Manufacturing Defined & Considerations PDF

Summary

This document provides an overview of manufacturing, from definitions and industrial classifications to considerations and processes. It covers topics such as manufacturing processes, material characteristics, product design, cost-efficiency, and optimization.

Full Transcript

#Manufacturing Defined:
#one technologic and the other economic.

#Technologically, manufacturing is the application of physical and chemical processes to
alter the geometry, properties, and/or appearance of a given starting material to make
parts or products;

#Economically, manufacturing is the transformation of materials into items of greater
value by means of one or more processing and/or assembly operations.

# The key point is that manufacturing adds value to the material by changing its shape or
properties, or by combining it with other materials that have been similarly altered.

# The words manufacturing and production are often used interchangeably. Production
has a broader meaning than manufacturing.
# Manufacturing Industries and Products:
#Manufacturing is an important commercial activity performed by companies that sell
products to customers. The type of manufacturing done by a company depends on the
kind of product it makes.

1. Primary industries cultivate and exploit natural resources, such as agriculture and
mining.

2. Secondary industries take the outputs of the primary industries and convert them into
consumer and capital goods.

3. Tertiary industries constitute the service sector of the economy.

A list of specific industries in these categories is presented the next Table

#Manufactured Products:
Final products made by the manufacturing industries can be divided into two major
classes: consumer goods and capital goods.

Consumer goods :are products purchased directly by consumers, such as cars, personal
computers, TVs, tires, and tennis rackets.

Capital goods: are those purchased by companies to produce goods and/or provide
services. Examples of capital goods include aircraft, computers, communication
equipment, medical apparatus, trucks and buses, railroad locomotives, machine tools,
and construction equipment.
#Manufacturing Considerations
Manufacturing Considerations refer to the various factors or variables that can influence
the manufacturing process of a product. There are specific factors to consider which
include

1) Design for Manufacturability

2) Process Selection

3) Cost-Efficiency in Manufacturing (Economic Production

4. Applying Quality Control Methods in Manufacturing

5. Understanding Environmental Considerations in Manufacturing

1) Design for Manufacturability
#Design Evaluation: A critical assessment of the design from the manufacturing
perspective. It takes into account several factors such as geometric complexity and
alignment with the chosen manufacturing process.

#Material Selection: Chosen based on the product's functional requirement. The selection
should also be favorable for the manufacturing process and cost effective.

#Simplification of Design: Simplifying the parts where possible. A simpler design can lead
to fewer complications during manufacturing and less potential for errors.

#Standardize parts: Utilizing standardized parts where possible reduces the cost of
products.

#Prototype: Testing of the product through creation of a prototype before proceeding to
full-scale manufacturing. This stage helps to identify and resolve any issues that could
potentially surface.
2) Process Selection
Process selection is the procedure of deciding on the most suitable manufacturing
process for production based on factors such as material requirements, production
volumes, and part geometry. Factors Influencing Process Selection in Manufacturing

# Material Characteristics: The physical and chemical properties of the raw material have
a significant impact on the choice of manufacturing process.

# Product Design: The geometry and complexity of the product design also play a key role.
Simple shapes might be produced through basic processes while more complex shapes
may require advanced techniques.

# Production Volume: The number of units to be produced can affect the choice of
process. High-volume production often justifies the use of high-speed processes, while
low-volume production may utilize more flexible processes.

# Cost: The financial aspect is always a consideration, with a constant aim to achieve the
lowest possible cost without compromising quality.
3) Cost-Efficiency in Manufacturing (Economic Production)

The term "cost-efficiency" in the manufacturing sector refers to the ability to produce
goods at the lowest possible cost, whilst maintaining a given level of product quality and
meeting the required production capacity. Achieving cost-efficiency in production requires
a systematic and strategic approach as follows:
# Optimization of Production Processes: Simplifying and rearrangement of processes to
eliminate wastage and down-time. This could be done by reducing material waste and
minimizing energy consumption.

# Automation: Automation of repetitive tasks, such as assembly or testing, can
significantly reduce labor costs and minimize errors, leading to more considerable savings.

# Preventive Maintenance: Regularly maintaining the machinery proactively can help
reduce expensive breakdowns and improve machine performance.

# Investment in Training: Training staff can help improve productivity, reduce mistakes
and downtime, increase morale, which, in turn, can all contribute to lower production
costs.

# Inventory Management: Effective inventory management can minimize holding cost and
other associated costs related to surplus stock

4. Applying Quality Control Methods in Manufacturing

Numerous quality control methods are incorporated across all stages of the
manufacturing process. Here are some commonly adopted quality control methods:

# Statistical Process Control (SPC): SPC involves applying statistical methods to monitor
and control a process. It's aimed at ensuring that the process operates efficiently,
producing more specification-conforming products with less wastage.

# Inspections : Regular inspections can catch deviations from standards and
specifications in the production line early, preventing defective products from reaching
customers.
# Audits: Internal or external audits can be used to review an operating system's
compliance with governing protocols and standards.

# Control Charts: These are used to study how a process changes over time. Data points
are plotted on a chart with predefined control limits. Any variations outside these limits
imply a non-random process variation.

5. Understanding Environmental Considerations in Manufacturing

Environmental considerations in manufacturing refer to the integration of ecologically
friendly practices and strategies into the production steps. This involves several
components which include, but are not limited to:

# Resource Efficiency: This involves using raw materials, energy, and water as efficiently
as possible to reduce environmental impact.

# Waste Minimization: Implementing ways to reduce waste production and promote
recycling and reuse of waste materials.
#Emissions Control: Strategies to limit harmful emissions produced during
manufacturing, promoting cleaner air and reducing the manufacturer's carbon footprint.

#Energy Efficiency: Focusing on energy-saving manufacturing processes and facilities,
using renewable energy sources, and reducing the overall energy consumption.

#Safe Disposal of Waste: Ensuring the safe and environmentally-friendly disposal of
manufacturing waste.

Engineering Materials (MATERIAL IN MANUFACTURING):
Most engineering materials can be classified into one of three basic categories:

(1) metals, (2) ceramics, and (3) polymers. Their chemistries are different, their mechanical
and physical properties are different, and these differences affect the manufacturing
processes that can be used to produce products from them. In addition to the three basic
categories, there are (4) composites-nonhomogeneous mixtures of the other three basic
types rather than a unique category. The classification of the four groups shown in Figure

1) METALS
Metals used in manufacturing are usually alloys, which are composed of two or more
elements, with at least one being a metallic element. Metals and alloys can be divided into
two basic groups: (1) ferrous and (2) nonferrous.

Ferrous Metals

Ferrous metals are based on iron; the group includes steel and cast iron. These metals
constitute the most important group commercially, more than three fourths of the metal
tonnage throughout the world. Pure iron has limited commercial use, but when alloyed
with carbon, iron has more uses and greater commercial value than any other metal. Alloys
of iron and carbon form steel and cast iron. Steel can be defined as an iron–carbon alloy
containing 0.02% to 2.11%carbon. It is the most important category within the ferrous
metal group. Its composition often includes other alloying elements as well, such as
manganese, chromium, nickel, and molybdenum, to enhance the properties of the metal.
Applications of steel include construction (bridges, I-beams, and nails), transportation
(trucks, rails, and rolling stock for railroads), and consumer products (automobiles and
appliances).

Cast iron is an alloy of iron and carbon (2% to 4%) used in casting (primarily sand casting).
Silicon is also present in the alloy (in amounts from 0.5% to 3%), and other elements are
often added also, to obtain desirable properties in the cast part. Cast iron is available in
several different forms, of which gray cast iron is the most common; its applications
include blocks and heads for internal combustion engines.

Nonferrous Metals

Nonferrous metals include the other metallic elements and their alloys. In almost all
cases, the alloys are more important commercially than the pure metals. The nonferrous
metals include the pure metals and alloys of aluminum, copper, gold, magnesium, nickel,
silver, tin, titanium, zinc, and other metals.

2. CERAMICS
A ceramic is defined as a compound containing metallic (or semi-metallic) and
nonmetallic elements. Typical nonmetallic elements are oxygen, nitrogen, and carbon.
Ceramics include a variety of traditional and modern materials. Traditional ceramics,
some of which have been used for thousands of years, include: clay (abundantly available,
consisting of fine particles of hydrous aluminum silicates and other minerals used in
making brick, tile, and pottery); silica (the basis for nearly all glass products); and alumina
and silicon carbide (two abrasive materials used in grinding). Modern ceramics include
some of the preceding materials, such as alumina, whose properties are enhanced in
various ways through modern processing methods.

Newer ceramics include: carbides—metal carbides such as tungsten carbide and titanium
carbide, which are widely used as cutting tool materials; and nitrides—metal and
semimetal nitrides such as titanium nitride and boron nitride, used as cutting tools and
grinding abrasives.

For processing purposes, ceramics can be divided into crystalline ceramics and glasses.
Different methods of manufacturing are required for the two types. Crystalline ceramics
are formed in various ways from powders and then fired (heated to a temperature below
the melting point to achieve bonding between the powders). The glass ceramics (namely,
glass) can be melted and cast, and then formed in processes such as traditional glass
blowing.

3. POLYMERS
A polymer is a compound formed of repeating structural units called mers, whose atoms
share electrons to form very large molecules. Polymers usually consist of carbon plus one
or more other elements, such as hydrogen, nitrogen, oxygen, and chlorine. Polymers are
divided into three categories:

(1) thermos-plastic polymers, (2) thermosetting polymers,

Thermoplastic polymers can be subjected to multiple heating and cooling cycles without
substantially altering the molecular structure of the polymer. Common thermos-plastics
include polyethylene, polystyrene, poly vinyl chloride, and nylon. Thermosetting polymers
chemically transform (cure) into a rigid structure on cooling from a heated plastic
condition; hence the name thermosetting.

4. COMPOSITES
Composites do not really constitute a separate category of materials; they are mixtures of
the other three types. A composite is a material consisting of two or more phases that are
processed separately and then bonded together to achieve properties superior to those of
its constituents. The term phase refers to a homogeneous mass of material, such as an
aggregation of grains of identical unit cell structure in a solid metal. The usual structure of
a composite consists of particles or fibers of one phase mixed in a second phase, called
the matrix.

The synthesized type is of greater interest here, and it includes glass fibers in a polymer
matrix, such as fiber-reinforced plastic; polymer fibers of one type in a matrix of a second
polymer, such as an epoxy-Kevlar composite; and ceramic in a metal matrix, such as a
tungsten carbide in a cobalt binder to form a cemented carbide cutting tool. Properties of a
composite depend on its components, the physical shapes of the components, and the
way they are combined to form the final material. Some composites combine high strength
with light weight and are suited to applications such as aircraft components, car bodies,
boat hulls, tennis rackets, and fishing rods. Other composites are strong, hard, and
capable of maintaining these properties at elevated temperatures, for example, cemented
carbide cutting tools.
Manufacturing Processes
A manufacturing process is a designed procedure that results in physical and/or chemical
changes to a starting work material with the intention of increasing the value of that
material. A manufacturing process is usually carried out as a unit operation, which means
that it is a single step in the sequence of steps required to transform the starting material
into a final product. Manufacturing operations can be divided into two basic types:
(1) Processing operations
A processing operation transforms a work material from one state of completion to a more
advanced state that is closer to the final desired product. It adds value by changing the
geometry, properties, or appearance of the starting material. In general, processing
operations are performed on discrete work-parts.
(2) Assembly operations
An assembly operation joins two or more components to create a new entity, called an
assembly, subassembly, or some other term that refers to the joining process.

Define the manufacturing process with sketch?
Give examples for Specific Industries in Primary, Secondary and Tertiary Categories.

Differentiate between Consumer goods & Capital goods.

What are the Manufacturing Considerations?

The implementation of Design for Manufacturability involves a structured approach
through the following key steps: ---------------------,---------------------,---------------------,--------
-------------,--------------

What is meant by production volume?

The term "cost-efficiency" in the manufacturing sector refers to-----------------------

The importance of inspections ------------------------

Show the classification of engineering materials

Differentiate between ferrous and nonferrous metals with examples

According the following image, define composites materials

Name the following images:
Manufacturing is an important commercial activity performed by companies that sell
products to customers

True False

Primary industries cultivate and exploit natural resources, such as agriculture and mining

True False

Consumer goods are products purchased directly by Investors, such as cars, personal
computers, TVs, tires, and tennis rackets

True False

Prototype: Testing of the product through creation of a prototype before proceeding to
full-scale manufacturing

True False

The physical and chemical properties of the raw material is not important on the choice of
manufacturing process

True False