Call for Abstract

5th World Congress on Chemical Engineering and Catalysis, will be organized around the theme “Innovation Integration in the field of Chemical Engineering”

Catalysis 2018 is comprised of keynote and speakers sessions on latest cutting edge research designed to offer comprehensive global discussions that address current issues in Catalysis 2018

Submit your abstract to any of the mentioned tracks.

Register now for the conference by choosing an appropriate package suitable to you.

Chemical Engineering is a train impacting various zones of innovation. In wide terms, substance chemical engineers consider and design processes to deliver change and transport materials — starting with experimentation in the lab took after by execution of the innovation in full-scale creation. New ideas and advancements were presented in concoction designing like transport phenomena; process framework building since unit operations alone was deficient in creating compound reactors. Chemical reaction engineering includes sorting out plant procedures and conditions to guarantee ideal plant operation to develop models for reactor process outline and investigation. Numerous uses of substance building includes in everyday life like elastic, plastic, concrete, sugar, earthenware and so on.

  • Track 1-1Process Design and Analysis
  • Track 1-2Plant Design and Construction
  • Track 1-3Chemical Reaction Engineering
  • Track 1-4Chemical Reactors
  • Track 1-5Transport Phenomena
  • Track 1-6Process Systems Engineering
  • Track 1-7Process Design

Thermodynamics is a division of physics involved with heat and temperature and their relation to energy and work. Thermodynamics mainly deals about the relationship between work, heat and other forms of energy. Thermodynamics applies to a wide range of subjects in science and engineering, mainly physical chemistry, chemical engineering and mechanical engineering. Thermodynamics applies to a wide range of subjects in science and engineering, mainly physical chemistrychemical engineering and mechanical engineering. Thermodynamic equilibrium is one of the very important concepts of thermodynamics. A thermodynamic operation usually results in thermodynamic process of transfer of mass or energy that modifies the state of the system, and the transfer occurs in natural accord with the laws of thermodynamics. Thermodynamic systems are theoretical constructions used to model physical systems that convert matter and energy in terms of the laws of thermodynamics. Distributed control systems are helping end-users to address complex process automation challenges effectively.

  • Track 2-1The Phase Equilibrium Problem
  • Track 2-2Equilibrium and stability
  • Track 2-3Volumetric properties
  • Track 2-4Solubility of solids in compressed gases
  • Track 2-5High pressure phase diagrams
  • Track 2-6Polymer solutions

Organic chemistry is the investigation of the structure, properties, synthesis, responses, and planning of carbon-containing compounds, which incorporate hydrocarbons as well as mixes with any number of different components, including hydrogen (most mixes contain no less than one carbon– hydrogen security), nitrogen, oxygen, incandescent lamp, phosphorus, silicon, and sulphur. This branch of chemistry was initially restricted to mixes created by living life forms however has been expanded to incorporate human-made substances, for example, plastics. The scope of use of organic compounds is colossal and furthermore incorporates, yet is not restricted to, pharmaceuticals, petrochemicals, sustenance, explosives, paints, and beauty care products.

  • Track 3-1Structure and Bonding
  • Track 3-2Resonance and Acid- Base Chemistry
  • Track 3-3Alkanes, Cycloalkanes, and Functional Groups
  • Track 3-4Stereochemistry
  • Track 3-5Alkanes and Alkynes
  • Track 3-6Aromatic Compounds
  • Track 3-7Amines
  • Track 3-8Spectroscopy

In the current chemical industry the point is to accomplish brilliant items and limit undesirable results. Selectivity in the reactor is especially critical in forms in which results cause ecological issues (e.g. NOx and CO in fumes gasses from cars). In forms where high immaculateness is required for authoritative reasons, for example, in the pharmaceutical business, the cost of cleaning winds up plainly vital and reactor execution is of key noteworthiness. Information of the focal points and disadvantages of synthetic reactor properties is subsequently basic for all chemical and biochemical processes. Research in chemical reaction engineering incorporates the energy and flow of chemical and biochemical procedures combined with sub-atomic mass transport phenomena. Other imperative research fields are turbulence displaying connected to chemical reaction, maturation forms, impetus deactivation, process control, steadiness and streamlining.

  • Track 4-1Stoichiometry, Kinetics & Ideal Reactors
  • Track 4-2Complex Reactions
  • Track 4-3Heterogeneous Reactions
  • Track 4-4Nonideal Flow in Reactors
  • Track 4-5Nonisothermal Reactors
  • Track 4-6Reactor Design

Petrochemical engineering is a branch of Chemical Engineering which deals with operations involved in refining petroleum or crude oil by the use of advanced technology. The course also includes extraction of crude petroleum obtained from the core of earth. Students learn about the mechanism and techniques involved in activities like exploration, production and exploitation of oil or natural gases. After the completion of undergraduate and postgraduate programmes in petroleum engineering, students can work in job profiles like petroleum geologists, drilling engineers, reservoir engineers and production engineers.  Petroleum engineering is the field of engineering science that involves locating and accessing reserves of natural gas. The course includes subjects like Reaction Engineering, Heat Transfer, Mass Transfer, Fluid Dynamics, Thermodynamics, Transport Phenomena are bridged with special subjects like Petrochemical Processes, Refinery operations with due weight-age on Numerical Computation Process Control, Modelling & Simulation.

  • Track 5-1Acoustics and Noise control
  • Track 5-2Coastal Engineering
  • Track 5-3Guidance and control of Marine Vehicles
  • Track 5-4Port and Harbour Structures
  • Track 5-5Advanced Marine Structures
  • Track 5-6Ocean Mining and Dredging

Biochemical engineering  likewise bioprocess building is a branch of chemical engineering  or natural designing that for the most part manages the outline and development of unit forms that include organic living beings or atoms, for example, bioreactors. Biochemical engineers consolidate information of science, chemistry and building to make items from crude materials and build up the procedures for accomplishing this. They additionally discover answers for issues which happen when chemical materials connect with nature. This could incorporate an extensive variety of exercises, including creating new, cleaner fills from regular assets, and creating and executing procedures to deliver medications and drugs, nourishment and beverages. Biochemical Engineering is the utilization of chemical engineering techniques and ways to deal with mechanical procedures in view of natural components, for example, living cells or their parts.

  • Track 6-1Animal Biotechnology
  • Track 6-2Genetic Engineering
  • Track 6-3Molecular Biology
  • Track 6-4Chemical and Biochemical Reactor Design
  • Track 6-5Immunology

The procedure whereby heat moves from one body or substance to the another by radiation, conduction, convection or a mix of these techniques. Heat transfer streams from a body with high vitality (high temperature) to bring down vitality (bring down temperature). Mass transfer portrays the vehicle of mass starting with one point then onto the next and is one of the fundamental columns in the subject of Transport Phenomena. Mass exchange may occur in a solitary stage or over stage limits in multiphase frameworks. Mass exchange is the net development of mass from one area, generally significance stream, stage, portion or part, to another. Mass move happens in many procedures, for example, assimilation, vanishing, drying, precipitation, film filtration, and refining.

  • Track 7-1One Dimensional Steady State Heat Conduction
  • Track 7-2Multi-dimensional Steady State Heat Conduction
  • Track 7-3Unsteady State Heat Conduction
  • Track 7-4Convection
  • Track 7-5Heat Exchangers
  • Track 7-6Boiling and Condensation

A fluid is a substance which is capable of flowing if allowed to do so. A fluid is a substance which undergoes continuous deformation when it subjected to shear force. Handling the fluids is much simpler and cheaper than handling solids. Wherever possible it is therefore desirable to handle everything in the form of liquids, solutions or suspensions. In industry, pumps, fans, blowers and compressors, pipelines, ducts, valves and fittings are the essential components of a system used for transportation of fluids from one location to another. Fluid flow operation is extremely broad; it includes hydraulics, fluid measurements, hydrodynamics, aerodynamics and hydrostatics. Moreover, it often acquires the closely related topics of heat and mass transfer of the fluid system.

  • Track 8-1Fluid Statics and Its Applications
  • Track 8-2Flow of Compressible Fluids
  • Track 8-3Flow Past Immersed Bodies
  • Track 8-4Transportation and Metering of Fluids
  • Track 8-5Agitation and Mixing of Liquids

A fuel is something that can be singed to discharge warmth and light vitality. The fundamental illustrations are coal, oil, gas and wood. Coal, oil and gas are called "petroleum products". At the end of the day, they were produced using fossils. Burning is a substance response that happens between a fuel and an oxidizing specialist that produces vitality, as a rule as heat and light. Burning is viewed as exergonic or exothermic chemical reactions it is otherwise called consuming. Burning is thought to be one of the principal concoction responses deliberately controlled by people.

  • Track 9-1Properties of Liquid Fuels
  • Track 9-2Properties of Coal
  • Track 9-3Properties of Gaseous Fuels
  • Track 9-4Properties of Agro Residues
  • Track 9-5Combustion
  • Track 9-6Control of Air and Analysis of Flue Gas

Polymer engineering is a division of engineering which utilizes the knowledge and concept of chemical engineering to make easy designing, developing and manufacturing pieces from polymers.  Polymer engineering is a sub-field of materials engineering primarily focusing on the development of new products. Polymer engineers often study plastics, although other substances are also considered polymers. Polymer engineering is emerging as one of the most important fields of engineering with varied applications in low weight–high strength designs, aerospace applications and in general replacing metals with same strength with lesser density.

  • Track 10-1Physical and chemical structures
  • Track 10-2Preparation methods
  • Track 10-3Physical properties
  • Track 10-4Applications

Nano science and technology is the branch of science that studies systems and manipulates matter on atomic, molecular and supra molecular scales (the nanometre scale). On such a length scale, quantum mechanical and surface boundary effects become relevant, conferring properties on materials that are not observable on larger, macroscopic length scales. Nano science, the behaviour of physical systems when confined to near atomic, Nano scale (< 100 nm) dimensions together with the physical phenomena that occur at the Nano scale, is currently one of the most dynamic and rapidly developing areas of interdisciplinary research in applied physics. This is in large part because nanotechnology, the use of these properties and phenomena, is believed to have the potential to revolutionize a wide range of scientific and technological fields.

  • Track 11-1Atom Manipulation
  • Track 11-2Carbon Nanostructures
  • Track 11-3Computational Nanoscience
  • Track 11-4Nanotechnology
  • Track 11-5General Nanoscience

Understanding the outline and operation of unit forms in wastewater treatment and presenting late improvements and further developed systems. This course gives you a fundamental comprehension of the outline and operation of unit forms in residential and modern wastewater treatment. We put a specific accentuation on natural standards and parameters. Wastewater engineering envelops the arranging, plan, development, and supervision of water and wastewater systems. The topic takes after the stream of water (and the plan of unit forms) from the advancement of a source through the unit procedures of coagulation, flocculation, softening, invert osmosis, Nano filtration, sedimentation, granular filtration, layer filtration, sanitization, and residuals administration.

  • Track 12-1The design and construction processes
  • Track 12-2General water supply design considerations
  • Track 12-3Wells
  • Track 12-4Wells
  • Track 12-5Coagulation and flocculation
  • Track 12-6Lime–soda softening
  • Track 12-7Sedimentation
  • Track 12-8Removal of specific constituents
  • Track 12-9water plant residuals management

This is where technology meets business:  Chemical engineers working in industry have to know about money and markets, capital investments, cost estimation, budgeting, business plans, and more.   Yet the tools used for finding business and market information are quite different from those used for technical information. A chemical plant design as part of chemical engineering curriculum is given in only a small percentage of institution which presumably trains men for the chemical and allied industries. Its value as a summation and correlative course can be equalled by very few engineering subjects. Its emphasis on the practical side closely connects student to industry. The viewpoint from the financial and economic phases causes the subject to be over alive, progressive and up-to-date.

  • Track 13-1Process Design Development
  • Track 13-2General Design Considerations
  • Track 13-3Computer-Aided Design
  • Track 13-4Cost and Asset Accounting
  • Track 13-5Cost Estimation
  • Track 13-6Materials Transfer, Handling, and Treatment Equipment-Design and Costs
  • Track 13-7Mass-Transfer and Reactor Equipment-Design and Costs

Application to the design of chemical equipment. Design of fluid storage and transfer equipment; pressure and non-pressure vessels, pumps and compressors, nozzles, piping, valves. Design of other operational units commonly used in chemical plants; heat exchangers, solid handling devices, fluid processing units. Hydraulic aspects of plate distillation column, packed columns, fluidised beds. Safety and integrity of equipment; safe working stress. Design standards and codes of practice. Flow sheets, plant layout; equipment, piping and site layouts.

  • Track 14-1Polymer Materials and Technology
  • Track 14-2Petrochemical Engineering
  • Track 14-3Industrial Pollution and Control
  • Track 14-4Fertilizer Technology
  • Track 14-5Instrumentation and Control

In chemical process plants worked all through the concoction procedure ventures (CPI) and related enterprises; plant utilities assume a basic part in supporting the operation of the office. Common plant utilities incorporate steam, power, refrigerants, delta water sources, packed air, mechanical gasses, heat transfer fluids, cooling towers, and that's only the tip of the iceberg. Legitimate plan, operation and upkeep of the building frameworks expected to give these things are vital. Vitality proficiency is vital to guaranteeing a protected, dependable, moderate and practical vitality framework for what's to come. It is the one vitality asset that each nation has in wealth and is the speediest and minimum expensive method for tending to vitality security, natural and monetary difficulties. Proficient energy utilize is accomplished principally by methods for a more effective innovation or process. Energy proficient structures, mechanical procedures and transportation could diminish the world's vitality needs in 2050 by 33%, and help controlling worldwide emanations of nursery gasses.

  • Track 15-1Steam, Steam Generation and Steam Distribution
  • Track 15-2Refractories
  • Track 15-3Insulation
  • Track 15-4Refrigerants and Cooling Water

In order to provide daily needs of the growing population, differ­ent types of industries are setup to produce different products. The industries use raw materials, process them and produce fin­ished products. Besides the finished products, a good number of by-products are produced. Out of all the by-products, if some are in huge quantities and the processing is cost effective, the indus­trialist preserves the by- products.

Control at Source: It involves suitable alterations in the choice of raw materials and process in treatment of exhaust gases before finally discharged and increasing stock height up to 38 metres in order to ensure proper mixing of the discharged pollut­ants.

Selection of Industry Site: The industrial site should be properly examined considering the climatic and topographical characteristics before setting of the industry.

Treatment of Industrial Waste: The industrial wastes should be subjected to proper treatment before their discharge.4. Plantation: Intensive plantation in the region considerably reduces the dust, smoke and other pollutants.5. Stringent Government Action: Government should take strin­gent action against industries which discharge higher amount of pollutants into the environment than the level prescribed by Pollu­tion Control Board

  • Track 16-1Petroleum Industry
  • Track 16-2Energy Production from Fossil Fuels
  • Track 16-3Inorganic Chemical Technology
  • Track 16-4Pulp and Paper

In order to provide daily needs of the growing population, differ­ent types of industries are setup to produce different products. The industries use raw materials, process them and produce fin­ished products. Besides the finished products, a good number of by-products are produced. Out of all the by-products, if some are in huge quantities and the processing is cost effective, the indus­trialist preserves the by- products.

Control at Source: It involves suitable alterations in the choice of raw materials and process in treatment of exhaust gases before finally discharged and increasing stock height up to 38 metres in order to ensure proper mixing of the discharged pollut­ants.

Selection of Industry Site: The industrial site should be properly examined considering the climatic and topographical characteristics before setting of the industry.

Treatment of Industrial Waste: The industrial wastes should be subjected to proper treatment before their discharge.4. Plantation: Intensive plantation in the region considerably reduces the dust, smoke and other pollutants.5. Stringent Government Action: Government should take strin­gent action against industries which discharge higher amount of pollutants into the environment than the level prescribed by Pollu­tion Control Board

  • Track 17-1Environmental Pollution Control and Prevention
  • Track 17-2Air Pollution Management
  • Track 17-3Air Pollution: Modelling of Air Pollutant Dispersion
  • Track 17-4Air Quality Monitoring
  • Track 17-5Air Pollution Control
  • Track 17-6Water Pollution Control
  • Track 17-7Principles of Waste Management
  • Track 17-8Safety Management

The need of the Department exercises is to build up the hypothesis of innovation of catalytic forms in close connection with real industrial processes. The investigations infer dynamic estimations, scientific and streamlined demonstrating, and enhancement of synergist forms, pilot testing, and readiness of engineering basis; start-up and writer's supervision for restrictive modern procedures. The R&D exercises in the Department are gone for the change of existing and production of new mechanical procedures. An essential reason for existing is the improvement of physicochemical premise of reactant advancements and operation of new catalysts.

  • Track 18-1Catalysis
  • Track 18-2Reactor Design
  • Track 18-3Spatially resolved measurement
  • Track 18-4Hydrogenation
  • Track 18-5Methane Aromatization
  • Track 18-6Power to Gas

 Catalysis and chemical reaction building lie at the center of numerous substance and biochemical procedures. Research exercises cover the principal impetus plan, through definition and impetus make, to operational issues and reactor outline. Catalysis and Reaction Engineering. "From a straightforward response between particles to the efficient outline of a chemical reactor, energy and impetuses is the key." The test in designing the catalyst  is to expand its viability and soundness. Substance response building is the capacity to judiciously outline and control synthetic responses. In this way one ought to comprehend reactor plan, catalysis, and divisions. Seeing how to control the profitability and selectivity of responses for chemical production, contamination decrease, restorative combination, and so forth, is basic for present day ventures and for the change of the human condition.

  • Track 19-1Octane Rating
  • Track 19-2Steps in Catalytical Reaction
  • Track 19-3Rate Limiting Step
  • Track 19-4Regulation for Automotive Exhaust Emissions
  • Track 19-5Chemical Vapour Deposition
  • Track 19-6Types of Catalyst Deactivation
  • Track 19-7Temperature-Time Trajectories
  • Track 19-8Temperature-Time Trajectories