Industrial engineering is concerned with designing, improving, and installing integrated systems involving people, materials, equipment, energy, and information. It draws on knowledge of mathematics, physical sciences, and engineering principles. The key competencies of industrial engineers include specifying, predicting, and evaluating the results of integrated systems; finding better ways to design, produce, and maintain systems; and continuously improving processes.
Modern precision manufacturing demands extreme dimensional accuracy and surface finish.Such performance is very difficult to achieve manually, if not impossible, even with expert operators. In cases where it is possible, it takes much higher time due to the need for frequent dimensional measurement to prevent overcutting. It is thus obvious that automated motion control would replace manual “handwheel” control in modern manufacturing. Development of computer numerically controlled (CNC) machines has also made possible the automation of the machining processes with flexibility to handle production of small to medium batch of parts. In the 1940s when the U.S. Air Force perceived the need to manufacture complex parts for highspeed aircraft. This led to the development of computer-based automatic machine tool controls also known as the Numerical Control (NC) systems. Commercial production of NC machine tools started around the fifties and sixties around the world. Note that at this time the microprocessor has not yet been invented. Initially, the CNC technology was applied on lathes, milling machines, etc. which could perform a single type of metal cutting operation. Later, attempt was made to handle a variety of workpieces that may require several different types machining operations and to finish them in a single set-up. Thus CNC machining Centres capable of performing multiple operations were developed. To start with, CNC machining centres were developed for machining prismatic components combining operations like milling, drilling, boring and tapping. Gradually machines for manufacturing cylindrical components, called turning centers were developed.
Automatically controlling a machine tool based on a set of pre-programmed machining and movement instructions is known as numerical control, or NC.In a typical NC system the motion and machining instructions and the related numerical data, together called a part program, used to be written on a punched tape. The part program is arranged in the form of blocks of information, each related to a particular operation in a sequence
of operations needed for producing a mechanical component. The punched tape used to be read one block at a time. Each block contained, in a particular syntax, information needed for processing a particular machining instruction such as, the segment length, its cutting speed, feed, etc. These pieces of information were related to the final dimensions of the workpiece (length, width, and radii of circles) and the contour forms (linear, circular, or other) as per the drawing. Based on these dimensions, motion commands were given separately for each axis of motion. Other instructions and related machining parameters, such as cutting speed, feed rate, as well as auxiliary functions related to coolant flow, spindle speed, part clamping, are also provided in part programs depending on manufacturing specifications such as tolerance and surface finish. Punched tapes are mostly obsolete.
Modern precision manufacturing demands extreme dimensional accuracy and surface finish.Such performance is very difficult to achieve manually, if not impossible, even with expert operators. In cases where it is possible, it takes much higher time due to the need for frequent dimensional measurement to prevent overcutting. It is thus obvious that automated motion control would replace manual “handwheel” control in modern manufacturing. Development of computer numerically controlled (CNC) machines has also made possible the automation of the machining processes with flexibility to handle production of small to medium batch of parts. In the 1940s when the U.S. Air Force perceived the need to manufacture complex parts for highspeed aircraft. This led to the development of computer-based automatic machine tool controls also known as the Numerical Control (NC) systems. Commercial production of NC machine tools started around the fifties and sixties around the world. Note that at this time the microprocessor has not yet been invented. Initially, the CNC technology was applied on lathes, milling machines, etc. which could perform a single type of metal cutting operation. Later, attempt was made to handle a variety of workpieces that may require several different types machining operations and to finish them in a single set-up. Thus CNC machining Centres capable of performing multiple operations were developed. To start with, CNC machining centres were developed for machining prismatic components combining operations like milling, drilling, boring and tapping. Gradually machines for manufacturing cylindrical components, called turning centers were developed.
Automatically controlling a machine tool based on a set of pre-programmed machining and movement instructions is known as numerical control, or NC.In a typical NC system the motion and machining instructions and the related numerical data, together called a part program, used to be written on a punched tape. The part program is arranged in the form of blocks of information, each related to a particular operation in a sequence
of operations needed for producing a mechanical component. The punched tape used to be read one block at a time. Each block contained, in a particular syntax, information needed for processing a particular machining instruction such as, the segment length, its cutting speed, feed, etc. These pieces of information were related to the final dimensions of the workpiece (length, width, and radii of circles) and the contour forms (linear, circular, or other) as per the drawing. Based on these dimensions, motion commands were given separately for each axis of motion. Other instructions and related machining parameters, such as cutting speed, feed rate, as well as auxiliary functions related to coolant flow, spindle speed, part clamping, are also provided in part programs depending on manufacturing specifications such as tolerance and surface finish. Punched tapes are mostly obsolete.
Adaptive Control Machining systems, Introduction, Where to use adaptive control ?.Adaptive Control, Elements of an adaptive control machining system, Types of Adaptive controls, Benefits of AC
manufacturing support system is the some arrangement of the machine and software and process to work easily with properly handling of equipment like operation different types.it also conclude that all types of material handling system like automated storage and retrieval system etc are come in this categories.
Adaptive Control Machining systems, Introduction, Where to use adaptive control ?.Adaptive Control, Elements of an adaptive control machining system, Types of Adaptive controls, Benefits of AC
manufacturing support system is the some arrangement of the machine and software and process to work easily with properly handling of equipment like operation different types.it also conclude that all types of material handling system like automated storage and retrieval system etc are come in this categories.
The CDIO™ INITIATIVE is an innovative educational framework for producing the next generation of engineers. The framework provides students with an education stressing engineering fundamentals set in the context of Conceiving - Designing - Implementing - Operating (CDIO) real-world systems and products. Throughout the world, CDIO Initiative collaborators have adopted CDIO as the framework of their curricular planning and outcome-based assessment. CDIO collaborators recognize that an engineering education is acquired over a long period and in a variety of institutions, and that educators in all parts of this spectrum can learn from practice elsewhere. The CDIO network therefore welcomes members in a diverse range of institutions ranging from research-led internationally acclaimed universities to local colleges dedicated to providing students with their initial grounding in engineering. CDIO envisions an education that stresses the fundamentals, set in the context of Conceiving - Designing - Implementing - Operating systems and products, through a curriculum organized around mutually supporting courses but with CDIO activities highly interwoven. CDIO activities are rich with student design-build-test projects, integrate learning of professional skills such as teamwork and communication, feature active and experiential learning, and are constantly improved through quality assurance process with higher aims than accreditation.
Research sfvuiehfvodihvidohidhvhvhh.pptxhepigi6836
Biology is the study of life and living organisms. It is a vast field that encompasses various sub-disciplines such as genetics, ecology, anatomy, and more. The study of biology is essential as it helps us understand the world around us and how living organisms interact with each other and their environment.
One of the most fascinating aspects of biology is genetics. Genetics is the study of genes, heredity, and genetic variation in living organisms. It is a crucial field as it helps us understand how traits are passed down from one generation to another and how genetic mutations can lead to diseases.
Another important sub-discipline of biology is ecology. Ecology is the study of how living organisms interact with each other and their environment. It is a crucial field as it helps us understand how ecosystems function and how human activities can impact the environment.
In conclusion, biology is a vast and fascinating field that encompasses various sub-disciplines. It is essential as it helps us understand the world around us and how living organisms interact with each other and their environment. If you are interested in learning more about biology, there are many resources available online that can help you get started ¹²³⁴..
Source: Conversation with Bing, 29/12/2023
(1) Biology Essay Questions And Answers - KCPE-KCSE. https://kcpe-kcse.com/wp-content/uploads/2020/06/KCSE-BIOLOGY-ESSAY-QUESTIONS-AND-ANSWERS.pdf.
(2) Biology Free Essay Examples And Topic Ideas | PapersOwl.com. https://papersowl.com/examples/biology/.
(3) 160 Biology Essay Topics – EssayStone. https://essaystone.com/blog/160-biology-essay-topics/.
(4) Essays About Biology: Top 5 Best Examples and 6 Prompts. https://becomeawritertoday.com/essays-about-biology/.
(5) Biology | Definition, History, Concepts, Branches, & Facts. https://www.britannica.com/science/biology.
(6) en.wikipedia.org. https://en.wikipedia.org/wiki/Biology.
This examines the potential for the application of Design Science principles to the solution design process within solution architecture to improve the rigour and accuracy of solution designs.
Design Science is the structured and systematic process for creating designs that resolve problems. It is concerned with the structured process for the acquisition and application of knowledge in relation to the problems to the resolved and the solution knowledge to be applied.
The application of Design Science must be a means to an end – better solution quality – and not an end in itself – an incentive for the design function is to become large.
Solution architecture requires a (changing) combination of technical, leadership, interpersonal skills, experience, analysis, appropriate creativity, reflection and intuition applied in a structured manner.
Knowledge management – problem knowledge and solution knowledge – is at the core of the application of design science principles.
Knowledge management requires good management of the solution architecture function.
Similar to Pti01 industrial engineering definition (20)
Cosmetic shop management system project report.pdfKamal Acharya
Buying new cosmetic products is difficult. It can even be scary for those who have sensitive skin and are prone to skin trouble. The information needed to alleviate this problem is on the back of each product, but it's thought to interpret those ingredient lists unless you have a background in chemistry.
Instead of buying and hoping for the best, we can use data science to help us predict which products may be good fits for us. It includes various function programs to do the above mentioned tasks.
Data file handling has been effectively used in the program.
The automated cosmetic shop management system should deal with the automation of general workflow and administration process of the shop. The main processes of the system focus on customer's request where the system is able to search the most appropriate products and deliver it to the customers. It should help the employees to quickly identify the list of cosmetic product that have reached the minimum quantity and also keep a track of expired date for each cosmetic product. It should help the employees to find the rack number in which the product is placed.It is also Faster and more efficient way.
NUMERICAL SIMULATIONS OF HEAT AND MASS TRANSFER IN CONDENSING HEAT EXCHANGERS...ssuser7dcef0
Power plants release a large amount of water vapor into the
atmosphere through the stack. The flue gas can be a potential
source for obtaining much needed cooling water for a power
plant. If a power plant could recover and reuse a portion of this
moisture, it could reduce its total cooling water intake
requirement. One of the most practical way to recover water
from flue gas is to use a condensing heat exchanger. The power
plant could also recover latent heat due to condensation as well
as sensible heat due to lowering the flue gas exit temperature.
Additionally, harmful acids released from the stack can be
reduced in a condensing heat exchanger by acid condensation. reduced in a condensing heat exchanger by acid condensation.
Condensation of vapors in flue gas is a complicated
phenomenon since heat and mass transfer of water vapor and
various acids simultaneously occur in the presence of noncondensable
gases such as nitrogen and oxygen. Design of a
condenser depends on the knowledge and understanding of the
heat and mass transfer processes. A computer program for
numerical simulations of water (H2O) and sulfuric acid (H2SO4)
condensation in a flue gas condensing heat exchanger was
developed using MATLAB. Governing equations based on
mass and energy balances for the system were derived to
predict variables such as flue gas exit temperature, cooling
water outlet temperature, mole fraction and condensation rates
of water and sulfuric acid vapors. The equations were solved
using an iterative solution technique with calculations of heat
and mass transfer coefficients and physical properties.
CW RADAR, FMCW RADAR, FMCW ALTIMETER, AND THEIR PARAMETERSveerababupersonal22
It consists of cw radar and fmcw radar ,range measurement,if amplifier and fmcw altimeterThe CW radar operates using continuous wave transmission, while the FMCW radar employs frequency-modulated continuous wave technology. Range measurement is a crucial aspect of radar systems, providing information about the distance to a target. The IF amplifier plays a key role in signal processing, amplifying intermediate frequency signals for further analysis. The FMCW altimeter utilizes frequency-modulated continuous wave technology to accurately measure altitude above a reference point.
Industrial Training at Shahjalal Fertilizer Company Limited (SFCL)MdTanvirMahtab2
This presentation is about the working procedure of Shahjalal Fertilizer Company Limited (SFCL). A Govt. owned Company of Bangladesh Chemical Industries Corporation under Ministry of Industries.
NO1 Uk best vashikaran specialist in delhi vashikaran baba near me online vas...Amil Baba Dawood bangali
Contact with Dawood Bhai Just call on +92322-6382012 and we'll help you. We'll solve all your problems within 12 to 24 hours and with 101% guarantee and with astrology systematic. If you want to take any personal or professional advice then also you can call us on +92322-6382012 , ONLINE LOVE PROBLEM & Other all types of Daily Life Problem's.Then CALL or WHATSAPP us on +92322-6382012 and Get all these problems solutions here by Amil Baba DAWOOD BANGALI
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Water billing management system project report.pdfKamal Acharya
Our project entitled “Water Billing Management System” aims is to generate Water bill with all the charges and penalty. Manual system that is employed is extremely laborious and quite inadequate. It only makes the process more difficult and hard.
The aim of our project is to develop a system that is meant to partially computerize the work performed in the Water Board like generating monthly Water bill, record of consuming unit of water, store record of the customer and previous unpaid record.
We used HTML/PHP as front end and MYSQL as back end for developing our project. HTML is primarily a visual design environment. We can create a android application by designing the form and that make up the user interface. Adding android application code to the form and the objects such as buttons and text boxes on them and adding any required support code in additional modular.
MySQL is free open source database that facilitates the effective management of the databases by connecting them to the software. It is a stable ,reliable and the powerful solution with the advanced features and advantages which are as follows: Data Security.MySQL is free open source database that facilitates the effective management of the databases by connecting them to the software.
Welcome to WIPAC Monthly the magazine brought to you by the LinkedIn Group Water Industry Process Automation & Control.
In this month's edition, along with this month's industry news to celebrate the 13 years since the group was created we have articles including
A case study of the used of Advanced Process Control at the Wastewater Treatment works at Lleida in Spain
A look back on an article on smart wastewater networks in order to see how the industry has measured up in the interim around the adoption of Digital Transformation in the Water Industry.
Hybrid optimization of pumped hydro system and solar- Engr. Abdul-Azeez.pdffxintegritypublishin
Advancements in technology unveil a myriad of electrical and electronic breakthroughs geared towards efficiently harnessing limited resources to meet human energy demands. The optimization of hybrid solar PV panels and pumped hydro energy supply systems plays a pivotal role in utilizing natural resources effectively. This initiative not only benefits humanity but also fosters environmental sustainability. The study investigated the design optimization of these hybrid systems, focusing on understanding solar radiation patterns, identifying geographical influences on solar radiation, formulating a mathematical model for system optimization, and determining the optimal configuration of PV panels and pumped hydro storage. Through a comparative analysis approach and eight weeks of data collection, the study addressed key research questions related to solar radiation patterns and optimal system design. The findings highlighted regions with heightened solar radiation levels, showcasing substantial potential for power generation and emphasizing the system's efficiency. Optimizing system design significantly boosted power generation, promoted renewable energy utilization, and enhanced energy storage capacity. The study underscored the benefits of optimizing hybrid solar PV panels and pumped hydro energy supply systems for sustainable energy usage. Optimizing the design of solar PV panels and pumped hydro energy supply systems as examined across diverse climatic conditions in a developing country, not only enhances power generation but also improves the integration of renewable energy sources and boosts energy storage capacities, particularly beneficial for less economically prosperous regions. Additionally, the study provides valuable insights for advancing energy research in economically viable areas. Recommendations included conducting site-specific assessments, utilizing advanced modeling tools, implementing regular maintenance protocols, and enhancing communication among system components.
Hierarchical Digital Twin of a Naval Power SystemKerry Sado
A hierarchical digital twin of a Naval DC power system has been developed and experimentally verified. Similar to other state-of-the-art digital twins, this technology creates a digital replica of the physical system executed in real-time or faster, which can modify hardware controls. However, its advantage stems from distributing computational efforts by utilizing a hierarchical structure composed of lower-level digital twin blocks and a higher-level system digital twin. Each digital twin block is associated with a physical subsystem of the hardware and communicates with a singular system digital twin, which creates a system-level response. By extracting information from each level of the hierarchy, power system controls of the hardware were reconfigured autonomously. This hierarchical digital twin development offers several advantages over other digital twins, particularly in the field of naval power systems. The hierarchical structure allows for greater computational efficiency and scalability while the ability to autonomously reconfigure hardware controls offers increased flexibility and responsiveness. The hierarchical decomposition and models utilized were well aligned with the physical twin, as indicated by the maximum deviations between the developed digital twin hierarchy and the hardware.
2. ENGINEERING
•... is the profession in which a knowledge of the
mathematical and natural sciences gained by study,
experience, and practice. It is applied with
judgment to develop ways to utilize, economically,
the materials and forces of nature for the benefit
of mankind (ABET Definition)
•... is the application of scientific, economic, social,
and practical knowledge in order to invent, design,
build, maintain and improve structures, machines,
devices, systems, materials and processes
(WIKIPEDIA Definition)
5. Engineering MethodEngineering Method
Scientific MethodScientific Method
•Identify
problem
•Explore
requirements
•Trace
constraints
•Diagnose
causes
•Define
objectives
•Plan program
schedule
•Drawings
•Schematics
•Models
•Algorithms
•Proof of
concepts
•Prototypes
•Experiments
•Validation
and
verification
•Summary
results
•Conduct
implementa-
tion
Phase 1
Idea
Phase 2
Concept
Phase 3
Planning
Phase 4
Design
Phase 5
Development
Phase 6
Launch
Step 1
Ask A
Question
Step 2
Do
Background
Research
Step 3
Construct
A
Hypothesis
Step 4
Test
Hypothesis
Step 5
Analyze Data &
Draw
Conclusion
Step 6
Communicate
6.
7. INDUSTRIAL ENGINEERING
..is concerned with the design, improvement, and
installation of integrated systems of men,
materials, information, energy, and equipments. It
draws upon specialized knowledge and skill in the
mathematical, physical and social sciences
together with the principles and methods of
engineering analysis and design to specify, predict
and evaluate the result to be obtained from such
systems
9. BASIC KNOWLEDGE AND SKILL
INDUSTRIAL ENGINEERING draws upon specialized
knowledge and skill in the mathematical, physical and social
sciences together with the principles and methods of
engineering analysis and design
principles andprinciples and
methods ofmethods of
EENGINEERINGNGINEERING
analysis andanalysis and
designdesign
10. BASIC KNOWLEDGE AND SKILL
Specialized knowledge and skill
•KNOWLEDGE : the condition of theoretical or practical
understanding with awareness or familiarity gained through
study, practice, experience and/or association
•SKILL : the ability to perform something well through
deliberate, systematic, and sustained effort to smoothly and
adaptively carryout complex activities or job functions.
•SPECIALIZED : highly differentiated or characterized by a
particular designed purpose or direction
11. BASIC KNOWLEDGE AND SKILL
the mathematical, physical and social
sciences together with the principles and
methods of engineering analysis and design
•BASIC SCIENCES : the sciences that fundamental to the study
which draws upon mathematical, physical and social sciences
•ENGINEERING SCIENCES : the sciences that encompass
several scientific knowledge to develop technology.
12. BASIC KNOWLEDGE AND SKILL
the mathematical, physical and social
sciences together with the principles and
methods of engineering analysis and design
•PRINCIPLES : the comprehensive and fundamental law,
doctrine, or assumption for body of knowledge and basis of
learning and reasoning.
•METHODS : the manner of procedure, especially an orderly,
logical, or systematic way of instruction to do something.
•ANALYSIS : the thorough study and detailed examination to
understand its nature or to determine its essential features.
•DESIGN : the detailed illustration to conceptualize idea of
something.
13. CORE COMPETENCIES
INDUSTRIAL ENGINEERING is concerned with the design,
improvement, and installation of integrated systems of men,
materials, information, energy, and equipments.
IIntegratedntegrated
SYSTEMSYSTEM
14. CORE COMPETENCIES : the design
• To INVENT
• To INNOVATE
• To CREATE
• To CONSTRUCT
• To BUILD
• To PLAN
• To DEVISE
• To CONTRIVE
• To CONCEIVE
• To MAKE a DRAWING /
SCHEME / FORMULATION /
MODEL
• To DISCOVER an IDEA
• To DEVELOP a CONCEPT
15. CORE COMPETENCIES : the
improvement
• To IMPROVE
• To REFINE
• To REPAIR
• To FIX
• To MAINTAIN
• To REMEDY
• To MODIFY
• To REVISE
• To REFORM
• To INCREASE
• To ELEVATE
• To ESCALATE
• To UPGRADE
• To ENHANCE
• To ADVANCE
• To REDUCE
• To MINIMIZE
• To MITIGATE
• To ELIMINATE
16. CORE COMPETENCIES : the installation
• To INSTALL
• To SET
• To LAY
• To LAUNCH
• To ESTABLISH
• To START
• To APPLY
• To IMPLEMENT
• To OPERATE
• To EXECUTE
• To RUN
• To DO
• To PERFORM
• To CONDUCT
• To CARRY OUT
• To UNDERTAKE
• To ORGANIZE
• To ARRANGE
• To MANAGE
17. CORE COMPETENCIES : the integrated
system
• A set of interdependent things (parts or elements) forming a unified
whole and performing a set of rules to carry out a specific purpose.
• An organized, purposeful structure that consists of interrelated and
interdependent elements (components, entities, factors, members,
parts etc.). These elements continually influence one another
(directly or indirectly) to maintain their activity and the existence of
the system, in order to achieve the goal of the system.
(http://www.businessdictionary.com/definition/)
• A regularly interacting or interdependent group of items forming a
unified whole (https://www.merriam-webster.com/dictionary/)
• A set of things working together as parts of a mechanism or an
interconnecting network; a complex whole
(https://en.oxforddictionaries.com/definition/)
• A set of connected things or devices that operate together
(http://dictionary.cambridge.org/dictionary/english/)
19. COGNITIVE COMPETENCIES : to
specify
• To DEFINE
• To CLARIFY
• To EXPLAIN
• To DESCRIBE
• To ILLUSTRATE
• To DEPICT
• To IDENTIFY
• To DETAIL
• To ITEMIZE
• To CLASSIFY
• To CHARATERIZE
• To CATEGORIZE
• To ELABORATE
• To DECOMPOSE
• To ELUCIDATE
• To DETERMINE
• To ASSIGN
20. COGNITIVE COMPETENCIES : to
predict
• To ESTIMATE
• To APPROXIMATE
• To GUESS
• To EXPECT
• To SUPPOSE
• To PRESUME
• To FORECAST
• To CALCULATE
• To COMPUTE
21. COGNITIVE COMPETENCIES : to
evaluate
• To CHECK
• To INSPECT
• To TEST
• To EXAMINE
• To VERIFY
• To ASSESS
• To APPRAISE
• To VALUE
• To COMPARE
• To OPPOSE
• To CONTRAST
• To REVIEW
• To ANALYZE
• To SYNTHESIZE
• To ANATOMIZE
• To CRITICIZE
• To INVESTIGATE
22. There’s no BEST way,
but there’re BETTER
ways
--- INDUSTRIAL ENGINEERS Find the Better Ways
23. BETTER WAYS
Industrial Engineers Find a Better Way...
•A better way to make a product faster and easier
•A safer way
•A less expensive way
•They examine and analyze to find better ways to solve the
problem
24. Getting worse is a problem.
Missed target is a problem.
Gap is a problem
Always make it BETTER
Unimproved achievement is also a problem
--- CONTINUOUS IMPROVEMENT
25. INDUSTRIAL ENGINEERING
COMPETENCIES
KNOWLEDGE COMPETENCIES
1.Proficient in the theoretical concepts of natural sciences and
engineering mathematics; engineering fundamentals, engineering
sciences and engineering designs that are required for analysis and
designing of the integrated systems
2.Comprehend principles and methods of integrated system analysis
and design using system approach
3.Has capability to envisage factual issues and paradigms in
economics, social, ecological environments
4.Has cultivated skills of communication techniques and pursues the
sophisticated technology and the latest developments
26. INDUSTRIAL ENGINEERING
COMPETENCIES
GENERAL COMPETENCIES
1.Able to apply logical, critical, systematic, and innovative thinking in
the context of the development or implementation of science and
technology, which observe and apply the value of humanities
according to their own competencies.
2.Able to perform independently, have standard, and measurable.
3.Able to review the implication of the development or
implementation of science and technology, which observe and apply
the value of humanities according to the competencies based on rules,
procedures, and ethics in order to produce a solution, idea, design or
art criticism
4.Able to arrange the scientific description of the result study in the
form of a thesis or final project report, and publish the result on
university official site.
27. INDUSTRIAL ENGINEERING
COMPETENCIES
GENERAL COMPETENCIES
5.Able to take appropriate decisions in the context of problem solving
in his field of competencies, based on the analysis of information and
data
6.Able to maintain and deploy the network between supervisors,
colleague, associate in the inside and outside the institution
7.Able to be responsible for the achievement of teamwork and make a
supervision and evaluation of the completion of the work, which
assigned to workers who under its responsibility
8.Able to perform a self-evaluation process of the teamwork who
under its responsibility, and able to manage learning independently
9.Able of documenting, storing and securing the document, and found
back the data to ensure the validity and prevent plagiarism
28. INDUSTRIAL ENGINEERING
COMPETENCIES
SPECIFIC COMPETENCIES
1.Able to apply math, sciences, and engineering principles to solve
complex problem in integrated system (consist of man, material,
equipment, energy, and information)
2.Able to identify, formulate, and analyze engineering complex
problem in integrated system using analytical, computational, and
experimental approach
3.Able to generate solutions of engineering complex problem in
integrated system considering economic factor, public health and
safety factor, culture factor, social factor, and environment factor
4.Able to design integrated system according to technical,
environmental health and safety standard, considering performance
and reliability aspect, ease of implementation and sustainability, in
regard to economic factor, social factor and cultural factor
29. INDUSTRIAL ENGINEERING
COMPETENCIES
SPECIFIC COMPETENCIES
5.Able to observe and investigate engineering complex problem in
integrated using engineering principles, and able to conduct research,
analysis, data interpretation, and information synthesis in developing
solutions
6.Able to select resources, utilize appropriate engineering design and
analysis ICT-based tools to conduct engineering activities
30. The 3 C’s of Life:
Choices, Chances, Changes
You must make a CHOICE to take a CHANCE or
your life will never CHANGE
--- WORK SMARTER NOT HARDERX
AND
31. WHAT IS SYSTEM ?
•A set of interdependent things (parts or
elements) forming a unified whole and
performing a set of rules to carry out a
specific purpose.
•An organized, purposeful structure that consists of
interrelated and interdependent elements
(components, entities, factors, members, parts
etc.). These elements continually influence one
another (directly or indirectly) to maintain their
activity and the existence of the system, in order to
achieve the goal of the system.
31
32. 32
WHAT IS SYSTEM ?
System
Environment
Boundary
Input /
Factors
Output /
Impacts
Feedback
Entitites / Subsystems
Interaction / Cennection
34. OTHER NAMES OF INDUSTRIAL
ENGINEERING
•SYSTEM ENGINEERING
•METHOD ENGINEERING
35. SYSTEM ENGINEERING
..is an interdisciplinary approach and means to
enable the realization of successful systems. It
focuses on defining customer needs and required
functionality early in the development cycle,
documenting requirements, then proceeding with
design synthesis and system validation while
considering the complete problem including
operations, performance, test, manufacturing, cost
and schedule. It integrates all the disciplines and
specialty forming a structured development
process.
38. METHOD ENGINEERING
..is concerned with the selection, development,
and documentation of the methods by which work
is to be done. It includes the analysis of input and
output conditions, assisting in the choice of the
processes to be used, operations and work flow
analysis, workplace design, assisting in tool and
equipment selection and specifications, ergonomic
and human factors considerations, workplace
layout, motion analysis and standardization, and
the establishment of work time standards.
41. Job Opportunities
of
INDUSTRIAL
ENGINEERING
(Occupation ; Department ; Industry)
What work do you want to do after graduating S1 Industrial
Engineering? Or ... What job would you expect to be in line with the
competence of Industrial Engineering graduates?
Example :
1.A planner of preventive maintenance schedule at Maintenance Department in
Motor Vehicle Manufacturing Industry
2.A production supervisor at production department in Pharmaceutical Chemical
Industry
3.An evaluator of financial feasibility at credit service division in banking services
industry
43. DELPHI METHOD
1. Do a brainstorming
2. Recapitulate the result of brainstorming
3. Spread the recapitulation result
4. Collect a polling to sort out the relevant
ones
5. Summarize the result of the polling
6. Spread the summary
7. Collect a ballot to sort according to
relevance level
8. Develop a sorting list of the ballot result
44. JOB OPPORTUNITIES OF INDUSTRIAL
ENGINEERING
INDUSTRIAL ENGINEER
• Helps in
decision
making
• Helps in
designing the
system
• Expert in new
Technology
like BPR,
TQM, MRP,
OR, etc.
• Interprets data
• Reviews data
• Advises for
improvement
• Suggests
productivity tool
• Identifies
system faults
• Analyses job
at micro level
• Coordinator
• Motivates
• Helps in work
study
• Trains the
workers in
methods &
motion study
• Applies new
technologies
• Negotiator
• Uses
Operation
Research &
Quantitative
Techniques
• Develops &
uses decision
tools
• Uses MIS &
computers
Expert
Advisor and
Consultant
Analyst of
System
Trainer
Decision
Maker
45. JOB OPPORTUNITIES OF INDUSTRIAL
ENGINEERING
INDUSTRIAL ENGINEER
Design and
improvement of
condition
Design and
improvement of
organisation
Design and
improvement of
workplace, method,
and procedure
Design and
improvement of
products and
services
External
•Vendor
development
•Customer
research
•Requirement
analysis
•etc
External
•Vendor
development
•Customer
research
•Requirement
analysis
•etc
Internal
Ergonomic
•Lighting
•Noise & vibration
•Fatigue
•Ventilations
•Temperature
•etc
Internal
Ergonomic
•Lighting
•Noise & vibration
•Fatigue
•Ventilations
•Temperature
•etc
Organisational
Issues
•Leadership
•Motivation
•Automation
•Organisation
culture
•etc
Organisational
Issues
•Leadership
•Motivation
•Automation
•Organisation
culture
•etc
•Work study
•System analysis
•Layout planning
•Planning
•Directing
•Control
•Scheduling
•etc
•Work study
•System analysis
•Layout planning
•Planning
•Directing
•Control
•Scheduling
•etc
•TQM (Total
Quality
Management)
•Value analysis &
engineering
•BPR (Business
Process
Reengineering
•Kansei
Engineering
•Benchmarking
•etc
•TQM (Total
Quality
Management)
•Value analysis &
engineering
•BPR (Business
Process
Reengineering
•Kansei
Engineering
•Benchmarking
•etc
Management
Science &
Operation
Research
Management
Science &
Operation
Research
Decision
Theory &
Strategic
Planning
Decision
Theory &
Strategic
Planning
Engineering dalam Bahasa Indonesia mempunyai beberapa kata terjemahan.
Kata terjemahan pertama yaitu Ke-insinyur-an, sehingga bermakna sebagai profesi. Yang menurut ABET (the Accreditation Board for Engineering and Technology) profesi insinyur tersebut membutuhkan pengetahuan di bidang matematika dan ilmu alam yang dibentuk dari belajar, pengalaman dan praktek. Profesi insinyur menerapkan pengetahuan tersebut dengan bijak untuk mengembangkan cara yang ekonomis untuk memberdayakan material dan tenaga bagi keuntungan manusia.
Kata terjemahan kedua yaitu Rekayasa, sehingga bermakna sebagai proses. Yang menurut WIKIPEDIA, proses rekayasa tersebut merupakan aplikasi dari pengetahuan ilmiah, ekonomi, sosial dan praktis untuk menemukan, merancang, membangun, merawat dan memperbaiki struktur, mesin, alat, sistem, material dan proses.
Kata terjemahan ketiga yaitu Teknik, sehingga bermakna sebagai cara. Teknik merupakan cara untuk melakukan sesuatu dengan mempergunakan pengetahuan dan keterampilan tertentu. Teknik mencakup prosedur sistematis, metode, alat, termasuk data, pengetahuan dan keterampilan yang dipersyaratkan.
Engineering mempunyai dua perspektif teoritis dan aplikatif. Pada pekerjaan yang lebih teoritis lebih membutuhkan pengetahuan yang dibentuk dari belajar, pengalaman dan praktek. Sebaliknya pada pekerjaan yang lebih aplikatif lebih membutuhkan keterampilan yang relevan.
Sistematika langkah-langkah metode keteknikan serupa dengan metode ilmiah.
1. Langkah pertama mengidentifikasikan masalah. Yang biasanya dilakukan dengan menjalankan pengamatan pendahuluan (preliminary investigation) melalui wawancara kepada pemangku kepentingan (stake holder), menggali fakta dari laporan-laporan, mempelajari pustaka, melakukan observasi lapangan, mencoba eksperimen awal.
2. Langkah kedua mendeskripsikan konsep gambaran umum masalah. Yang biasanya meliputi menjelaskan latar belakang masalah, merumuskan permasalahan yang menjadi fokus penelitian, menggali kebutuhan-kebutuhan (metode dan alat penelitian), menelusuri kendala-kendala (batasan dan asumsi penelitian), mendiagnosa penyebab-penyebab masalah (elemen-elemen objek penelitian).
3. Langkah ketiga membuat perencanaan atau hipotesa atau tahapan penelitian. Yang biasanya dimulai dengan menentukan tujuan penelitian, merinci aktivitas-aktivitas yang akan dilakukan, menyusun sistematika urutan (serial-paralel) dari aktivitass-aktivitas tersebut hingga mencapai tujuan yang ditentukan sebelumnya, membuat jadwal pelaksanaannya.
4. Langkah keempat melakukan penelitian pada obyek penelitian. Yang biasanya dilaksanakan dengan mengumpulkan data-data dari elemen-elemen relevan dan penting (memberikan pengaruh signifikan), membuat gambar / skema / model / algoritma / formula, mengolah data, mengevaluasi masalah untuk membuktikan hipotesa atas penyebab-penyebab masalah yang memberikan pengaruh signifikan.
5. Langkah kelima mengembangkan usulan perbaikan atau solusi masalah. Yang biasanya dilakukan dengan menganalisa hasil pengolahan data, menyusun alternatif rekomendasi perbaikan, membuat rancang bangun (prototype), mencobakan dengan eksperimen, menguji verifikasi dan validasi, membandingkan dengan kondisi awal, menarik kesimpulan.
6. Langkah keenam menyampaikan usulan perbaikan atau solusi masalah. Yang biasanya sedikitnya melaporkan ringkasan dan kesimpulan, atau ditindaklanjuti dengan mengimplementasikannya.
Dari bagan terlihat bahwa Teknik Industri terkait erat dengan Teknik Mesin (Mechanical Engineering) terutama konsentrasi Teknik Produksi. Pada perkembangan awalnya, lingkup studi Teknik Industri dimulai dari skala mikro, yaitu bagaimana memproduksi yang efektif dan efisien. Sehingga studi lebih berfokus pada sistem manusia mesin. Perkembangan industri di masa itupun mayoritas industri manufaktur yang lebih banyak mengandalkan mekanikal. Dan dari sisi manusianya, ditunjang dengan keilmuan psikologi dan sosiologi industri, serta ilmu manajemen. Salah satu pelopor Teknik Industri (Gilbreth) banyak memberikan penerapan scientific management (bagian dari keilmuan awal Teknik Industri) dalam Teknik Sipil, misalnya terkait langkah-langkah pembuatan campuran beton, dan pemasangan bata. Namun dalam perkembangannya, di mana industri proses atau industri kimia, industri elektronik terus berkembang, bahkan perkembangan sistem kontrol dan teknologi informasi dalam industri, maka Teknik Industri berkaitan dengan teknik kimia dan teknik elektro, demikian pula disiplin ilmu teknik lainnya. Teknik Industri tidak terlepas dari ilmu matematika, statistika dan ekonomika, karena Teknik Industri berkaitan erat dengan efisiensi.
Teknik Industri seperti halnya keilmuan teknik lainnya pasti berkenaan dengan kemampuan creating and improving solutions or benefits, atau kemampuan merancang dan memperbaiki, termasuk kemampuan untuk installation atau implementasinya.
Tetapi berbeda dengan teknik lainnya, kekhususan teknik industri berfokus pada SISTEM TERINTEGRASI.
Pada gambar diilustrasikan bahwa seorang yang mempunyai keahlian dalam keilmuan teknik industri perlu didukung pengetahuan dan keterampilan dalam matematika, ilmu alam, ilmu sosial dan keteknikan. Berfokus pada sistem terintegrasi dalam upaya untuk melakukan design, improvement and installation sistem tersebut. Saat melakukannya, dia harus selalu memikirkan bagaimana specify-predict-evaluate keluaran yang dihasilkan sistem yang dipelajari.
TI dapat dideskripsikan dengan cara lain, yaitu sebagai keahlian keilmuan yang tersusun dalam tiga layer atau tingkatan, meliputi: (1) Basic Knowledge and skill, (2) Core competencies dan (3) Cognitive competencies.
Pada layer paling dasar atau basic knowledge and skill yang menjelaskan pengetahuan dan keterampilan dasar yang harus dimiliki TI, Ditunjukkan bahwa TI harus menguasai prinsip dan metode keteknikan atau rekayasa dalam menganalisa dan merancang terutama pada sistem terintegrasi.
Dalam hal ini, TI membutuhkan kemampuan dasar dalam pengetahuan dan keterampilan di bidang ilmu matematika, ilmu alam dan ilmu sosial yang diperlukan sesuai dengan sistem yang dipelajari.
Pada layer berikutnya atau Core competencies menjelaskan kompetensi utama dari TI. TI sebagai sebagai bagian dari keilmuan teknik pasti berkenaan dengan design, improvement dan installation, namun berbeda pada fokus studi yaitu pada integrated system.
Kemampuan design ini berkaitan dengan merancang sistem baru atau sistem yang sebelumnya masih belum ada. Sedangkan kemampuan improvement ini berkaitan dengan memperbaiki atau merancang ulang sistem yang sudah ada sebelumnya agar menjadi lebih baik. Dan kemampuan installation berkaitan dengan bagaimana mengimplementasikan hasil dari design dan improvement tersebut.
To specify an existing / previous system. To predict the (re)designed / improved system before it is installed. To evaluate the installed / new system.
suatu kesatuan yang terdiri dari sekumpulan elemen-elemen (entitas atau subsistem) yang saling berinteraksi (selaras atau bertolak belakang, bergabung atau terurai) secara simultan dan terpadu untuk mewujudkan tujuan tertentu dengan mendapatkan masukan dan menghasilkan keluaran pada lingkungan di luar batasan sistem
Selain disebut dengan TEKNIK INDUSTRI (INDUSTRIAL ENGINEERING), disiplin ilmu ini terkadang juga disebut dengan : System Engineering atau Method Engineerg