Project report on ceramics industry - Technology Book - Feasibility Report - Market Survey - Industrial Report

CERAMIC SANITARYWARES PRODUCTS

EIRI Team — Fri, 15 Apr 2016 10:28:31 +0000

Sanitary ware is a general term for articles that are usually made of ceramic including toilets, washbasins and bidets. They are considered to be extremely durable as well as hygienic. The manufacture of ceramic sanitary ware is now a highly automated process with thousands of pieces per week being produced in factories all around the world. Wash basins, toilets and bidets are all considered standard sanitary ware pieces but each manufacturer has his own range of designs. This can include articles of different size, shape, colour and finish.

Ceramic Sanitary wares are used for sanitation purposes. Sanitary ware products range from Wash Basins, Closets, Urinals, Sinks, Baths tubs etc. Because of its good properties like good corrosion resistance, good abrasion resistance, glazy surface with different appealing colours, the use of sanitary ware for sanitation purpose has not yet been remarkably replaced by other materials like steel, fibre etc. The ceramic sanitary wares are rather cheap, easy to clean and are available of various colours.

Sanitary is the general nomenclature given to ceramic wares used for sanitary facilities, water supply, drainage, sewerage, and sanitary treatment of excertion for the purpose of comfortable living. Because of the incombustible, waterproof, non-abrasion, and chemical resistant properties all sorts of ceramic products have played a constructive role for comfortable living.

The major raw materials of sanitary ware are ball clay, kaolin, feldspar and quartz. Some of the products are wash basin, water closet, squats pan, urinal, pedestal, bidet and other accessory materials such as toilet roll holder, tooth brush holder, towel and soap holder etc.

Sanitary ware, especially, is closely connected with housing, and so it has developed considerably with the structural improvement and modernization of dwelling.

Sanitary fittings are important in every home. They are used for disposing of the waste and cleaning the home. Sanitary fittings with regards to their functions have been divided into two groups. One of the groups is waste appliances. This group includes those appliances which are used for cleansing. Wash basins, showers, bath tubs are few of the waste appliances to name. Another group is soil appliances. These are the appliances which are mainly used to dispose of the wastage. They are mainly used to discharge excreta matter. Water closet and urinal are the examples of these appliances. These appliances are made of ceramic, stainless steel and sometimes plastic. They are also made up of vitreous chinaware or glazed fire clay. The material that is used to make all these sanitary appliances is non-absorbent and non-corroding. It is also smooth and therefore is quite easy to clean.

INTRODUCTION
SANITARY APPLIANCES
TYPES OF WATER CLOSETS
TYPES OF WC PAN
STYLES OF PAN
THE TYPES OF URINALS
TYPES OF BIDETS
TYPE OF WASHBASIN
PROPERTIES OF CERAMIC SANITARYWARE
B.I.S. SPECIFICATIONS
MARKET SURVEY
PRESENT MANUFACTURERS/ SUPPLIERS OF CERAMIC SAINTARY WARE
MANUFACTURING PROCESS
MAIN STEAPS ARE GIVEN BELOW
PROCESS FLOW CHART
SUPPLIERS OF PLANT AND MACHINERY
POWDER COATING PLANTS
SUPPLIERS OF RAW MATERIALS

APPENDIX – A :

1. COST OF PLANT ECONOMICS
2. LAND & BUILDING
3. PLANT AND MACHINERY
4. FIXED CAPITAL INVESTMENT
5. RAW MATERIAL
6. SALARY AND WAGES
7. UTILITIES AND OVERHEADS
8. TOTAL WORKING CAPITAL
9. COST OF PRODUCTION
10. PROFITABILITY ANALYSIS
11. BREAK EVEN POINT
12. RESOURCES OF FINANCE
13. INTEREST CHART
14. DEPRECIATION CHART
15. CASH FLOW STATEMENT
16. PROJECTED BALANCE SHEET

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CERAMIC INSULATOR (HT/LT)

EIRI Team — Mon, 08 Sep 2014 07:25:30 +0000

Ceramic materials are widely used in applications where high temperatures are encountered. Frequently ceramic materials are used to provide thermal insulation in high temperature application. Ceramic insulators have been utilized in a variety of electrical devices. Ceramic insulators are often used as electrical insulators in chemically and electrically hostile environments. These ceramic insulators are often prepared from compositions containing lead, such as lead silicate. The lead is utilized to lower the firing temperature of the ceramic material and to promote bonding and sintering of other constituents in the ceramic used to form the insulator. High voltage insulators of ceramic materials are mainly used in outdoor switching stations and outdoor lines. They comprise an elongated insulation body which is equipped with shields for the formation of a leakage path which is matched, to the atmospheric conditions. The ceramic insulators, however, are heavy and bulky; they require specialized assembly fixtures or processes and are awkward and difficult to handle and ship. The ceramic insulators are also
brittle and easily chipped or broken. As an alternative to ceramics, composite materials were developed for use in insulators for transmission systems

Project Report Covers:

Introduction
Uses and Applications
Properties
Market Survey with future aspects
Present Manufacturers
B.I.S. Specifications
Manufacturing Process with Formulae
Cost Economics with Profitability Analysis
Capacity
Land & Building Requirements with Rates
List & Details of Plant and Machinery with their Costs
Raw Materials
Details/List and Costs
Power & Water Requirements
Labour/Staff Requirements
Utilities and Overheads
Total Capital Investment
Turnover
Cost of Production
Break Even Point
Profitability
Land Man Ratio
Suppliers of Plant & Machineries and Raw Materials.

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CERAMIC FUSE TUBE/BARRELS USED IN HRC FUSE

EIRI Team — Mon, 28 Jul 2014 08:23:40 +0000

CERAMIC FUSE TUBE/BARRELS USED IN HRC FUSE
[CODE NO. 1590]

In electronics and electrical engineering, a fuse (from the French fuser, Italian fuso, "spindle"[1]) is a type of low resistance resistor that acts as a sacrificial device to provide over current protection, of either the load or source circuit. Its essential component is a metal wire or strip that melts when too much current flows through it, interrupting the circuit that it connects. Short circuits, overloading, mismatched loads, or device failure are the prime reasons for excessive current. Fuses are an alternative to circuit breakers.

PROJECT REPORT COVERS:

Introduction
Uses and Applications
Properties
Market Survey with future aspects
Present Manufacturers
B.I.S. Specifications
Manufacturing Process with Formulae
Cost Economics with Profitability Analysis
Capacity
Land & Building Requirements with Rates
List & Details of Plant and Machinery with their Costs
Raw Materials
Details/List and Costs
Power & Water Requirements
Labour/Staff Requirements
Utilities and Overheads
Total Capital Investment
Turnover
Cost of Production
Break Even Point
Profitability
Land Man Ratio
Suppliers of Plant & Machineries and Raw Materials.

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Hand Book of Ceramics & Ceramics Processing Technology

EIRI Team — Wed, 19 Feb 2014 11:33:55 +0000

Contents-cum-Index

Introduction

Types of ceramic products
Examples of whiteware ceramics
Classification of technical ceramics
Other applications of ceramics
Types of ceramic materials
Crystalline ceramics
Noncrystalline ceramics

Ceramics vs. Fine Ceramics

Classification of Ceramics
Pottery and Ceramics
Ceramics
Glass
Cement
Refractories
Grinding Wheels
Porcelain enamels
Pottery and Ceramics
Earthernware
Pottery
Stoneware
Porcelain
Fine Ceramics

Fine Ceramics Production Process

Types of Fine Ceramics
Barium Titanate (BaTiO3)
Lead Zirconate Titanate
[Pb(Zr,Ti)O3]
Ferrite (M2+O.Fe2O3)
Alumina (Al2O3)
Forsterite (2MgO.SiO2)
Zirconia (ZrO2)
Zircon (ZeO2.SiO2)
Mullite (3Al2O3.2iO2)
Steatite (MgO.SiO2)
Cordierite
(2MgO.2Al2O3.5SiO2)
Aluminium Nitride (AIN)
Silicon Nitride (Si3N4) .
Silicon Carbide (SiC)
Fine Ceramic Materials Play an Important Role in Submarine Earthquake Observation
Self-Surfacing Ocean Bottom Seismograph
Comparison of Strength and Specific Density Between Fine Ceramics and Metals

Ceramic Matrix Composites

Fabrication of Ceramic
Matrix Composites
by Chemical Vapour
Infiltration (CVI) .
Chemical Vapour
Infiltration (CVI)
Types of Chemical
Vapour Infiltration process
Chemical Vapour
Infiltration (CVI) process
Advantages and Disadvantages of Chemical Vapour
Infiltration (CVI) process
Fabrication of Ceramic Matrix
Composites by Liquid phase Infiltration
Slurry Infiltration
Process (SIP)
Reactive Melt Infiltration
Process (RMI)
Polymer Infiltration and Pyrolysis (PIP)
Fabrication of Ceramic
Matrix Composites by Sol-gel process
Sol-gel Infiltration – description
Sol-gel Infiltration process
Advantages and Disadvantages of Sol-gel Infiltration
Advantages of Sol-Gel Infiltration
Disadvantages of Sol-Gel Infiltration
Self-lubricating ceramic composites
Solid lubricants, which are used or may be potentially used in selflubricating ceramic composites
Graphite
Alumina-graphite
composite
Silicon nitride-graphite composite
Alumina-carbon nanotube composite
Alumina-CaF2 composite
Nano-structured alumina-
FeS composite
Carbon-Carbon
Composites
Structure of Carbon-
Carbon Composites
Fabrication of Carbon-
Carbon Composites by Liquid Phase
Infiltration process
Fabrication of Carbon-
Carbon Composites by Chemical Vapour
Deposition process
Properties of Carbon-
Carbon Composites
Oxidation protection of
Carbon-Carbon
Composites
Applications of Carbon-
Carbon Composites
Structure of composites
Interfacial bonding
Shape and orientation of dispersed phase
Particulate Composites
Fibrous Composites
Laminate Composites
Estimations of composite materials properties
Rule of Mixtures
Density
Coefficient of Thermal
Expansion
Modulus of Elasticity
Long align fibers
Short fibers
Shear modulus
Poisson’s ratio
Tensile Strength
Metal Matrix Composites
Titanium Matrix Composite
Copper Matrix Composites
Liquid state fabrication of Metal Matrix
Composites
Stir Casting
Infiltration
Solvent debinding
Gas Pressure Infiltration
Squeeze Casting
Infiltration
Pressure Die Infiltration
Solid state fabrication of Metal Matrix
Composites
Diffusion Bonding
Diffusion
Pressure
Sintering
Hot Pressing Fabrication of Metal Matrix
Composites
Hot Isostatic Pressing
Fabrication of Metal
Matrix Composites
Hot Powder Extrusion Fabrication of Metal Matrix Composites
In-situ fabrication of Metal Matrix Composites
Advantages of in situ Metal
Matrix Composites:
Fabrication of Metal Matrix Composites by codeposition
Electrolytic co-deposition
Spray co-deposition
Vapour co-deposition
Carbon Fiber Reinforced
Polymer Composites
PAN-based carbon fibers (the most popular type of carbon fibers)
Pitch-based carbon fibers

Ceramics

Suitable esters are polymers comprising

Ceramic Process

Preparation of a cermet by electrochemical means
Example 1: Replication of the shape of a flower
Example 2: Replication of the shape of a carnation
Example 3: Replication of the shape of a flower
Example 4: Replication of the shape of a burdock bush
Example 5: Replication of the shape of a flower
Example 6: Heat Treated Cermet Electroplate

Process for Preparing Ceramic Moulding

Example 1 to 3 and Comparative Examples 1 to 3
Example 4
Example 5
Example 6
Example 7
Example 8
Example 9

Ceramic-Ceramic Composite Filter

Ceramic-Ceramic Nanocomposite Electrolyte

Conductivity
Conductivity

Process for Ceramic Composites

Ceramic Heater

Ceramic Foam

Dried Emulsion Ceramic Process

Synthesis of Cadmium Zinc Borate Concentrate (Acetate Salts)
Aqueous Phase Preparation
Oil Phase Add 2.0 Kg of Surfactant, OLOA- 1200, to a sufficient volume
Emulsification
Distillation
Synthesis of Cadmium Zinc Borate Concentrate (Nitrate Salts)
Aqueous Phase
Preparation
Oil Phase
Emulsification
Distillation
Synthesis of Cadmium Zinc Borate Concentrate (Xylene Oil Phase)
Aqueous Phase Preparation
Oil Phase
Emulsification
Distillation

Piezoelectric Ceramics

Preparation of Piezoelectric Ceramic Powder
Preparation of Spinel Ceramic Powder
Creation of Piezoelectric Ceramic Containing Spinel Ceramic
Measurement of Characteristics

Ceramic Processing and Shaped Ceramic Bodies

Ceramic Lever

Ceramic Log Moulding Process

Ceramic Capacitor

Manganese Oxide Layer
Iron Oxide Layer
Cobalt Oxide Layer
Nickel Oxide Layer
Zinc Oxide Layer
Indium Oxide Layer
Indium Tin Oxide Layer
Tin Oxide Layer

Brazing Ceramics

Hydroxylapatite Ceramic

Ceramic Igniters

Igniter Fabrication .
Additional Igniter Fabrication
Additional Igniter
Fabrication

Glass-ceramicbonded Ceramic Composites

Semiconductive Ceramic

Ceramic Bearing

The First Method
The Second Method
Other Methods

Ceramic Powders

Ceramic Armour

Ceramic Decal

Ceramic Cooktop

Ceramic Elements

Step 11 (S 11 ): Preparation of Slurry for Forming Ceramic Layer
Step 12 (S 12 ): Formation of Green Sheet
Step 13 (S 13 ): Formation of Internal Electrode Paste Layer
Step 14 (S 14 ): Formation of Laminate
Step 15 (S 15 ): Cutting
Step 16 (S 16 ): Baking
Step 17 (S 17 ): Formation of Protective Layer
Step 18 (S 18 ): Formation of Base Electrode
Step 19 (S 19 ): Plating
Comparative Method 1
Investigation of Protective Layer
Changes in Insulation Resistance

Ceramic Welding Process

Ceramic Catalysts

Ceramic Powder Transfer Process

Ceramic Susceptor

Ceramic Instrument

Ceramic Board

Explanation of symbols
Step of forming the ceramic substrate
Step of printing a conductor containing paste on the ceramic substrate
Firing of the conductor containing paste
Step of forming a metal covering layer
Fitting of terminal pins and so on
Step of forming the ceramic substrate
Step of printing a conductor containing paste on the green sheet
Step of laminating the green sheets
Step of firing the green sheet lamination
Production of a Ceramic Heater
Production of a Ceramic Heater
Production of a Ceramic Heater
Comparative Example 1
Comparative Example 2
Industrially Applicability .

Ceramic Waferboard

Ceramic Insulation

Ceramic Decalcomania

Whitlockite Ceramic

Ceramic Microtruss

Chemical Vapour Deposition
Ceramic Through Reaction with the Scaffold
Preceramic Polymers

Ceramic Pigments

The book Hand Book of Ceramics & Ceramics Processing Technology covers Introduction,Ceramics vs. Fine Ceramics, Fine Ceramics Production Process, Ceramic Matrix Composites, Ceramics, Ceramic Process, Process for Preparing Ceramic Moulding, Ceramic Ceramic Composite Filter,Ceramic Ceramic Nanocomposite Electrolyte, Process for Ceramic Composites, Ceramic Heater, Ceramic Foam,Dried Emulsion Ceramic Process, Piezoelectric Ceramics, Ceramic Processing and Shaped Ceramic Bodies, Ceramic Lever, Ceramic Log Moulding Process, Ceramic Capacitor, Brazing Ceramics, Hydroxylapatite ceramic, Ceramic Igniters, Glass ceramicbonded Ceramic Composites, Semiconductive Ceramic, Ceramic Bearing, Ceramic Powders, Ceramic Armour, Ceramic Decal, Ceramic Cooktop, Ceramic Elements, Ceramic Welding Process, Ceramic Catalysts, Ceramic Powder Transfer Process, Ceramic Susceptor, Ceramic Instrument, Ceramic Board, Ceramic Waferboard, Ceramic Insulation, Ceramic Decalcomania, Whitlockite Ceramic , Ceramic Microtruss, Ceramic Pigments.

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