Oxygen in Anhydrous Ammonia
SCOPE AND FIELD OF APPLICATION
This method is suitable for the determination of trace amounts of oxygen in Liquefied anhydrous ammonia.
The trace oxygen analyzer provides for trace oxygen analysis in decade steps ranging from 0 - 10 to 0 - 10,000 ppm v/v (full scale).
The document discusses ways to reduce nitrogen oxide (NOx) emissions from cement plants. It outlines various primary measures cement plants can take including optimizing processes like air levels and burner operations, using low-nitrogen fuels, and installing equipment like low-NOx burners and calciners. Secondary measures like selective non-catalytic reaction and selective catalytic reaction are also mentioned. Charts show the effectiveness of different measures and NOx emission levels from specific plants over time periods. The goal is to control NOx emissions to meet regulatory limits.
The document discusses nitrogen oxide (NOx) control in power plant systems. It covers the sources and formation mechanisms of NOx, including thermal NOx from high-temperature combustion and fuel NOx from organically bound nitrogen in fuels. Control methods aim to reduce combustion temperature like flue gas recirculation or optimize fuel-air ratios to lower oxygen levels. Selective catalytic reduction is mentioned as the most common downstream NOx reduction method using ammonia.
Preparation of catalysts_by_impregnation_methods THOMAS DANIYA
The document summarizes the impregnation method of preparing industrial catalysts. It involves adding catalytically active materials to a support substrate. There are several impregnation techniques described - pore volume impregnation, excess solution impregnation, and reaction precipitation. The method allows for good dispersion of the active phase within the support and concentration of the catalyst. An example process of making a copper oxide-cerium oxide catalyst on an alumina support via two sequential impregnation steps is provided. Potential applications include catalytic converters for exhaust gas pollution reduction. Benefits of impregnation catalysts include lower cost than platinum-based catalysts and stability over a wide temperature range.
Pulp and Paper Manufacturing and Treatment Of Waste Water
is About:
What is Fiber?
Lignin?Hemicellouse?
Real Explanation of Photosynthesis?
SEM (Scanning Electronic Microscope) Pictures of Trees
Can Plants Survive in Green Light?
How the Pulp is Produced from The Trees (Video) ?
Can We Use Other Than Trees for Pulp Preparation?
Some Information about Locally Located oldest Paper Mills
How the Waste Water Treated from Industries?
Styrene butadiene rubber (SBR) is a synthetic rubber derived from styrene and butadiene monomers. It can be produced through emulsion polymerization or solution polymerization. SBR has good abrasion resistance and aging stability when protected by additives. Approximately 50% of car tires are made from various types of SBR. It finds applications in tires, shoe soles, gaskets, and chewing gum due to its properties.
Determination of Oxygen in Anhydrous Ammonia
SCOPE AND FIELD OF APPLICATION
This method is suitable for the determination of trace amounts of oxygen in Liquefied anhydrous ammonia.
The trace oxygen analyzer provides for trace oxygen analysis in decade steps ranging from 0 - 10 to 0 - 10,000 ppm v/v (full scale).
The document discusses ways to reduce nitrogen oxide (NOx) emissions from cement plants. It outlines various primary measures cement plants can take including optimizing processes like air levels and burner operations, using low-nitrogen fuels, and installing equipment like low-NOx burners and calciners. Secondary measures like selective non-catalytic reaction and selective catalytic reaction are also mentioned. Charts show the effectiveness of different measures and NOx emission levels from specific plants over time periods. The goal is to control NOx emissions to meet regulatory limits.
The document discusses nitrogen oxide (NOx) control in power plant systems. It covers the sources and formation mechanisms of NOx, including thermal NOx from high-temperature combustion and fuel NOx from organically bound nitrogen in fuels. Control methods aim to reduce combustion temperature like flue gas recirculation or optimize fuel-air ratios to lower oxygen levels. Selective catalytic reduction is mentioned as the most common downstream NOx reduction method using ammonia.
Preparation of catalysts_by_impregnation_methods THOMAS DANIYA
The document summarizes the impregnation method of preparing industrial catalysts. It involves adding catalytically active materials to a support substrate. There are several impregnation techniques described - pore volume impregnation, excess solution impregnation, and reaction precipitation. The method allows for good dispersion of the active phase within the support and concentration of the catalyst. An example process of making a copper oxide-cerium oxide catalyst on an alumina support via two sequential impregnation steps is provided. Potential applications include catalytic converters for exhaust gas pollution reduction. Benefits of impregnation catalysts include lower cost than platinum-based catalysts and stability over a wide temperature range.
(LTS) Low Temperature Shift Catalyst - Comprehensive OverviewGerard B. Hawkins
The document discusses low temperature shift catalysts used in hydrogen production plants. It describes the purpose of low temperature shift catalysts in further converting carbon monoxide to carbon dioxide to improve hydrogen yield and remove impurities. It then covers the chemistry, typical operating conditions, factors influencing catalyst activity like temperature profile and poisons, and byproduct formation issues. The document promotes the VSG-C111/112 series as superior catalysts, highlighting their resistance to poisons like sulfur and chloride, low methanol byproduct formation, high activity, and strength properties.
Catalyst poisons & fouling mechanisms the impact on catalyst performance Gerard B. Hawkins
Primary Effects
Secondary Effects
Typical Poisons in hydrocarbon processing
Permanent Poisons
- Arsenic, lead, mercury, cadmium…
- Silica, Iron Oxide….
Temporary Poisons
- Sulfur, Chlorides, Carbon
Boiler Feed water impurities
Heavy Metals
Foulants
THE NATURE OF CARBON DEPOSITS FORMED ON CATALYSTS
- CARBON FORMATION
Type A, B, C
- FEEDSTOCK COMPOSITION EFFECTS
COMMERCIAL’ CARBON DEPOSITS
- CARBON BURNING IN AIR
- CARBON REMOVAL BY STEAMING
- CARBON BURN CONTROL METHODS
- CATALYST – REACTION WITH STEAM
- MAXIMUM OXYGEN CONCENTRATION
- TEMPERATURE OF THE CATALYST SURFACE DURING CARBON BURNS
- CONDITIONS TO BURN OFF CARBON COATED CATALYST
- EFFECT OF CARBON FORMATION
Liquid phase alkylation of benzene with-ethyleneLê Thành Phương
This document presents a process design for producing ethyl benzene (EB) through the liquid phase alkylation of benzene and ethylene. Three main EB production methods are discussed: a gas-phase process using zeolite catalysts, a liquid phase process using AlCl3 catalyst, and a liquid phase process using zeolite catalyst in a fixed bed. The document selects the EBOne process, which uses a zeolite catalyst in a fixed bed, as the basis for the process design due to its safer catalyst and moderate operating conditions. The design involves simulating the necessary unit operations to produce EB using HYSYS software. Key aspects of the process, including reaction kinetics, separation systems, energy requirements, costs,
Reformer Tube design principles
- Larsen Miller Plot
- Larsen Miller & Tube Design
- Design Margins - Stress Data Used
- Max Allowable & Design Temperature
- Tube Life
- Effect of Temperature on Life
- Material Types
HK40: 25 Cr / 20 Ni
HP Modified: 25 Cr / 35 Ni + Nb
Microalloy: 25 Cr / 35 Ni + Nb + Ti
- Alloy Developments
- Comparison of Alloys
Manufacturing Technology
- Welds
Failure mechanisms
- Failure Mechanisms - Creep
- Creep Propagation
- Common Failure Modes
- Uncommon Failure Modes
- Failure by Creep
- Creep Rupture - Cross Section
- Failure at Weld
Actions to Take if Tube Fails
- Pigtail Nipping
Inspection techniques
Classification of Problems
- Visual Examination
- Girth Measurement
- Ultrasonic Attenuation
- Radiography
Eddy Current Measurement
LOTIS Tube Inspection
LOTIS Compared to External Inspection
1) Snowman formation occurs when dusty clinker blows back from the cooler into the kiln, creating a cycle that increases dust levels.
2) High secondary air velocities above 5m/s can carry finer dust from the kiln into the burning zone, stealing liquid and creating stickier clinker dust.
3) This dust builds up on the cooler surfaces, forming snowman-like structures, worsened by the presence of alkalis or sulfur that increase melting. Maintaining a short, radiant flame with oxidizing conditions and optimizing air flow can help control clinker dust levels.
This document gives a brief description on defoamer chemicals used in industry. Foaming is a problem in processing industry like, food, paper and pulp, paint and coating, printing, dyeing, oil drilling, boiler steam production, water treatment, waste management, etc.
Distillation is a key separation process used in petroleum refining to separate crude oil into its various components like gasoline, kerosene, and diesel. Crude oil is first desalted and dewatered before being fed to a distillation unit where it is heated and separated based on differences in boiling points into various hydrocarbon fractions. Further refining processes like reforming, cracking, and hydrotreating are used to convert heavier fractions into lighter, more valuable products like gasoline.
This document summarizes the formation and control of sulfur dioxide and other sulfur compounds in Portland cement kiln systems. It discusses how sulfur is introduced from raw materials and fuels and how it is oxidized to SO2 at different temperatures in the kiln. It evaluates several control techniques including inherent removal in rotary kilns, in-line raw mills, process alterations, and SO2 scrubbing technologies. Overall removal efficiencies range from 40-99% for rotary kilns and 50-70% for in-line raw mills. Scrubbing technologies like dry injection, spray dryers, and wet scrubbers can achieve 50-95% sulfur capture depending on the absorbent, temperature, and residence time. The document provides
- W. Matthes presented on laboratory work testing cement paste setting time and mortar strength.
- Methods tested included Vicat needle and penetrometer for setting time, and standard EN and ASTM mortars for strength.
- Factors that influence setting time and strength development include clinker composition, presence of mineral admixtures, and curing conditions. Benchmarking of different cements in both mortar and concrete is important.
5. Screening, Density Scale,Lab Milling Equipment_ May 2016Shantel Breytenbach
The document describes several laboratory testing devices:
1. The Marcy Pulp Density & Specific Gravity Scale measures weight, specific gravity of liquids and pulps, percent solids, and specific gravity of dry solids using interchangeable dials. It eliminates errors from charts and calculations.
2. The MACSALAB 200 Cross Beater Lab Mill is used to crush materials like coal, ores, chemicals and more. Materials are fed into the grinding chamber and pulverized against the chamber lining by fast moving hammers then discharged through screens.
3. The MACSALAB ES-200 Sieve Shaker is recommended for general laboratory sieving including fine particles. It can hold up to 16 test
Ethyl benzene is an organic compound used primarily in the production of styrene. It has a history dating back to the late 1800s but commercial production began in the 1930s. Today it is produced through liquid phase alkylation of benzene and ethylene using zeolite catalysts. Almost all ethyl benzene is used to make styrene, which is then used to produce polystyrene and other plastics. As a flammable liquid, ethyl benzene requires careful handling, storage, and transportation to prevent fires or explosions.
The document summarizes the tannery process, associated wastewater treatment, and impact on public health. It describes the various stages of tanning including soaking, liming, pickling, and tanning. This generates wastewater high in salts, chromium, sulfides, and organic matter. Primary treatment includes screening, equalization, coagulation, and sludge dewatering to remove solids and reduce BOD and COD. Effluent standards vary by country but are often exceeded by tanneries. Pollutants from tanneries like chromium, ammonia, and hydrogen sulfide can cause respiratory illness and dermatitis. Alternative treatment methods are evaluated based on cost, technical criteria, and
The document discusses catalyst preparation methods. It begins by classifying catalysts based on physical state, chemical nature, and the reactions they catalyze. It then describes different types of catalysts like gaseous, liquid, and solid catalysts. Solid catalysts are further classified as bulk catalysts, supported catalysts, and mixed agglomerates. The key steps in catalyst preparation are described, including precipitation, sol-gel process, impregnation, forming operations, and calcination. Different catalytic agents like metallic conductors, semiconductors, and insulators are also explained. The roles of support materials, promoters, and preparation techniques are summarized as well.
Activated carbon is a form of carbon processed to increase its surface area for adsorption. It has micro-pores that adsorb substances via Van der Waals forces. Activated carbon is made from materials like wood and coal. It has a wide range of applications including water treatment, food processing, and gas storage. Carbon nanotubes are also being investigated as catalyst supports due to their strength, conductivity, and adsorption properties.
This document presents the design of a process to produce phthalic anhydride from o-xylene. It includes a literature review on the production process, kinetic data, safety and environmental precautions. Mass and energy balances were developed for the key units: a mixing point, reactor, condenser, and two distillation columns. Process simulation and equipment sizing were performed. The reactor was designed to operate adiabatically at 150°C and 30 bar. The first distillation column was designed to separate o-xylene from other components with a minimum reflux ratio.
Portland cement is produced by heating limestone, clay, and other materials in a kiln to form clinker, which is then ground with gypsum. The key compounds formed are tricalcium silicate (C3S), dicalcium silicate (C2S), tricalcium aluminate (C3A), and tetracalcium aluminoferrite (C4AF). Their proportions can be estimated using Bogue's equations based on the oxide composition measured through chemical analysis. The document provides details on the production process, chemical reactions, composition standards, and example calculations.
Ammonia Synthesis Catalyst Chemistry and Operator TrainingGerard B. Hawkins
The document discusses ammonia synthesis catalysts including their formulation, production, and operation. Key points include:
1) Ammonia synthesis catalysts are typically based on magnetite that is reduced to form a porous iron structure. Promoters like alumina and potash boost activity and stability.
2) Catalyst production involves melting components to control precursor phases before milling to size.
3) The reaction favors high pressure and low temperature. Typical conditions are 350-530°C and 100-600 bar. Temperature and pressure balance kinetics and equilibrium.
The document discusses how to control corrosion of cement kiln shells. It describes how volatile compounds from alternative fuels can cause corrosion by penetrating refractory lining and reaching the shell. Proper refractory selection, installation, and oxidizing kiln conditions can minimize corrosion. The mechanisms of oxidation and sulfidization corrosion are explained. Maintaining good refractory quality with low porosity, proper installation, and controlled process parameters can help reduce shell corrosion.
The Global CCS Institute and USEA co-hosted a briefing on the importance of R&D in advancing energy technologies on June 29 2017. This is the presentation given by Tim Merkel, Director, Research and Development Group at Membrane Technology & Research (MTR)
This document provides information about Aqua Seen, a company that specializes in water treatment. It has over 20 years of experience and has completed almost 1500 projects in Poland and abroad. The company offers design, equipment, and turnkey solutions for drinking water treatment, sewage management, and renewable energy. It has divisions for potable water, equipment, service, and research and development. The document then describes several large water treatment plant modernization and construction projects the company has completed.
(LTS) Low Temperature Shift Catalyst - Comprehensive OverviewGerard B. Hawkins
The document discusses low temperature shift catalysts used in hydrogen production plants. It describes the purpose of low temperature shift catalysts in further converting carbon monoxide to carbon dioxide to improve hydrogen yield and remove impurities. It then covers the chemistry, typical operating conditions, factors influencing catalyst activity like temperature profile and poisons, and byproduct formation issues. The document promotes the VSG-C111/112 series as superior catalysts, highlighting their resistance to poisons like sulfur and chloride, low methanol byproduct formation, high activity, and strength properties.
Catalyst poisons & fouling mechanisms the impact on catalyst performance Gerard B. Hawkins
Primary Effects
Secondary Effects
Typical Poisons in hydrocarbon processing
Permanent Poisons
- Arsenic, lead, mercury, cadmium…
- Silica, Iron Oxide….
Temporary Poisons
- Sulfur, Chlorides, Carbon
Boiler Feed water impurities
Heavy Metals
Foulants
THE NATURE OF CARBON DEPOSITS FORMED ON CATALYSTS
- CARBON FORMATION
Type A, B, C
- FEEDSTOCK COMPOSITION EFFECTS
COMMERCIAL’ CARBON DEPOSITS
- CARBON BURNING IN AIR
- CARBON REMOVAL BY STEAMING
- CARBON BURN CONTROL METHODS
- CATALYST – REACTION WITH STEAM
- MAXIMUM OXYGEN CONCENTRATION
- TEMPERATURE OF THE CATALYST SURFACE DURING CARBON BURNS
- CONDITIONS TO BURN OFF CARBON COATED CATALYST
- EFFECT OF CARBON FORMATION
Liquid phase alkylation of benzene with-ethyleneLê Thành Phương
This document presents a process design for producing ethyl benzene (EB) through the liquid phase alkylation of benzene and ethylene. Three main EB production methods are discussed: a gas-phase process using zeolite catalysts, a liquid phase process using AlCl3 catalyst, and a liquid phase process using zeolite catalyst in a fixed bed. The document selects the EBOne process, which uses a zeolite catalyst in a fixed bed, as the basis for the process design due to its safer catalyst and moderate operating conditions. The design involves simulating the necessary unit operations to produce EB using HYSYS software. Key aspects of the process, including reaction kinetics, separation systems, energy requirements, costs,
Reformer Tube design principles
- Larsen Miller Plot
- Larsen Miller & Tube Design
- Design Margins - Stress Data Used
- Max Allowable & Design Temperature
- Tube Life
- Effect of Temperature on Life
- Material Types
HK40: 25 Cr / 20 Ni
HP Modified: 25 Cr / 35 Ni + Nb
Microalloy: 25 Cr / 35 Ni + Nb + Ti
- Alloy Developments
- Comparison of Alloys
Manufacturing Technology
- Welds
Failure mechanisms
- Failure Mechanisms - Creep
- Creep Propagation
- Common Failure Modes
- Uncommon Failure Modes
- Failure by Creep
- Creep Rupture - Cross Section
- Failure at Weld
Actions to Take if Tube Fails
- Pigtail Nipping
Inspection techniques
Classification of Problems
- Visual Examination
- Girth Measurement
- Ultrasonic Attenuation
- Radiography
Eddy Current Measurement
LOTIS Tube Inspection
LOTIS Compared to External Inspection
1) Snowman formation occurs when dusty clinker blows back from the cooler into the kiln, creating a cycle that increases dust levels.
2) High secondary air velocities above 5m/s can carry finer dust from the kiln into the burning zone, stealing liquid and creating stickier clinker dust.
3) This dust builds up on the cooler surfaces, forming snowman-like structures, worsened by the presence of alkalis or sulfur that increase melting. Maintaining a short, radiant flame with oxidizing conditions and optimizing air flow can help control clinker dust levels.
This document gives a brief description on defoamer chemicals used in industry. Foaming is a problem in processing industry like, food, paper and pulp, paint and coating, printing, dyeing, oil drilling, boiler steam production, water treatment, waste management, etc.
Distillation is a key separation process used in petroleum refining to separate crude oil into its various components like gasoline, kerosene, and diesel. Crude oil is first desalted and dewatered before being fed to a distillation unit where it is heated and separated based on differences in boiling points into various hydrocarbon fractions. Further refining processes like reforming, cracking, and hydrotreating are used to convert heavier fractions into lighter, more valuable products like gasoline.
This document summarizes the formation and control of sulfur dioxide and other sulfur compounds in Portland cement kiln systems. It discusses how sulfur is introduced from raw materials and fuels and how it is oxidized to SO2 at different temperatures in the kiln. It evaluates several control techniques including inherent removal in rotary kilns, in-line raw mills, process alterations, and SO2 scrubbing technologies. Overall removal efficiencies range from 40-99% for rotary kilns and 50-70% for in-line raw mills. Scrubbing technologies like dry injection, spray dryers, and wet scrubbers can achieve 50-95% sulfur capture depending on the absorbent, temperature, and residence time. The document provides
- W. Matthes presented on laboratory work testing cement paste setting time and mortar strength.
- Methods tested included Vicat needle and penetrometer for setting time, and standard EN and ASTM mortars for strength.
- Factors that influence setting time and strength development include clinker composition, presence of mineral admixtures, and curing conditions. Benchmarking of different cements in both mortar and concrete is important.
5. Screening, Density Scale,Lab Milling Equipment_ May 2016Shantel Breytenbach
The document describes several laboratory testing devices:
1. The Marcy Pulp Density & Specific Gravity Scale measures weight, specific gravity of liquids and pulps, percent solids, and specific gravity of dry solids using interchangeable dials. It eliminates errors from charts and calculations.
2. The MACSALAB 200 Cross Beater Lab Mill is used to crush materials like coal, ores, chemicals and more. Materials are fed into the grinding chamber and pulverized against the chamber lining by fast moving hammers then discharged through screens.
3. The MACSALAB ES-200 Sieve Shaker is recommended for general laboratory sieving including fine particles. It can hold up to 16 test
Ethyl benzene is an organic compound used primarily in the production of styrene. It has a history dating back to the late 1800s but commercial production began in the 1930s. Today it is produced through liquid phase alkylation of benzene and ethylene using zeolite catalysts. Almost all ethyl benzene is used to make styrene, which is then used to produce polystyrene and other plastics. As a flammable liquid, ethyl benzene requires careful handling, storage, and transportation to prevent fires or explosions.
The document summarizes the tannery process, associated wastewater treatment, and impact on public health. It describes the various stages of tanning including soaking, liming, pickling, and tanning. This generates wastewater high in salts, chromium, sulfides, and organic matter. Primary treatment includes screening, equalization, coagulation, and sludge dewatering to remove solids and reduce BOD and COD. Effluent standards vary by country but are often exceeded by tanneries. Pollutants from tanneries like chromium, ammonia, and hydrogen sulfide can cause respiratory illness and dermatitis. Alternative treatment methods are evaluated based on cost, technical criteria, and
The document discusses catalyst preparation methods. It begins by classifying catalysts based on physical state, chemical nature, and the reactions they catalyze. It then describes different types of catalysts like gaseous, liquid, and solid catalysts. Solid catalysts are further classified as bulk catalysts, supported catalysts, and mixed agglomerates. The key steps in catalyst preparation are described, including precipitation, sol-gel process, impregnation, forming operations, and calcination. Different catalytic agents like metallic conductors, semiconductors, and insulators are also explained. The roles of support materials, promoters, and preparation techniques are summarized as well.
Activated carbon is a form of carbon processed to increase its surface area for adsorption. It has micro-pores that adsorb substances via Van der Waals forces. Activated carbon is made from materials like wood and coal. It has a wide range of applications including water treatment, food processing, and gas storage. Carbon nanotubes are also being investigated as catalyst supports due to their strength, conductivity, and adsorption properties.
This document presents the design of a process to produce phthalic anhydride from o-xylene. It includes a literature review on the production process, kinetic data, safety and environmental precautions. Mass and energy balances were developed for the key units: a mixing point, reactor, condenser, and two distillation columns. Process simulation and equipment sizing were performed. The reactor was designed to operate adiabatically at 150°C and 30 bar. The first distillation column was designed to separate o-xylene from other components with a minimum reflux ratio.
Portland cement is produced by heating limestone, clay, and other materials in a kiln to form clinker, which is then ground with gypsum. The key compounds formed are tricalcium silicate (C3S), dicalcium silicate (C2S), tricalcium aluminate (C3A), and tetracalcium aluminoferrite (C4AF). Their proportions can be estimated using Bogue's equations based on the oxide composition measured through chemical analysis. The document provides details on the production process, chemical reactions, composition standards, and example calculations.
Ammonia Synthesis Catalyst Chemistry and Operator TrainingGerard B. Hawkins
The document discusses ammonia synthesis catalysts including their formulation, production, and operation. Key points include:
1) Ammonia synthesis catalysts are typically based on magnetite that is reduced to form a porous iron structure. Promoters like alumina and potash boost activity and stability.
2) Catalyst production involves melting components to control precursor phases before milling to size.
3) The reaction favors high pressure and low temperature. Typical conditions are 350-530°C and 100-600 bar. Temperature and pressure balance kinetics and equilibrium.
The document discusses how to control corrosion of cement kiln shells. It describes how volatile compounds from alternative fuels can cause corrosion by penetrating refractory lining and reaching the shell. Proper refractory selection, installation, and oxidizing kiln conditions can minimize corrosion. The mechanisms of oxidation and sulfidization corrosion are explained. Maintaining good refractory quality with low porosity, proper installation, and controlled process parameters can help reduce shell corrosion.
The Global CCS Institute and USEA co-hosted a briefing on the importance of R&D in advancing energy technologies on June 29 2017. This is the presentation given by Tim Merkel, Director, Research and Development Group at Membrane Technology & Research (MTR)
This document provides information about Aqua Seen, a company that specializes in water treatment. It has over 20 years of experience and has completed almost 1500 projects in Poland and abroad. The company offers design, equipment, and turnkey solutions for drinking water treatment, sewage management, and renewable energy. It has divisions for potable water, equipment, service, and research and development. The document then describes several large water treatment plant modernization and construction projects the company has completed.
The document describes new techniques for wastewater management, including filtration methods like media, membrane, and hybrid filtration systems. It also discusses disinfection systems using chlorine, ozone or UV radiation. The techniques aim to remove solid matter through various physical, chemical and biological processes like sedimentation, filtration, and the use of bacteria. Treated water and sludge can then be disposed of safely.
Started to create milestones, we Shree Samarth Engineers marked our presence in the year 2001 and operates in the manufacturing/servicing of Pressure Sand Filters Bed, Activated Carbon Media, Chemical Dosing System, Softeners Unit, Filtration Plant since 11 years. Our quality services/products have always won us many appreciations from our clients. Our spontaneous performance and confident approach in offering the excellent range of Pressure Sand Filters Bed, Activated Carbon Media, Chemical Dosing System, Softeners Unit, Filtration Plant, Activated Carbon Filters that has made us to deepen our roots in the market. We Shree Samarth Engineers breathe with the aim to satisfy our clients with our smart products/services. We are a unit of highly experienced professionals who all contribute best of their potentials to offer high efficiency.
The document discusses various methods for treating and purifying water, including particulate removal processes, filtration, ion exchange, reverse osmosis, and disinfection. It addresses topics like the hydrologic cycle, sources of water pollution, different filter types and materials like activated carbon, membrane construction and fouling issues for reverse osmosis, and the use of ultraviolet light and ozone for disinfection.
Sand filters are the second most common type of pool filter in the US, able to filter particles down to 30-40 microns in size. They operate using a multi-port valve to control the flow of water through the filter tank containing sand or alternative media. Proper maintenance such as backwashing is important when the pressure increases above normal levels to remove trapped debris from the sand and ensure effective filtering.
The document discusses effluent treatment plants (ETPs), which are necessary for treating wastewater from industries like textile processing that generate large amounts of pollution. It provides an overview of the various processes involved in ETPs, including primary treatment to remove solids, secondary treatment using biological processes, and tertiary treatment to further clean the water before discharge or reuse. The document outlines the key stages and treatments at both small and large scale ETPs, and addresses some common questions about effluent treatment.
Activated carbon is a form of carbon processed to be riddled with small, low-volume pores that increase the surface area available for adsorption or chemical reactions.
Slow sand filtration is an old water treatment technology that is not fully understood. Particles are removed from water as it passes slowly through a bed of sand, but the mechanisms were unknown. Research has found that both biological and physical-chemical processes contribute to particle removal. Biologically, small particles (<2um) are removed as microorganisms in the filter feed on bacteria. Larger particles are removed through physical-chemical attachment to other particles that have built up in the filter bed and cake layer. Ongoing research continues to investigate the mystery compounds and processes involved in slow sand filtration.
New Technologies for Water Purification, Ion Exchange(India) LimitedIndia Water Portal
Presentation at the Seminar on Packaged Water Industry in India which was organised by Confederation of Indian Industry (CII) on 30th June 2009.
To know more click on the link http://indiawaterportal.org/post/6790
We thank CII and the presenters for giving us permission to make these presentations available online.
The document discusses industrial hazards and safety measures. It covers types of industrial hazards like chemical, dust explosion, fire, and electrical hazards. It also discusses accident reduction approaches like the actuarial approach and safety education campaigns. Control measures for different hazards are mentioned, like filters and cyclones for dust explosions, fireproof construction and sprinklers for fire hazards, and personal protective equipment for various exposures. The importance of a safety program and its advantages are highlighted.
Amyloid–carbon hybrid membranes for universal water purification Antonio E. Serrano
This document summarizes a study on using amyloid-carbon hybrid membranes for water purification. The membranes consist of amyloid protein fibrils assembled onto porous activated carbon. They are able to remove various heavy metal ions and radioactive waste from water 3 to 5 orders of magnitude more efficiently than current technologies. The membranes maintain high removal efficiency even after multiple reuse cycles and can purify water contaminated with several pollutants simultaneously. Additionally, valuable metals captured by the membranes can be recovered as nanoparticles or thin films.
1) Water treatment involves ensuring a safe and clean drinking water supply. It requires identifying a water source and protecting it from contamination through appropriate treatment and distribution.
2) Conventional drinking water treatment typically includes aeration, coagulation/flocculation, sedimentation, filtration and disinfection. It aims to remove microbes, particles, dissolved solids and other pollutants.
3) The key processes involve adding coagulants to neutralize particle charges, forming flocs for removal via sedimentation and filtration. Chlorine is commonly used for disinfection but produces disinfection byproducts, so alternatives like chloramines and ozone are also used.
The document discusses various aspects of water treatment processes. It describes the typical steps in conventional surface water treatment, which include screening, coagulation, flocculation, sedimentation, filtration, and disinfection. It also discusses other treatment methods like softening, activated carbon treatment for removing synthetic organic chemicals, and onsite treatment systems. The key steps in water treatment are aimed at removing suspended particles, pathogens, and other contaminants to make water safe for drinking and other uses.
The document summarizes various stages of wastewater treatment processes. It discusses preliminary treatment which removes solids, grit, and grease. Primary treatment uses sedimentation to remove 60% of suspended solids. Secondary treatment uses biological processes like activated sludge and oxidation ditches to remove organic matter. Tertiary treatment further removes nutrients and particles through processes like filtration and disinfection. The document provides details on the treatment units and processes involved at each stage of wastewater treatment.
BIOMASS AS FUEL FOR REHEATING FURNACES FOCUSING ON IMPURITIES. (Emilia, Sir...Siri Andersson
This document summarizes research on using biomass-based fuels in steel reheating furnaces. It discusses how alkali metals in syngas from biomass gasification can affect steel. The document reviews literature on impurities in biomass and syngas, as well as methods for syngas cleaning. An experiment measured tar content and particle levels in syngas from a gasifier. While biomass fuels could potentially replace fossil fuels, pretreatment is important due to impurities like alkali metals that can impact the steel and furnace equipment if not controlled.
Environmental comparison of the use of anaerobic digestion to produce energy ...Alex Marques
This document analyzes the environmental impacts of using anaerobic digestion to produce different end products like methane, hydrogen, and acetic acid, compared to their conventional production processes. It finds that anaerobic digestion of food waste to produce biomethane has the greatest environmental benefits in terms of reducing CO2 emissions and fossil fuel consumption per kg of food waste processed compared to other end products. Biomethane production through anaerobic digestion saves more greenhouse gases and fossil fuels than producing electricity, hydrogen, or acetic acid from the same amount of food waste.
An alternative process for energy recovery and disposal of mswZahid Latif
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1. Activated carbon
for
purification of alcohol
- and some useful distillation tips -
Meso pores
Macro pores
Micro pores
by Gert Strand
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 1
4. ACTIVATED CARBON
FOR
PURIFICATION OF ALCOHOL
What is activated carbon?
Activated carbon is the common term used for a group of absorbing substances of
crystalline form, having large internal pore structures that make the carbon more
absorbent. Activated carbon is manufactured according to the Ostreijkos patents of 1900
and 1902. Every year, approximately one hundred fifty thousand metric tons of pulverized
activated carbon are manufactured, together with one hundred fifty thousand metric tons
of granules and thirty thousand metric tons of pellets/rods. Many different materials can
be activated (wood, plastic, stone and synthetic materials) without actually turning them
into carbon, and one can still get the same effect.
Activated carbon is the most popular and the cheapest material used in purification of
alcohol, and steam-activated carbon is derived from natural raw materials. Much of
activated carbon is regenerated (cleaning/desorption) and is used hundreds, or even
thousands, of times.
Carbon is made from a variety of raw materials that are heated and further treated.
During this treatment, some parts turn to gas and leave pores behind. There are
hundreds of varieties of carbon on the market, but only a few are suitable for the
purification of alcohol. Some types of carbon make the alcohol worse than before filtering
- the reason for this is explained further on in this document.
We often speak of the absorption surface of carbon, which can vary from 400-1600 sq.
meter per gram, as a measure of the effectiveness of carbon. This is incorrect. The
effectiveness of carbon depends on its ability to absorb a certain substance or
substances, depending on the chemical and physical properties that carbon possesses.
Activated carbon can be manufactured for different purposes.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 4
5. What is important for the purification of alcohol as
regards carbon pores:
1. The size of the pores in the carbon at the molecule level
2. What use one makes of the different carbon pores
3. How the different types of carbon pores are distributed
Carbon pores consist of:
1. Micro pores with a radius of less than 1 nm (small pores)
Meso pores
Macro pores
Micro pores
2. Meso pores with a radius of 1-25 nm (medium pores)
3. Macro pores with a radius larger than 25 nm (large pores)
Large pores are used for the transport of liquid through the carbon, and absorption
occurs in the medium and small pores. Pores are formed during the manufacturing
process, when the carbon is activated. The activation basically means that pores are
created in a non-porous material by means of chemical reactions.
There are two different methods for this and they produce totally different pore structures:
1. Chemical activation
2. Activation by steam
The large macro pores act as channels through the carbon to the meso- and micro
pores. Granular activated carbon always has macro pores, but in powdered activated
carbon often no macro pores are to be found, since after grinding, the carbon consists of
very small particles.
High and Low activated carbon
It has become standard practice to describe the level of activity in the carbon by the
quantity of the carbon that has become gaseous and left behind empty spaces (the
pores). Thus, a high activated carbon is the one with the most empty space. Such carbon
has many meso pores and macro pores. It can have so many large meso pores (12-25
nm) and a large quantity of macro pores that it is not suitable for purification of alcohol.
That a carbon is high activated is no guarantee of its quality or a measure of its
effectiveness.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 5
6. Pores in chemically activated carbon
Chemical activation is principally used for the activation of wood-based activated carbon
and activated carbon made from stones, e.g., olive stones. This differs from steam
activation in that carbonification and activation occur simultaneously. The raw material,
usually wood chips, is mixed with an activating and dehydrating substance, usually
phosphoric acid or zinc chloride. The activation takes place at a low temperature: 500°C
is the norm, but sometimes it can go up to 800°C. The phosphoric acid causes the wood
to swell and open its cellulose structure. During the activation, the phosphoric acid acts
as a stabilizer and ensures that the carbon does not collapse again. The result is a very
porous activated carbon full of phosphoric acid. This is later washed out and re-used in
the next production.
As a result of the manufacturing process, no “chips” (crystalline plates) are to be found in
this carbon. Instead, the carbon acquires a very open pore structure, which is ideal for
the absorption of large molecules, e.g., in the clarification of liquids. As a rule, this carbon
is ground down to powdered carbon.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 6
7. Steam activated carbon
Steam activation is used throughout for the activation of carbon made from peat, coal,
coconut shells, lignite, anthracite, or wood. First, the raw material is converted into carbon
by heating. When coal is used as the raw material in steam activation, it always consists
of small graphic-like plates, rather like potato crisps. The crisps are flat or a little curved,
just like potato crisps, 0.35 nm thick and a few nm in width and length. The crisps are in
disarray, as in a bag of potato crisps.
Water steam +130°C is then blown in at a coal temperature of approx. 1000°C. Some of
the crisps (“in the bag”) become gas and leave pores (empty space) behind. The form this
takes depends largely on the raw material used. A hard material, like coconut shell,
leaves almost nothing but micro pores, while a soft material like peat always get many
meso pores as well.
Short activation period, Medium activation period,
many micro pores. many meso pores.
Long activation period, many
large meso- and macro pores.
If we continue for a long period to blow in more steam, more and more crisps turn to gas
and leave empty spaces (pores) behind. First we get micro pores. As the process
continues, the surrounding crisps also turn to gas and the pores develop into meso pores.
If we continue still further, we get a macro pore. This is usually already found in the
structure of the raw material, so we do not need to make more. Wood, peat, and coconut
shell have definite cellular structures that are maintained throughout the entire activation
process.
.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 7
8. Re-formed activated carbon (compressed under high pressure) is also manufactured,
often as small pellets a few mm long. Powdered charcoal is mixed with a binding agent
and compressed under high pressure. Here, the macro pores are formed in the cracks
between the powder particles. This type of activated carbon is not good for alcohol
purification: the pellets are too big, the contact surface is too small, and the contact time
is too short.
Ash content and after-treatment of activated carbon
The ash content of activated carbon is a measure of the mineral content (Ca, Mg, Si, Fe,
salts, etc.) left in the carbon after the manufacturing process. We are only interested in
the soluble (in water and alcohol) substances that remain. We don’t want to drink them,
and they often leave a deposit in the alcohol. Therefore, activated carbon used for
purification of water, alcohol, and other foodstuffs is cleaned with acid, often followed by
water, to get rid of most of these substances.
But - all this carbon is meant to be used in carbon beds that are started up in the
correct way. This includes wetting and washing (or rinsing) the carbon. No carbon bed in
an industrial filter is started unless the carbon has been saturated for 24 hours and
thereafter rinsed for some hours. In this way all the remaining soluble substances are
washed out.
The amateur distiller, who often pours dry carbon into a pipe and then directly filters the
alcohol through it, releases the substances from the carbon and then drinks them.
Carbon made from coconut shells usually leaves a white deposit in the alcohol. The
carbon almost exclusively contains micro pores and is difficult to clean: hence the
deposits. If you start up the carbon in the way recommended here, this problem will
disappear by itself. In difficult cases an extra 10 liters of water is filtered through the
carbon bed before alcohol is filtered.
Effectiveness of purification and pore size
Only a small part of the carbon’s absorption surface is such that impurities can get stuck
in them. The largest surface area is made up of micro pores, normally 90-98%. One to
ten percent are meso pores and ca. 1% are macro pores. Many of the impurities we want
to separate from the alcohol have molecules 2-10 nm in size, and are too large to be
caught in the micro pores. We also need meso pores. Ideally, the pores in the carbon
are slightly larger than the impurities that are to be caught in them. Smaller pores are not
found, and there are few larger pores.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 8
9. Pore structure depends on raw materials used
Activated carbon made from peat has both meso- and micro pores. In the manufacturing
process it is possible to control the distribution of meso- and micro pores and get many
meso pores for a multipurpose activated carbon. Even pulverized peat carbon contains
meso pores.
Activated carbon made from mined stone coal also has both micro- and meso pores and
also has a multipurpose character. Some of the most popular coal carbons on the
market have 0.4-1.4 mm grains. An increasingly popular newcomer is coal carbon with
smaller grains: 0.4-0.85 mm.
Activated carbon based on lignite has many meso pores 1-4 nm in size, along with larger
meso pores with easy accessibility, also in pulverized form.
Activated carbon based on coconut shell has only micro pores throughout, less than 1
nm in size. If you purify alcohol (where many impurities are between 2-10 nm) with
coconut carbon, you soon clog up the entrances to the micro pores, with the result that
you cannot use the carbon to its fullest capacity. However, it can still be successful, since
coconut carbon often has 2-3 times the ability of other carbons.
Chemically activated carbon is extremely porous, with many micro- and meso pores.
Compared with steam-activated carbon, chemically activated carbon has a surface that
takes in less liquid and has a more negative charge. This reduces the effect in the
purification of alcohol.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 9
10. Best pore combination for the purification of home-distilled alcohol
Several activated carbons are available for perfect purification on an industrial scale. This
is because the alcohol is filtered from below upward and the contact time can be
controlled by a slow flow-through speed. The amateur distiller filters downward from
above, a process that is usually too fast for the carbon purification process.
So a simple peat carbon can be as good as - or even better than - a significantly better
coal carbon. It depends more on how small one can get the granules. A coconut carbon
of 0.4-0.85 mm, which is almost without meso pores, can do a fantastic job. The
impurities are caught between the grains and in the approaches to the micro pores -
because the filtration is slow. Likewise, a peat carbon (0.25-1 mm) can work better
than a significantly “better” carbon.
Peat carbon usually has a surface of approx. 750 sq. meter / g, weighs half of, and can
purify better than twice as much “good” carbon. This occurs because of slow filtering
(longer contact time), a large contact surface, and also because there are many meso
pores in peat carbon. On the other hand, it is not as good for regeneration in repeated
use, as it is easily broken. Harder carbons, like stone carbon, are better for
regeneration.
There is no obvious carbon for the amateur’s use. One can choose a carbon with 0.4-
0.85 mm grain, or mix 2-3 varieties. The tried and tested mix is that of stone carbon and
peat carbon. With Prestige activated stone carbon, 0.4-1.4 mm, the quality is consistent.
It is a reliable carbon, but the grains are large, 0.4-1.4 mm, so it does not always have
enough time to be 100% effective. Peat carbon has smaller grains and many meso
pores, giving slow filtration. It is also popular to mix coal carbon 0.4-1.4 mm and a coal
carbon that has smaller grains, 0.4-0.85 mm.
Lately, many people have started to use stone carbon only, 0.4-0.85 mm. As it is a coal
carbon, it has both micro- and meso pores, and the small granules make this carbon
preferable. In terms of quality, the Prestige activated carbons found at www.partyman.se
are the best. Here one can choose between the leading products’ qualities. Prestige
activated carbons are useful as they set the standard and can be used to compare and
evaluate other brands. The first thing to check when a carbon does not work is its ability
to purify alcohol. With a Prestige carbon one always knows it works.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 10
11. Problems with quality
There are large numbers of quality problems with activated carbon. The most common
problem is the deposit in the alcohol. This is typical of coconut carbon. One time it’s
fantastically good, the next time the carbon leaves a deposit. Usually this means that the
manufacturer has not given the carbon a proper acid washing. If this is not done properly,
the carbon leaves a deposit; next time there is no deposit, so the washing has been done
correctly.
You must wash out the substances from the carbon remaining from the manufacturing
process: they are not carbon, and have not turned to gas and left the carbon during the
manufacturing process. When the carbon leaves a deposit (not to be confused with the
chalky deposit from the “too hard” water in which the alcohol was sometimes diluted), it is
these substances (the salts) that are deposited. They get mixed in with the alcohol and
later begin to separate as white particles.
Another common problem is the poor sifting of small-grained carbon. The powder is not
properly sifted away and the filtration stops. Similarly, there may be too few small
granules, speeding up the filtration, thus the carbon does not manage complete
absorption. The same happens if granules too large in size are chosen. For example, 1-3
mm granules will not work at all.
Another quality problem is that the sales person has no notion of what she/he is selling to
you. They sometimes tell you that “this” is a wood carbon – when it’s a peat carbon. The
carbon is re-packaged and the label information is not consistent with the content. One
brand can be bought in two types with exactly the same content information, one
manufactured in Europe, the other in China. The European carbon is far superior, despite
the fact that they should be exactly the same.
Worst of all are ignorant dealers, who think that all activated carbon can be used for
purification of alcohol. This is not the case. First and foremost it must be a pure (food
grade) activated carbon for foodstuffs, like drinking water or alcohol. Instead they sell
carbon meant for air or gas filtering. This type of carbon has not been rinsed after
manufacture, and there are many undesirable substances in the alcohol, which then must
be discarded. If the carbon is chemically activated, one gets phosphoric acid or other
chemicals.
Some types of carbon are made from byproducts like oil, bone, animal carcasses and
other material, which cannot be used for food-grade carbon. Many of these carbons give
the alcohol a worse taste than before purification (often a gunpowder taste). It is a direct
health hazard.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 11
12. Does all home-distilled pure alcohol require purification with activated carbon?
Yes. Even if one makes equilibrated distillation, collects pure 95% body only, there will be
traces from the fore shots and the head in the alcohol. Books and experts might tell you
this is not so, but it is easy to prove: regenerate the carbon in an oven and smell the
vapor.
Purification with activated carbon
Activated carbon as a means of purification of alcohol is a very effective natural product.
It is also cheap, and the carbon can be recycled and used again. It is the world’s best-
known medium for purification of water and alcohol. The fantastic properties of activated
carbon allow us to trap poisons, creosotes, heavy metals, insecticides, bad smells and
tastes, chemical substances, fusel oils and impurities, or undesirable substances in both
liquid and gases.
Activated carbon works when ordinary physical filtering (using a sieve, filter paper and
filter pads, and sand) cannot separate a particular substance. Activated carbon works by
absorbing impurities into its pores. Absorption happens through cooperation of the
carbon’s enormous adsorptive surface, including its weak electrostatic charges (known
as Van der Waals forces, named after the scientist who studied them), together with the
distribution of pore sizes (micro-, meso-, and macro pores), and the construction of the
pores surfaces (called cohesion forces). The carbon pores become saturated with
impurities, attaching even to the outside of the carbon.
What happens when carbon adsorbs impurities?
Absorption occurs when organic impurities are bound inside the carbon pores. This
happens when the pores are marginally larger than the impurities (molecules) that they
bind.
There are 2 kinds of absorption, physical and chemical
Physical absorption happens when the impurities are bound in the pores and on the
surface of the carbon by means of Van der Waals electrostatic forces, making the carbon
act as a magnet. The impurities on the outside of the carbon are loosely attached, like
oversize molecules that have been trapped in the opening of smaller pores.
Chemical absorption is the union of impurities with other substances on the surface of
the carbon pores. This is a powerful absorption. The chemical substances present on the
pore surface depend on the raw material used, activation method, and after-treatment.
Three available forms of activated carbon
1. Pulverized carbon
2. Granulated carbon
3. Reformed (under high pressure) carbon, usually pellets
Purification ability depends on many things, including:
• Which carbon is used
• The surface of the carbon in sq. meters per gram
• Pore structure (distribution of micro-, meso- and macro pores)
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 12
13. The substances that will be absorbed depend on:
• The size of the molecules in the impurities (they must be smaller than the carbon
pores)
• The density of the impurities
• The amount of impurities in the alcohol
• The boiling point of the impurities
The impurities must be small enough to fit in the carbon pores. An impurity with a higher
boiling point is more easily absorbed, and adheres better than one with a lower boiling
point. If the carbon becomes saturated, an impurity with a higher boiling point can eject a
lighter impurity and take its place. This happens most easily on the carbon surface, where
the impurities are loosely attached, but can even happen inside the carbon pores. This is
why we never filter the same alcohol more than once through the pipe: the result would
be worse.
Temperature
Room temperature works well, whereas purification in cold temperatures works less
effectively, or not at all.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 13
14. Purification methods
1. Using pulverized carbon, which is sludge in the alcohol
2. Filtering the alcohol through granulated activated carbon
Pulverized activated carbon
Pulverized activated carbon is not 100% effective in purification of alcohol. If you want a
really pure alcohol, you must use a tube filled with granulated activated carbon. But it is
helpful to pre-treat the alcohol with pulverized activated carbon before ordinary
purification. It is done as follows:
1. Mix 4 grams pulverized carbon per liter of alcohol.
2. Pour straight into the alcohol.
3. Let it stand at least 24 hours.
NOTE: During this time, the mixture should be shaken at least four times.
4. Let the mixture clear for 24 hours or more, during which time the sediment sinks to
the bottom and the alcohol clears.
5. Now siphon off the alcohol: the sediment is filtered.
6. Filter the alcohol in the usual way in a pipe filled with granulated activated carbon.
Since the alcohol is already somewhat purified, the granules can work more
easily.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 14
15. Granulated activated carbon
Granulated activated carbon is used in thick layers, usually between 1.5-2.5 meters
where the filtering takes place through the carbon. Inside the carbon, the alcohol runs
through the macro pores in the granules. The layer is constructed by filling a pipe with
activated carbon. For easily purified liquids, like water, a layer of 5-10 cm should be
enough. Alcohol normally needs 1.5 meters. It does not matter if the layer (the length of
pipe used) is higher, but if it is too thin, then purification will not take place. The pipe
must be at least 38 mm in diameter otherwise a “wall effect” will be created and the
alcohol runs past the carbon along the wall, without being purified.
For the filtering to really take place in the carbon, the pipe must be free from air. This
means that the purification must take place in one continuous flow. The pipe must not be
allowed to run dry. The carbon must also be saturated so that the alcohol immediately
runs through the carbon. Neither should any channels be allowed to form in the carbon
filled in the pipe. This will happen if you pour dry carbon into the pipe and then in the
alcohol. Channels are formed in the carbon, through which the alcohol can escape
unpurified, as in the film of air between the carbon granules. The carbon bed must be
correctly started.
When water or alcohol is filtered through carbon, the first thing to happen is that the
soluble substances left in the pores from manufacturing are dissolved. These are the
substances that have not become gas and evaporated, and have not been rinsed out
after manufacturing. It would be too expensive to completely rid the carbon of the
substances. All industrial filters are started up despite this, and the carbon is rinsed
through before use. Everyone who works with activated carbon knows that these
substances are present in the carbon.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 15
16. The substances (salts) are easiest described as soap-like. When these substances are
dissolved, the pH balance rises from 7 to nearly 10, and the carbon will not be as
effective again until the pH balance has been restored to that of water or alcohol, approx.
pH7 (neutral). Before the carbon is used for purification, these substances must be
washed or rinsed away:
1. Before pouring the carbon into the pipe, mix the carbon (stirring vigorously) with 2-
3 times as much hot or boiling water in a stainless steel saucepan.
2. Discard the surplus water and repeat the process 4-5 times, ensuring that all
soluble substances are dissolved away from the carbon.
3. Leave to stand for 24 hours, giving the carbon time to soak up more water.
4. Again, pour in hot or boiling water, stir and discard the surplus water. Attach 2-3
filter papers to the pipe and fill it with warm water.
5. Pour the saturated carbon into the pipe in such a way that it always remains in
the water and all air is driven out.
6. Tap the pipe to make sure the carbon is properly settled and packed (positioned).
7. Filter at least 2-5 liters of water through the pipe, and fill up with alcohol before
the water has run through the funnel, making sure the pipe does not run dry. If
you let the funnel run dry by mistake, filter another 4-5 liters of warm water to get
rid of all the air, and continue with alcohol before the last of the water has left the
funnel. In this way the carbon is started up and no air remains in the pipe. The
air film between and inside granules disappears.
Filtration must be continuous; the pipe must not be allowed to run dry. It is best
to have a large funnel or container attached so that you don’t have to keep filling
all the time. It is all too easy to forget a filling and let air into the tube.
8. Lastly, pour a liter of water through the pipe to get all the alcohol out.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 16
17. A filter bed of granulated activated carbon
Activated carbon with both micro- and meso pores is needed.
The tube can be filled with several kinds of activated carbon, mixed or separately in
layers. It is very common to use one carbon only. Activated stone carbon is the most
popular.
As regards the filter bed, there are two things that can strongly affect the absorption. The
smaller the carbon grains (the granulation) we have in the carbon, the greater the
increase in the speed of diffusion (speed of passage / spread through the carbon) so that
a more rapid contact takes place both outside and inside the carbon. With granules or
pellets of 1-3 mm or larger, there is almost no contact, and impurities do not reach the
meso- or micro pores. It does not work. But exactly the same carbon with a finer
granulation works well.
What we want are grains as small as possible. But if the grains are too small, a blockage
will occur in the pipe’s carbon bed and no filtration will take place. Soft carbon from peat
or wood is usually 0.25-1 mm in size, and harder varieties from coal or coconut shell
around 0.4-0.85 mm. These are very good, suitable grain sizes, giving the alcohol large
contact surface with the carbon.
The quality of activated carbon is presently so varied that varieties of carbon with larger
grains are usually preferred e.g., 0.4-1.4 mm, to ensure faster filtration. That way, we
know it will work - if not perfectly, at least well.
The second matter influencing the absorption is the speed of filtration. This is measured
in Bed volume per hour (HSV, Hourly Space Velocity), i.e., the quantity of purified alcohol
per hour in relation to the volume of the pipe. The volume is easiest measured by filling
the pipe with water.
Bed volume per hour (HSV) is usually around 0.25 (very, very slow) when purifying
alcohol, while water is usually purified at 2-3 HSV. For a pipe holding 1.7 liters, the
maximum purification occurs at 4 dl per hour if the pipe is approx. 40 mm wide and the
carbon grain 0.4-1.4 mm in size. If the filtering speed is higher, the carbon sometimes
cannot manage proper purification. There are only three ways to speed this up:
1. A wider pipe
2. A longer pipe
3. Smaller carbon grains
It is not possible to have a pipe narrower than 38 mm, because this would create a “wall
effect” in the carbon bed, where impurities escape filtration along the wall of the pipe. If
we increase the width of the pipe, the alcohol volume per hour is increased without
increasing the flow speed. Within the alcohol industry this filter is over 1 meter wide and
pumping the alcohol through the carbon bed from below at 0.25 HSV regulates the HSV.
Method comparison
Using the method I describe and a Prestige activated carbon or another carbon of the
same capacity, one can often filtrate much faster then 0.25 HSV.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 17
18. To describe how good this “pre-wetting” method works is easy. To purify 5 liters of
alcohol 40-50% one normally needs 1 tube 40 mm x 1.5 meter, then one more to take the
last 10% volatiles that remain (this can be used again next time as first filtration).
With the pre-wetting method, the same can be done in one filtration in a 1-meter tube,
sometimes shorter.
Consumed Used activated Used activated Used activated
zone carbon carbon carbon
Purification
zone (MTZ)
Purification
Unused activated zone (MTZ)
carbon Purification
Unused activated
zone (MTZ)
carbon
In the purification process, three zones are formed in the carbon bed (the pipe). At the
top, nearest to where the unpurified alcohol is poured in, is a zone known as the
consumed zone.
Then comes a zone where the carbon is working and absorption of impurities is constant.
This is the Purification Zone (MTZ).
After the MTZ zone, furthest down in the pipe, is a zone with activated carbon, which has
not yet caught any impurities: unconsummated carbon.
During the purification process, the consumed zone and the purification zone will move
farther and farther down the pipe until the unconsummated zone comes to an end. When
this happens, all remaining impurities will pass through the bed and the alcohol filtration
ceases.
Absorption occurs in the MTZ. The MTZ should be as short as possible. The larger the
carbon grains (the smaller the contact surface) and the faster the speed of filtration
(HSV), the longer the MTZ is. If the grains are 2-3 mm, the MTZ becomes longer that the
pipe, and purification does not take place.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 18
19. The MTZ can be shortened by:
1. Using smaller granules, which gives greater contact surface, e.g., 0.4-0.85 mm.
2. A slower filtration speed (HSV), to give longer contact time.
The filtration speed can be controlled by:
1. Selecting the carbon grain size
2. Packing the carbon in the pipe
3. Impeding the flow
If you are using carbon with a larger grain size, e.g., 0.4-1.4 mm, change to one that is
smaller. Tap on the pipe to pack as much carbon in as possible. Be careful not to pack
the peat carbon (0.25-1 mm) too hard, or it will block the pipe.
Impeding it mechanically can also slow the rate of speed. This has to take place at the
end of the pipe, never at the top, or you would get air in the pipe. You can apply more or
denser filter papers, or build and attach a tap or similar device. A rubber bung with a
length of tubing and an aquarium tap is one example. You must use food-grade materials
with alcohol tolerance, which do not give off-flavors to the alcohol for the impeding
process.
A short MTZ means you can purify larger volumes through the carbon. If you cannot get a
suitably short MTZ, you must extend the pipe.
Fast
filtration
Filtration speed (bed volume/hour, HSV)
Slow
filtration
Length of carbon bed (pipe)
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 19
20. Recycling activated carbon.
If you remove the impurities in the used activated carbon, it can be re-used. You can
recover up to 80% of its effectiveness, which in practice is 100%, since one seldom uses
the carbon to its limit. In theory this can be done as many times as you like. If the carbon
is soft (e.g., peat carbon will degenerate with recycling), the grains become smaller every
time. Hard varieties, like coconut or stone coal keep significantly better, and can be
recycled hundreds of times.
There are two ways to recycle activated carbon:
1. With heat (thermal recycling)
2. With steam (steam recycling)
Recycling with heat within the industry is done as follows:
1. The carbon is dried.
2. It is then pre-heated so that the impurities in the carbon pores are carbonized.
3. The carbon is reactivated around 700-1000°C, when the carbonized impurities turn
into gas and escape from the carbon. This is done in an oxygen-free environment
to ensure that the carbon does not ignite. In this way, the pores become empty
once again and the carbon can be reused.
It is not unusual for amateur distillers in some countries to heat recycle their activated
carbon. It is done as follows:
Note: the carbon contains mostly fusel oils whose highest boiling point is 138°C. Fusel
oils are higher alcohols like amyl, butyl and propyl alcohols and their vapor is
flammable.
1. Begin by pouring the carbon into a sieve and rinsing it with hot water from the tap.
If the carbon grains are 0.4-0.85 mm, they will go right through an ordinary kitchen
sieve when rinsed, so you must get a sieve with a finer mesh or omit this step
entirely.
2. Then, boil the carbon in water for 10-15 minutes, to dissolve some of the higher
alcohols (already it has a 15-20% regeneration). Boil as long as it smells. Repeat
if needed.
3. The carbon is then dried in a deep baking dish or roasting tray. When the carbon
has dried, it is placed in an electric oven. Note: keep the kitchen fan on and
the window partly open, as the vapor can be flammable.
4. Turn the oven on to 140°C or 150°C and heat up the carbon for 2-3 hours.
5. Turn the oven off and let the carbon cool down - now it is ready to be used
again.
Remember that the impurities leaving the carbon when it is heated have a very bad
smell. Also note that the danger of recycling carbon in the oven is that it can ignite.
Carbon made from wood or peat ignites at approx. 200°C and stone carbon at approx.
400°C. Stone carbon can sometimes be recycled in the oven at 300-350°C if one wants
to do so.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 20
21. Recycling with steam is common in the alcohol industry and is done in the following
manner:
1. The filter is back-flushed with hot water. This is done downward from above, since
these carbon filters always works upward from below.
2. After that, the steam is connected and forced through the carbon. This too is done
downward from above. The steam is 120-130°C and very soon the carbon is
heated to the same temperature. All fusel oils and impurities are flushed out of the
carbon pores.
3. Finally the carbon is back-flushed and is ready for use again.
I don’t know of any amateurs who recycle with steam. If you are distilling your own
alcohol and recycling the carbon with heat or steam, please drop me, Gert Strand, an e-
mail and tell me of your experience (mailto: strand@partyman.se).
The recycling power of steam is very high, in fact the steam from a kettle is enough to
recycle activated carbon. It is not impossible that in the future we will be able to connect
an appliance to the still or a steam cleaner, and recycle the carbon this way. There are
steam cleaners on the market, to buy or rent, with which you can steam clean walls,
floors, houses and similar, in an environmentally friendly way, totally without chemicals.
Filling a large sieve with carbon in a layer of 5-10 cm deep and then blowing it clean with
the steam from a steam cleaner shouldn’t be too difficult. The steam from a good cleaner
is 145°C, with a pressure of 4.5 bar, and the cleaning process can be left unattended for
an hour or longer. The water dripping from the bottom of the sieve can be tasted. When
the carbon is clean the water will taste like water. Send me an e-mail –
mailto:strand@partyman.se – if you have tried this, with photos if possible.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 21
22. Effectiveness
The information in this document is intended for use in countries where home distillation
is legal. Note: Home distillation is prohibited in many countries. It is the responsibility of
the reader to abide by the law in his/her home country. However, many countries also
have freedom of information, which allows reading and writing on the subject. Here is the
information on the effectiveness of high-quality activated carbon:
Activated carbon is more effective if high layers of granules are used. Fill a tube with
granulated carbon. Normally a 1.5-meter-long tube with a 40-mm diameter is used.
Filtration should be as slow as possible, without actually being blocked or stopped. The
alcohol must flow through the carbon granules if the purification is to be as effective as
possible. Make sure no alcohol bypasses the carbon, and make sure the tube is free
from air.
Effectiveness can be increased significantly
Increase the purification effect of carbon by 100%
AC
T
CA IVAT Hot
RB E
ON D
1. Pour the carbon into a stainless steel saucepan and add at least twice as much
hot or boiling water.
Stir with a large spoon and allow the carbon to sink to the bottom of the
saucepan before discarding the surplus water. Repeat this process 4-5 times so
that all soluble substances in the carbon pores are washed out and it is saturated
with water.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 22
23. 0
H2
Picture A Picture B Picture C
2. Attach 2-3 filters to the tube (Picture A), and completely fill the tube with warm
water. Fill up with carbon, making sure it is poured into the water and all air is
expelled (Picture B). Tap the tube to settle and pack the carbon. Filter 2-5 liters of
water through the tube to flush out the remaining soluble substances (Picture C).
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 23
24. 50%
42-
3. Pour in alcohol as the last drops of water drain from the funnel. Taste the filtered
water/alcohol, and as soon as the alcohol emerges, let it run into a container.
Cover the funnel with a lid to avoid vaporization of the alcohol.
4. When the last drops of alcohol leave the funnel, pour in a liter of water to ensure
that all alcohol is filtered through. Again, taste the filtered alcohol/water, and
discard the water.
5. This way, the carbon is started, and all air in the tube is expelled. It also eliminates
the bypass “channels” formed when using dry carbon, and prevents changes in
the pH-value (from 7 to 10) that normally occur when the soluble substances in
the carbon are dissolved in water or alcohol.
Once the carbon has been heated and soaked, and when all air is expelled from
the tube, the alcohol will flow through the channels in the carbon, and not escape
unfiltered. Effectiveness is increased by at least 100%, giving a cleaner alcohol,
and it is possible to filter twice the volume much faster.
The diameter of the tube should not be less than 38 mm. If it is, too much alcohol
escapes unfiltered along the inner wall (wall effect).
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 24
25. Increase the purification effect of carbon by 150%
AC
T
CA IVAT
RB E
ON D
Hot
1. Pour the carbon into a stainless steel saucepan, and fill with at least twice as
much boiling water.
2. Stir with a large spoon, allow the carbon to sink to the bottom of the saucepan
before discarding the surplus water. Repeat the process 4-5 times, making sure all
soluble substances in the carbon have been washed out.
Cover with boiling water, put a lid on the saucepan, and leave it to soak for 24 hours.
It is the internal wetting within the carbon granule that mostly increase the
purification effect. Those 24 hours add 50% more so we can use the whole capacity of
the activated carbon.
3. Discard surplus water and cover once more with hot or boiling water.
4. Stir and pour off remaining water.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 25
26. 0
H2
Picture A Picture B Picture C
5. Attach 2-3 filters to the tube (Picture A),and fill completely with warm water.
Fill up with carbon, making sure it is poured into the water and all air is expelled
(Picture B). Tap the tube to settle and pack the carbon. Filter 2-5 liters of water
through the tube to flush out the remaining soluble substances (Picture C).
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 26
27. 50%
42-
6. Pour in alcohol as the last drops of water drain from the funnel. Taste the filtered
water/alcohol, and as soon as the alcohol emerges, let it run into a container.
Cover the funnel with a lid to avoid vaporization of the alcohol.
7. When the last drops of alcohol leave the funnel, pour in a liter of water to ensure
that all alcohol is filtered through. Again, taste the filtered alcohol/water, and
discard the water.
8. This way, the carbon is started, and all air in the tube is expelled. It also eliminates
the bypass “channels” formed when using dry carbon, and prevents changes in
the pH-value (from 7 to 10) that normally occur when the soluble substances in
the carbon are dissolved in water or alcohol.
Once the carbon has been heated and soaked, and when all air is expelled from
the tube, the alcohol will flow through the channels in the carbon, and not escape
unfiltered. Effectiveness is increased by at least 100%, giving a cleaner alcohol,
and it is possible to filter twice the volume much faster.
The diameter of the tube should not be less than 38 mm. If it is, too much alcohol
escapes unfiltered along the inner wall (wall effect).
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 27
28. Some useful distillation tips
Preparing the mash and getting better-tasting alcohol
Europeans take this information for granted, since they often distill fruit schnapps: Gheist.
In the early stages they noticed that sediment in wine produced bad-tasting and foul-
smelling distilled alcohol. This happened when the sediment “burned” in the places where
the pot was heated up. The problem was solved two ways:
1. By not using direct heat. Instead a “water bottle” was placed around the pot and
filled with hot water.
2. By clarifying the wine. A crystal-clear wine does not leave any off-flavors in the
alcohol. The same goes for the mash. Leave it to clear and siphon the crystal
clear mash before distillation. If the mash doesn’t clear, leave it for a few days,
preferably in a cool place (an old fridge will do). If it’s still cloudy, add wine fining.
It can also be filtered through a coarse wine filter.
A useful distillation tip
Alcohol was always distilled twice in the traditional Swedish distilleries. The first
distillation was quick and of low quality. This produced the raw spirit, which was diluted
with water to 50%, distilled a second time in a column still at 78°C.
Home distillers can do this as well. First, a quick distillation (stripping) and then dilute with
water to 40-50% (otherwise it will boil dry and the alcohol will not be as pure). Distill a
second time - several fermentations can be distilled as one batch at the same time. It’s
easier to maintain the temperature and the result is a cleaner alcohol since many of the
impurities are separated out during the first distillation.
Mysterious bad taste in home distilled alcohol
One has done everything right but the distilled alcohol smells and tastes a lot of volatile.
Maybe you have distilled good vodka for the second time and it comes out worst. There
is no explanation.
This use to come from the column filling. The column shall always be back flushed with
hot water from the tap. At least every third time (every time if you use pot scrubbers, also
before the first run) the column filling shall be rinsed with GLASRENS. This is a super
effective cleaner, high in pH and containing chloride. Dissolve 2 teaspoons in 2.5 liters
(1/2 gallon) warm water. Put the column filling (rashig rings or similar) into the solution
and leave it for 15-20 minutes. Rinse everything thoroughly and accurately with pure and
warm water, then let it dry.
Cleaning of a copper still with GLASRENS
GLASRENS is one of the best cleaners available. But it is high in pH and copper does
not like high pH cleaners, it turns black. But this takes times.
GLASRENS works great if the cleaning is done within 15 minutes. Dissolve 2 teaspoons
in 5 liters (1 gallon) warm water. Put the copper still parts into the solution and leave it for
10-15 minutes. Rinse everything thoroughly and accurately with pure and warm water,
then let it dry. One can also mix some acid, for example 25-gram citric acid with 5 liter (1
gallon) of water and rinse with after GLASRENS. It neutralizes all high pH particles that
are left.
Gert Strand AB, Box 50221, S-202 12 Malmo, Sweden 28