Tuesday, September 28, 2021

Design Thinking and Industrial Engineering



Do industrial engineers need design thinking?

Design Thinking for Managers
Design Thinking can do for organic growth and innovation what TQM did for quality.
http://nraombakc.blogspot.com/2013/08/design-thinking-for-managers.html


Industrial engineers redesign product and processes. Hence development in design process, design thinking is relevant for industrial engineers.

What is Design Thinking?


Design thinking is Ideo's approach for design which is human-centered. As a design company, Ideo tries to solve design problems starting with the user's requirements, feelings and difficulties in using or experiencing products. While tech-centered companies focus on their technical capabilities to design products, Ideo focuses on its behavioral research skills to understand the customers' pain points and pleasure points.

Ideo's research for product design is based on teams having persons from diverse disciplines spanning from business to behavior sciences (that includes engineers and scientists). The research team tries to observe consumers during their product evaluation and purchase decisions through videos and photographs apart from interviews. It uses photographs and videos persons in physical locations of the companies to observe how they feel and why they feel in the location. The insights gained are used to improve the facility. It forms of groups of consumers to help it in evaluating the experience in using products and encourages them to take pictures and videos and write descriptions regarding their feelings on various aspects of the products.

Frequent prototypes of are made of the proposed products so that consumers can give their evaluation more frequently about the proposed products. It encourages its employees and the employees of client companies to participate in the research project. One illustration of the benefit of this approach is an objection by Steve Jobs to the noise made the movement of a proposed mouse design. It was resolved by rubber coating the steel ball.

The principal focus of Ideo is on solving usability problem for consumers. It research is broad to cover many consumers and in depth to discuss issues with select group of consumers. The approach of Ideo now became a design excellence model like that of Toyota Production System for World Class Manufacturing.

(Source: Marketing Case Study in Kotler and Keller, Marketing Management, 15th Ed. P.160-161)



Today (4 May 2017), I came across an interesting article on design thinking.

NO PROCESS, JUST 4 TENETS OF DESIGN THINKING
Published on April 22, 2017 by Manoj Kothari, Director & Chief Design Strategist - Turian Labs on Linkedin.

https://www.linkedin.com/pulse/process-just-4-tenets-design-thinking-manoj-kothari

He emphasizes four points:  Empathic Inquiry, Abductive Reasoning, Visual Thinking or Creative Visualization and Iterative Prototyping.

Empathic inquiry is to go and stand in the posture of the users. Go and sit in the posture of the user. Understand the users' requirement from the their point of view. Go and use the item as they are using. Don't come with an ideal way of using it all the 8 hours or more a users uses an item. Understand why he does a thing the way he does it.

Aductive reasoning: Imagine various possibilities.

Visual thinking: Don't use only words to express. Use pictures and visuals.

Iterative prototyping - Once again don't limit yourself to picture or a design drawing. Convert it into prototype that can be seen as a 3D shape and handled.

I think industrial engineers have to accept all the four points and incorporate rate them into their design process.

Ud 28.9.2021
Pub. 4 May 2017

Improvement of Transport - Material Handling Operations in Processes

 

Lesson 136 of  Industrial Engineering ONLINE Course.

Sub-Module in Process Improvement - Transport - Material Handling Operations

Lessons  136  -  137  - 138 - 139 - 140 -  141

In the flow process chart method, the third operation is transport and material handling. Like the other two earlier operations, material transformation and inspection, industrial engineers have to reduce the activity (activity based management) and make efforts to increase the speed of the equipment used in the activity to reduce the activity time. So we can observe two types of improvement tasks. One to reduce the number of times the activity is carried and to reduce the time taken for doing the activity. Industrial engineer's primary focus is on engines and engineering, the devices that help man to do more. In the next step he is focusing on the speed with which a man can work with the equipment. A man's power and speed are limited and cannot be easily enhanced except by providing engines or machines.



Productivity Analysis of Material Handling for Machining Operation - Operation Analysis Step

 



Analysis

How is the material moved from the earlier machine to the current machine? Can it be automated? Can better equipment be provided to increase productivity?

Is an  operator required to pick up the work piece and stack it?

Where are the work pieces stacked?

What is the motion pattern used by the operator to load the work piece?

What is the motion pattern used by the operator to unload the work piece?


Does he need to stack it?

Does he have a role in placing the finished item stack in the next material handling movement from his workstation?


https://www.masterautomation.in/machine-shop/







Pig Iron Handling Improvement by  F.W. Taylor - Development of Productivity Science of Material Handling


This work is  typical of perhaps the crudest and most elementary form of labor which is performed by man. This work is done by men with no other implements than their hands. The pig-iron handler stoops down, picks up a pig weighing about 92 pounds, walks for a few feet or yards and then drops it on to the ground or upon a pile. 

Yet it will be shown that the science of handling pig iron is so great and amounts to so much that it is impossible for the man who is best suited to this type of work to understand the principles of this science, or even to work in accordance with these principles without the aid of a man better educated than he is. And the further illustrations to be given will make it clear that in almost all of the mechanic arts the science which underlies each workman's act is so great and amounts to so much that the workman who is best suited actually to do the work is incapable (either through lack of education or through insufficient mental capacity) of understanding this science. This is announced as a general principle, the truth of which will become apparent as one illustration after another is given. After showing these four elements in the handling of pig iron, several illustrations will be given of their application to different kinds of work in the field of the mechanic arts (human effort), at intervals in a rising scale, beginning with the simplest and ending with the more intricate forms of labor.

One of the first pieces of work undertaken by us, when the writer started to introduce scientific management into the Bethlehem Steel Company, was to handle pig iron on task work. The opening of the Spanish War found some 80,000 tons of pig iron placed in small piles in an open field adjoining the works. Prices for pig iron had been so low that it could not be sold at a profit, and it therefore had been stored. With the opening of the Spanish War the price of pig iron rose, and this large accumulation of iron was sold. This gave us a good opportunity to show the workmen, as well as the owners and managers of the works, on a fairly large scale the advantages of task work over the old-fashioned day work and piece work, in doing a very elementary class of work.

The Bethlehem Steel Company had five blast furnaces, the product of which had been handled by a pig-iron gang for many years. This gang, at this time, consisted of about 75 men. They were good, average pig-iron handlers, were under an excellent foreman who himself had been a pig-iron handler, and the work was done, on the whole, about as fast and as cheaply as it was anywhere else at that time.

A railroad switch was run out into the field, right along the edge of the piles of pig iron. An inclined plank was placed against the side of a car, and each man picked up from his pile a pig of iron weighing about 92 pounds, walked up the inclined plank and dropped it on the end of the car.

We found that this gang were loading on the average about 12 and a half long tons per man per day. We were surprised to find, after studying the matter, that a first-class pig-iron handler ought to handle between 47, and 48 long tons per day, instead of 12 and a half tons. This task seemed to us so very large that we were obliged to go over our work several times before we were absolutely sure that we were right. Once we were sure, however, that 47 tons was a proper day's work for a first-class pig-iron handler, the task which faced us as managers under the modern scientific plan was clearly before us. It was our duty to see that the 80,000 tons of pig iron was loaded on to the cars at the rate of 47 tons per man per day, in place of 12 and a half tons, at which rate the work was then being done. And it was further our duty to see that this work was done without bringing on a strike among the men, without any quarrel with the men, and to see that the men were happier and better contented when loading at the new rate of 47 tons than they were when loading at the old rate of 12 and a half tons.

Our first step was the scientific selection of the workman. In dealing with workmen under this type of management, it is an inflexible rule to talk to and deal with only one man at a time, since each workman has his own special abilities and limitations, and since we are not dealing with men in masses, but are trying to develop each individual man to his highest state of efficiency and prosperity. Our first step was to find the proper workman to begin with. We therefore carefully watched and studied these 75 men for three or four days, at the end of which time we had picked out four men who appeared to be physically able to handle pig iron at the rate of 47 tons per day. A careful study was then made of each of these men. We looked up their history as far back as practicable and thorough inquiries were made as to the character, habits, and the ambition of each of them. Finally we selected one from among the four as the most likely man to start with. He was a little Pennsylvania Dutchman who had been observed to trot back home for a mile or so after his work in the evening about as fresh as he was when he came trotting down to work in the morning. We found that upon wages of $1.15 a day he had succeeded in buying a small plot of ground, and that he was engaged in putting up the walls of a little house for himself in the morning before starting to work and at night after leaving. He also had the reputation of being exceedingly "close," that is, of placing a very high value on a dollar. As one man whom we talked to about him said, "A penny looks about the size of a cart-wheel to him." This man we will call Schmidt.

The task before us, then, narrowed itself down to getting Schmidt to handle 47 tons of pig iron per day and making him glad to do it. This was done as follows. Schmidt was called out from among the gang of pig-iron handlers and talked to somewhat in this way:

"Schmidt, are you a high-priced man?"


"Vell, I don't know vat you mean."

"Oh yes, you do. What I want to know is whether you are a high-priced man or not."

"Vell, I don't know vat you mean."

"Oh, come now, you answer my questions. What I want to find out is whether you are a high-priced man.  What I want to find out is whether you want to earn $1.85 a day or whether you are satisfied with $1.15, just the same as all others are getting."

"Did I want $1.85 a day? Was dot a high-priced man? Well, yes, I was a high-priced man."

"Oh, You see that pile of pig iron?"


"Yes."

"You see that car?"

"Yes."

"Well, if you are a high-priced man, you will load that pig iron on that car tomorrow for $1.85. Now do wake up and answer my question. Tell me whether you are a high-priced man or not."

"Vell, did I got $1.85 for loading dot pig iron on dot car to-morrow?"

"Yes, of course you do, and you get $1.85 for loading a pile like that every day right through the year. That is what a high-priced man does, and you know it just as well as I do."

"Vell, dot's all right. I could load dot pig iron on the car to-morrow for $1.85, and I get it every day, don't I?"

"Certainly you do--certainly you do."

"Vell, den, I vas a high-priced man."

"Well, if you are a high-priced man, you will do exactly as this man tells you tomorrow, from morning till night. When he tells you to pick up a pig and walk, you pick it up and you walk, and when he tells you to sit down and rest, you sit down. You do that right straight through the day. And what's more, no back talk. Now a high-priced man does just what he's told to do, and no back talk. Do you understand that? When this man tells you to walk, you walk; when he tells you to sit down, you sit down, and you don't talk back at him. Now you come on to work here to-morrow morning and I'll know before night whether you are really a high-priced man or not."

Schmidt started to work, and all day long, and at regular intervals, was told by the man who stood over him with a watch, "Now pick up a pig and walk. Now sit down and rest. Now walk--now rest," etc. He worked when he was told to work, and rested when he was told to rest, and at half-past five in the afternoon had his 47 and a half tons loaded on the car. And he practically never failed to work at this pace and do the task that was set him during the three years that the writer was at Bethlehem. And throughout this time he averaged a little more than $1.85 per day, whereas before he had never received over $1.15 per day, which was the ruling rate of wages at that time in Bethlehem. That is, he received 60 per cent. higher wages than were paid to other men who were not working on task work. One man after another was picked out and trained to handle pig iron at the rate of 47 and a half tons per day until all of the pig iron was handled at this rate, and the men were receiving 60 per cent. more wages than other workmen around them.

The writer has given above a brief description of three of the four elements which constitute the essence of scientific management: first, the careful selection of the workman, and, second and third, the method of first inducing and then training and helping the workman to work according to the scientific method. Nothing has as yet been said about the science of handling pig iron. The writer trusts, however, that before leaving this illustration the reader will be thoroughly convinced that there is a science of handling pig iron, and further that this science amounts to so much that the man who is suited to handle pig iron cannot possibly understand it, nor even work in accordance with the laws of this science, without the help of those who are over him.


Pig Iron Handling - Further explanation


The law is confined to that class of work in which the limit of a man's capacity is reached because he is tired out. It is the law of heavy laboring, corresponding to the work of the cart horse, rather than that of the trotter. Practically all such work consists of a heavy pull or a push on the man's arms, that is, the man's strength is exerted by either lifting or pushing something which he grasps in his hands. And the law is that for each given pull or push on the man's arms it is possible for the workman to be under load for only a definite percentage of the day. For example, when pig iron is being handled (each pig weighing 92 pounds), a first-class workman can only be under load 43 per cent of the day. He must be entirely free from load during 57 per cent of the day.

And as the load becomes lighter, the percentage of the day under which the man can remain under load increases. So that, if the workman is handling a half-pig, weighing 46 pounds, he can then be under load 58 per cent of the day, and only has to rest during 42 per cent. As the weight grows lighter the man can remain under load during a larger and larger percentage of the day, until finally a load is reached which he can carry in his hands all day long without being tired out. When that point has been arrived at this law ceases to be useful as a guide to a laborer's endurance, and some other law must be found which indicates the man's capacity for work.

When a laborer is carrying a piece of pig iron weighing 92 pounds in his hands, it tires him about as much to stand still under the load as it does to walk with it, since his arm muscles are under the same severe tension whether he is moving or not. A man, however, who stands still under a load is exerting no horse-power whatever, and this accounts for the fact that no constant relation could be traced in various kinds of heavy laboring work between the foot-pounds of energy exerted and the tiring effect of the work on the man. It will also be clear that in all work of this kind it is necessary for the arms of the workman to be completely free from load (that is, for the workman to rest) at frequent intervals. Throughout the time that the man is under a heavy load the tissues of his arm muscles are in process of degeneration, and frequent periods of rest are required in order that the blood may have a chance to restore these tissues to their normal condition.

-----------------------

To return now to our pig-iron handlers at the Bethlehem Steel Company. If Schmidt had been allowed to attack the pile of 47 tons of pig iron without the guidance or direction of a man who understood the art, or science, of handling pig iron, in his desire to earn his high wages he would probably have tired himself out by 11 or 12 o'clock in the day. He would have kept so steadily at work that his muscles would not have had the proper periods of rest absolutely needed for recuperation, and he would have been completely exhausted early in the day. By having a man, however, who understood this law, stand over him and direct his work, day after day, until he acquired the habit of resting at proper intervals, he was able to work at an even gait all day long without unduly tiring himself.

Now one of the very first requirements for a man who is fit to handle pig iron as a regular occupation that he shall be so stupid and so phlegmatic that he more nearly resembles in his mental make-up the ox than any other type. The man who is mentally alert and intelligent is for this very reason entirely unsuited to what would, for him, be the grinding monotony of work of this character. Therefore the workman who is best suited to handling pig iron is unable to understand the real science of doing this class of work. He is so stupid that the word "percentage" has no meaning to him, and he must consequently be trained by a man more intelligent than himself into the habit of working in accordance with the laws of this science before he can be successful.

The writer trusts that it is now clear that even in the case of the most elementary form of labor that is known, there is a science, and that when the man best suited to this class of work has been carefully selected, when the science of doing the work has been developed, and when the carefully selected man has been trained to work in accordance with this science, the results obtained must of necessity be overwhelmingly greater than those which are possible under the plan of "initiative and incentive."

Let us, however, again turn to the case of these pig-iron handlers, and see whether, under the ordinary type of management, it would not have been possible to obtain practically the same results.

The writer has put the problem before many good managers, and asked them whether, under premium work, piece work, or any of the ordinary plans of management, they would be likely even to approximate 47 tons* per man per day, and not a man has suggested that an output of over 18 to 25 tons could be attained by any of the ordinary expedients. It will be remembered that the Bethlehem men were loading only 12 1/2 tons per man.

[*Footnote: Many people have questioned the accuracy of the statement that first-class workmen can load 47 1/2 tons of pig iron from the ground on to a car in a day. For those who are skeptical, therefore, the following data relating to this work are given:

First. That our experiments indicated the existence of the following law: that a first-class laborer, suited to such work as handling pig iron, could be under load only 42 per cent of the day and must be free from load 58 per cent of the day.

Second. That a man in loading pig iron from piles placed on the ground in an open field on to a car which stood on a track adjoining these piles, ought to handle (and that they did handle regularly) 47 1/2 long tons (2240 pounds per ton) per day.

That the price paid for loading this pig iron was 3.9 cents per ton, and that the men working at it averaged $1.85 per day, whereas, in the past, they had been paid only $1.15 per day.

In addition to these facts, the following are given:

  47 1/2 long tons equal 106,400 pounds of pig iron per day.
  At 92 pounds per pig, equals 1156 pigs per day.
  42 per cent. of a day under load equals 600 minutes; multiplied by   0.42 equals 252 minutes under load.
  252 minutes divided by 1156 pigs equals 0.22 minutes per pig under  load.

A pig-iron handler walks on the level at the rate of one foot in 0.006 minutes. The average distance of the piles of pig iron from the car was 36 feet. It is a fact, however, that many of the pig-iron handlers ran with their pig as soon as they reached the inclined plank. Many of them also would run down the plank after loading the car. So that when the actual loading went on, many of them moved at a faster rate than is indicated by the above figures. Practically the men were made to take a rest, generally by sitting down, after loading ten to twenty pigs. This rest was in addition to the time which it took them to walk back from the car to the pile. It is likely that many of those who are skeptical about the possibility of loading this amount of pig iron do not realize that while these men were walking back they were entirely free from load, and that therefore their muscles had, during that time, the opportunity for recuperation. It will be noted that with an average distance of 36 feet of the pig iron from the car, these men walked about eight miles under load each day and eight miles free from load.  If any one who is interested in these figures will multiply them and divide them, one into the other, in various ways, he will find that all of the facts stated check up exactly.]

To go into the matter in more detail, however: As to the scientific selection of the men, it is a fact that in this gang of 75 pig-iron handlers only about one man in eight was physically capable of handling 47 1/2 tons per day. With the very best of intentions, the other seven out of eight men were physically unable to work at this pace. Now the one man in eight who was able to do this work was in no sense superior to the other men who were working on the gang. He merely happened to be a man of the type of the ox,--no rare specimen of humanity, difficult to find and therefore very highly prized. On the contrary, he was a man so stupid that he was unfitted to do most kinds of laboring work, even. The selection of the man, then, does not involve finding some extraordinary individual, but merely picking out from among very ordinary men the few who are especially suited to this type of work. Although in this particular gang only one man in eight was suited to doing the work, we had not the slightest difficulty in getting all the men who were needed--some of them from inside of the works and others from the neighboring country--who were exactly suited to the job.

Under the management of "initiative and incentive" the attitude of the management is that of "putting the work up to the workmen." What likelihood would there be, then, under the old type of management, of these men properly selecting themselves for pig-iron handling? Would they be likely to get rid of seven men out of eight from their own gang and retain only the eighth man? No! And no expedient could be devised which would make these men properly select themselves. Even if they fully realized the necessity of doing so in order to obtain high wages (and they are not sufficiently intelligent properly to grasp this necessity), the fact that their friends or their brothers who were working right alongside of them would temporarily be thrown out of a job because they were not suited to this kind of work would entirely prevent them from properly selecting themselves, that is, from removing the seven out of eight men on the gang who were unsuited to pig-iron handling.

As to the possibility, under the old type of management, of inducing these pig-iron handlers (after they had been properly selected) to work in accordance with the science of doing heavy laboring, namely, having proper scientifically determined periods of rest in close sequence to periods of work. As has been indicated before, the essential idea of the ordinary types of management is that each workman has become more skilled in his own trade than it is possible for any one in the management to be, and that, therefore, the details of how the work shall best be done must be left to him. The idea, then, of taking one man after another and training him under a competent teacher into new working habits until he continually and habitually works in accordance with scientific laws, which have been developed by some one else, is directly antagonistic to the old idea that each workman can best regulate his own way of doing the work. And besides this, the man suited to handling pig iron is too stupid properly to train himself. Thus it will be seen that with the ordinary types of management the development of scientific knowledge to replace rule of thumb, the scientific selection of the men, and inducing the men to work in accordance with these scientific principles are entirely out of the question. And this because the philosophy of the old management puts the entire responsibility upon the workmen, while the philosophy of the new places a great part of it upon the management.

Although the reader may be convinced that there is a certain science back of the handling of pig iron, still it is more than likely that he is still skeptical as to the existence of a science for doing other kinds of laboring. One of the important objects of this paper is to convince its readers that every single act of every workman can be reduced to a science. With the hope of fully convincing the reader of this fact, therefore, the writer proposes to give several more simple illustrations from among the thousands which are at hand.

Illustration of Shoveling


For example, the average man would question whether there is much of any science in the work of shoveling. Yet there is but little doubt, if any intelligent reader of this paper were deliberately to set out to find what may be called the foundation of the science of shoveling, that with perhaps 15 to 20 hours of thought and analysis he would be almost sure to have arrived at the essence of this science. On the other hand, so completely are the rule-of-thumb ideas still dominant that the writer has never met a single shovel contractor to whom it had ever even occurred that there was such a thing as the science of shoveling. This science is so elementary as to be almost self-evident.

For a first-class shoveler there is a given shovel load at which he will do his biggest day's work. What is this shovel load? Will a first-class man do more work per day with a shovel load of 5 pounds, 10 pounds, 15 pounds, 20, 25, 30, or 40 pounds? Now this is a question which can be answered only through carefully made experiments. By first selecting two or three first-class shovelers, and paying them extra wages for doing trustworthy work, and then gradually varying the shovel load and having all the conditions accompanying the work carefully observed for several weeks by men who were used to experimenting, it was found that a first-class man would do his biggest day's work with a shovel load of about 21 pounds. For instance, that this man would shovel a larger tonnage per day with a 21-pound load than with a 24-pound load or than with an 18-pound load on his shovel. It is, of course, evident that no shoveler can always take a load of exactly 21 pounds on his shovel, but nevertheless, although his load may vary 3 or 4 pounds one way or the other, either below or above the 21 pounds, he will do his biggest day's work when his average for the day is about 21 pounds.

The writer does not wish it to be understood that this is the whole of the art or science of shoveling. There are many other elements, which together go to make up this science. But he wishes to indicate the important effect which this one piece of scientific knowledge has upon the work of shoveling.

At the works of the Bethlehem Steel Company, for example, as a result of this law, instead of allowing each shoveler to select and own his own shovel, it became necessary to provide some 8 to 10 different kinds of shovels, etc., each one appropriate to handling a given type of material not only so as to enable the men to handle an average load of 21 pounds, but also to adapt the shovel to several other requirements which become perfectly evident when this work is studied as a science. A large shovel tool room was built, in which were stored not only shovels but carefully designed and standardized labor implements of all kinds, such as picks, crowbars, etc. This made it possible to issue to each workman a shovel which would hold a load of 21 pounds of whatever class of material they were to handle: a small shovel for ore, say, or a large one for ashes. Iron ore is one of the heavy materials which are handled in a works of this kind, and rice coal, owing to the fact that it is so slippery on the shovel, is one of the lightest materials. And it was found on studying the rule-of-thumb plan at the Bethlehem Steel Company, where each shoveler owned his own shovel, that he would frequently go from shoveling ore, with a load of about 30 pounds per shovel, to handling rice coal, with a load on the same shovel of less than 4 pounds. In the one case, he was so overloaded that it was impossible for him to do a full day's work, and in the other case he was so ridiculously underloaded that it was manifestly impossible to even approximate a day's work.

Briefly to illustrate some of the other elements which go to make up the science of shoveling, thousands of stop-watch observations were made to study just how quickly a laborer, provided in each case with the proper type of shovel, can push his shovel into the pile of materials and then draw it out properly loaded. These observations were made first when pushing the shovel into the body of the pile. Next when shoveling on a dirt bottom, that is, at the outside edge of the pile, and next with a wooden bottom, and finally with an iron bottom. Again a similar accurate time study was made of the time required to swing the shovel backward and then throw the load for a given horizontal distance, accompanied by a given height. This time study was made for various combinations of distance and height. With data of this sort before him, coupled with the law of endurance described in the case of the pig-iron handlers, it is evident that the man who is directing shovelers can first teach them the exact methods which should be employed to use their strength to the very best advantage, and can then assign them daily tasks which are so just that the workman can each day be sure of earning the large bonus which is paid whenever he successfully performs this task.

There were about 600 shovelers and laborers of this general class in the yard of the Bethlehem Steel Company at this time. These men were scattered in their work over a yard which was, roughly, about two miles long and half a mile wide. In order that each workman should be given his proper implement and his proper instructions for doing each new job, it was necessary to establish a detailed system for directing men in their work, in place of the old plan of handling them in large groups, or gangs, under a few yard foremen. As each workman came into the works in the morning, he took out of his own special pigeonhole, with his number on the outside, two pieces of paper, one of which stated just what implements he was to get from the tool room and where he was to start to work, and the second of which gave the history of his previous day's work; that is, a statement of the work which he had done, how much he had earned the day before, etc. Many of these men were foreigners and unable to read and write, but they all knew at a glance the essence of this report, because yellow paper showed the man that he had failed to do his full task the day before, and informed him that he had not earned as much as $1.85 a day, and that none but high-priced men would be allowed to stay permanently with this gang. The hope was further expressed that he would earn his full wages on the following day. So that whenever the men received white slips they knew that everything was all right, and whenever they received yellow slips they realized that they must do better or they would be shifted to some other class of work.

Dealing with every workman as a separate individual in this way involved the building of a labor office for the superintendent and clerks who were in charge of this section of the work. In this office every laborer's work was planned out well in advance, and the workmen were all moved from place to place by the clerks with elaborate diagrams or maps of the yard before them, very much as chessmen are moved on a chess-board, a telephone and messenger system having been installed for this purpose. In this way a large amount of the time lost through having too many men in one place and too few in another, and through waiting between jobs, was entirely eliminated. Under the old system the workmen were kept day after day in comparatively large gangs, each under a single foreman, and the gang was apt to remain of pretty nearly the same size whether there was much or little of the particular kind of work on hand which this foreman had under his charge, since each gang had to be kept large enough to handle whatever work in its special line was likely to come along.

When one ceases to deal with men in large gangs or groups, and proceeds o study each workman as an individual, if the workman fails to do his task, some competent teacher should be sent to show him exactly how his work can best be done, to guide, help, and encourage him, and, at the same time, to study his possibilities as a workman. So that, under the plan which individualizes each workman, instead of brutally discharging the man or lowering his wages for failing to make good at once, he is given the time and the help required to make him proficient at his present job, or he is shifted to another class of work for which he is either mentally or physically better suited.

All of this requires the kindly cooperation of the management, and involves a much more elaborate organization and system than the old-fashioned herding of men in large gangs. This organization consisted, in this case, of one set of men, who were engaged in the development of the science of laboring through time study, such as has been described above; another set of men, mostly skilled laborers themselves, who were teachers, and who helped and guided the men in their work; another set of tool-room men who provided them with the proper implements and kept them in perfect order, and another set of clerks who planned the work well in advance, moved the men with the least loss of time from one place to another, and properly recorded each man's earnings, etc. And this furnishes an elementary illustration of what has been referred to as cooperation between the management and the
workmen.



F.W. Taylor, Scientific Management

All Chapters
F.W. Taylor Scientific Management - With Appropriate Sections

Ud 28 Sep 2021
Pub 5.12.2020

L.D. Miles - 13 Value Analysis and Engineering Techniques

Lesson 38 of Industrial Engineering ONLINE Course

13 techniques proposed by L.D. Miles, the founder of value analysis and engineering


____________________________________________________________________

Value analysis techniques help in identifying the potential or scope for redesign by showing the opportunity for lower cost alternatives. The analytical idea forces one to search and think in particular directions that uncover lower cost sources for value engineering. These lower cost alternatives provide direction and value engineering, that is engineering to increase value (by reducing cost) has to be done as an engineering activity. Value engineer is basically an engineer and value analysis provides to direction or idea to him to redesign the component or product or a feature of the component.

Value Analysis Techniques


Miles provided 13 ideas as value analysis techniques (Each technique linked to a video).
 
  1. Avoid generalities
  2. Get all available costs
  3. Use information from the best source
  4. Blast create and refine
  5. Use real creativity
  6. Identify and overcome roadblocks
  7. Use industry experts to extend specialized knowledge
  8. Get a dollar sign on key tolerances
  9. Utilize vendors’ available functional products
  10. Utilize and pay for vendors’ skills and knowledge
  11. Utilize specialty processes
  12. Utilize applicable standards
  13. Use the criterion, “would I spend my money this way?”
The list in above order was given by Miles in his first edition of the book. The order can be changed to study the techniques in a sequential process way.

Value Analysis Techniques of Miles in a different order


Analysis techniques for creating low cost alternatives

1. Blast, Create and Refine
2. Utilize vendors’ available functional products
3. Utilize specialty processes
4. Utilize applicable standards
5.Use the criterion, “would I spend my money this way?”

Information needed to start the activity and to analyze

6. Avoid generalities
7. Get all available costs
8. Use information from the best source 
9. Get a dollar sign on key tolerances

During the value engineering process use real creativity to come up with useful and novel solutions that use the ideas generated during value analysis. 

9. Use real creativity

This will motivate you to focus on the issue and come with alternatives

Use outside expertise also to come with value enhancing suggestions and their development 


11. Use industry experts to extend specialized knowledge
12. Utilize and pay for vendors’ skills and knowledge

Be ready for roadblocks after you come out with a solution

13. Identify and overcome roadblocks

Read the excerpts of the chapter in
https://books.google.co.in/books?id=XxhbDwAAQBAJ&pg=PT119#v=onepage&q&f=false

The book is available as E-Book for Rs. 124.78

Brief Explanation of the VE Analytical Techniques 

1. Blast, Create and Refine

Blast
To do blast activity, the basic functions to be accomplished by a product or a component are given the focus and alternative products, materials and processes are brought into the picture. These alternatives need not entirely accomplish all the basic functions completely. These alternatives need to qualify on the basis of accomplishing some important part of the function or functions in a very economical manner. The alternatives are in the consideration list even if they can accomplish important part of the function based on some modifications. During this activity, the amount of the function which would be accomplished by the suggested or identified alternatives and the cost involved are ascertained.

Create
Use real creativity to generate alternatives to  improve the ideas of blast stage, to accomplish large part of the required function with accompanying increase in cost. Increase in functions obtained needs to be accounted by increase in cost.

Refine
The solution obtained in create stage is further sifted and refined by adding features which provide further functions and fully accomplish the desired function. Miles stated that this blast, create and refine technique delivered the total function with the same reliability but at a cost of one-half to one-tenth of the original for many components and products.



________________


________________

2. Utilize vendors’ available functional products

Number of products like special hinges, special rivets, special tapered structural shapes etc. are available to perform various functions from vendors. Available functional products (even though not standard but special) have low costs because the specialty supplier has a sufficient lead in his particular technology and sufficient volume.

But there are interfering factors that prevent engineers from using the available functional products and they design items for their products afresh. Miles identified some of them as lack of knowledge regarding the availability of the items, preference for do-it-ourselves, feeling that boss wants me to design, inhouse design shows our capability thinking, feeling that own designs are proprietary knowledge, problems of search, and feeling that we can improve over a period of time etc.

Miles recommends preparing functional product lists and specially creating lists for items that are not usually bought.


3. Utilize specialty processes and special tools


Miles defines specialty process as an applicable process which would reliably accomplish the needed function for significantly lower cost and which either exists or could, and would be developed by some one who leads in the technology involved if he understood the need for it.

Miles gave the opinion that even persons engaged in value work take time to recognize specialty processes. In 1961, he gave the delay as three years. Other engineers take around 10 years to recognize specialty processes. The purpose of identifying and emphasizing this point in the list of VE techniques is to reduce this time lag.

Special tools also provide value opportunities. Value engineers have to be on the lookout for appearance of special tools.

____________

___________

4. Utilize applicable standards

Miles has written that including in the list of techniques and highlighting it may look silly, but it is a valuable technique in VE application.

The full meaning includes utilization of standard parts, parts of standard products, engineering concepts, manufacturing concepts, manufacturing processes and materials. He also emphasized that where not applicable standard items should not be used.


5. Use information from the best source


This point is relevant to the issue of overcoming roadblocks to various value suggestions. In one example, a component, a cover of an item was judged to be redundant. The designer said it was required by the customers. When the value engineer approached the sales person, he was told that only one customer uses the item with the cover and all others actually remove the cover and use it. Hence the initial idea that the cover was redundant was right. So the suggestion is that information from the best and ultimate source is to be only used for decision making in value work.



___________________

___________________

6. Get a dollar sign on key tolerances

Tolerances are required to obtain necessary fit or to allow assembly.
But many times tolerances are specified as standard practice and to give the impression of a complete drawing. Tolerances have cost.
For efficient use in value work each tolerance is to subjected to the following questions.
i) What does it cost?
ii) What function does it provide?
If the cost of tolerance is trifling, it did not be analyzed further. But if it is substantial in the process cost, it is to be analyzed.

7. Use real creativity

Creativity is generating alternatives.  Creative people believe that there are many ways of doing a thing. Miles made the observation that many creative people believe there are at least eight ways of doing a thing. They are not satisfied when they find one way.

In value analysis, creativity is to be applied as soon as the function desired is brought out in specifics. The most common obstacle to creative thinking is natural tendency to let judicial thinking work along. It interferes.  What is required is to suspend judicial thinking and let the ideas flow. Creativity is not associated with only complex problems. Even simple things can have creative alternatives. Creativity can be sustained and more alternatives can be generated in a group brainstorming.


__________________


___________________

8. Identify and overcome roadblocks

A roadblock is a decision that prevents value alternatives. The decisions could be due to lack of information, acceptance of wrong information and wrong belief on the part of the decision maker.  The value engineers have to recognize the roadblocks, and provide more correct information with proper timing and presentation so that the decision maker will use it.

___________________


___________________

9. Avoid generalities

Many times general statements are used to stop value alternatives from proceeding further. Examples given by Miles include:
* It's not practical to build dies for drop forging when quantities are less than 25,000 per order.
* It's not practical to build molds for casting in quantities of less than 5,000.
But a value engineer needs to make inquiries. Parts vary in complexity and material may make a difference.  There will be advancements in diemaking and as well as in diemaking machines. Instead stopping with general statements, value engineer needs to make specific inquiries.


________________


________________

10. Get all available costs

Cost data are produced in companies to support financial statements and tax statements. Hence a value engineer has to get all available costs and assess their utility for his decision making purpose. When costs are utilized for decision making they have to make economic sense. An example was given by Miles, wherein inappropriate cost allocations and decision report higher cost figures for an item.


_________________


_________________

11. Use industry experts to extend specialized knowledge

The quality of answers to value problems is dependent upon the depth of penetration of the subject matter brought to bear on the problem. It has to be noted that knowledge, techniques and processes are continually being developed in each technology and that only the specialists know of those which have become practical with the last year or two. Value engineers have to bring these experts into their value projects and try and get best answers to the attainment of functions desired.

12. Utilize and pay for vendors’ skills and knowledge

There are suppliers with skills to develop special products at low prices. They continuously upgrade their skills and are looking out for opportunities applying their technology. Users benefit by contacting them and posing their function fulfillment problems.  These suppliers spend time and come out with solutions. Whenever they come up with good value solutions, they need to be rewarded with orders. There have to fair relations between suppliers and company.

13. Use the criterion, “would I spend my money this way?”

Miles documents that an average person evaluates his personal expenditures in the following steps.
A limited amount is allocated for the purpose.
Effort is done to secure maximum use function and appearance function from the expenditure. For this, he generates number of alternatives or considers number of alternatives. He will make a comparison of relative use values, esteem values and cost to make a decision.

Design engineers, manufacturing engineers, purchasing personnel and management have to follow similar procedure for organizational decision making also.

Extension of


     
Updated on 28 September 2021, 8 July 2021,  24 June 2020,  16 May 2020,   17 July 2019, 29 August 2018
First published on Blog 30 March 2012 from Knol
Original knol - http://knol.google.com/k/narayana-rao/ value-analysis-and-engineering/ 2utb2lsm2k7a/  3887

Monday, September 27, 2021

Skoda Auto - Modernisation and Improvement of Coordinate Measuring Machines (CMMs)


Case Study 132


2021


Skoda Auto - Modernisation and Improvement of Coordinate Measuring Machines (CMMs)

Automated optical measurement as an engine of modernisation and innovation

HxGN-Robotic-Auotmation-Skoda-Software-and-Tracker

Hexagon and Å KODA AUTO have been measurement partners for decades. At the end of 2018,  the companies concluded an agreement to reconfigure  inspection processes for 3D optical systems instead of tactile measurement. This programme has resulted in a significant increase in measurement capacity and quality, as well as the digitalisation of outputs from measuring devices.

This was achieved through the modernisation of several installed coordinate measuring machines (CMMs). It also resulted in a unique installation of two fully automated smart measuring cells for the measuring centre in Mladá Boleslav.

In terms of software, the measuring cell is equipped with Hexagon’s leading metrology platform PC-DMIS. The use of a single software platform across the factories has a number of practical advantages, such as the uniform integration of VW Group measuring principles directly into PC-DMIS. It has also added technical value in the possibility for the offline preparation of measuring programs.

A significant shift in the development of PC-DMIS in recent years has made it possible to take full advantage of offline programming. The operators of the new measurement cells in Mladá Boleslav have been able to make the most of this capacity, which allows them to start measuring very quickly when the production of new parts is launched.

In the new HxGN Robotic Automation software, which Hexagon officially launched in 2021, this offline programming functionality within PC-DMIS can now be more fully taken advantage of in the context of optical robotic measurement.

HxGN-Robotic-Auotmation-Skoda-Case-T-Scan-5

“The HxGN Robotic Automation software significantly reduces the time required for the offline programming of robotic measurement and the debugging of measurement programs. ”

“Hexagon’s fully robotic measuring cells are the first embodiment of  “The HxGN Robotic Automation software" in the field of optical measurement. It is is just the beginning. More projects will follow as soon as possible to  use the HxGN Robotic Automation Software for in-line and at-line measurement. 


Tailor-made smart solution

The measuring cell itself is based on robotic absolute measurement powered by the large-volume measuring capabilities of Hexagon’s advanced laser tracker and 3D laser scanner technology.  “The Leica Absolute Tracker AT960 is capable of six degrees of freedom (6DoF) measurement as standard, allowing the use of a 3D laser scanner or probe from up to 60 metres away."

Magnetic fixturing system “Ensuring fully automated control of the dimensions, shapes and positions of measured elements is then just a matter of programming using a unique combination of integrated Hexagon accessories within the cell – from interconnected metrology and programming software, selected rotary tables and flexible fixtures to the new cell control system architecture. The system as configured ensures fast data exchange between all peripherals and therefore enables the automatic creation of measuring programs based on CAD data of parts and jigs, as well as measurement simulation, the precise positioning of clamping jigs according to reference points, and last but not least the fast evaluation of large volumes of scanned data into graphically presented measurement results.” 

The robotic measuring cell concept now in place in Mladá Boleslav arose from close cooperation between ŠKODA AUTO and Hexagon, and the resulting solution that was installed within a few months is a prototype tailored specifically to the needs of the measuring centre in this location. The system was designed to deliver the versatility the centre needed, with an installed tool changer unit allowing for direct automated switching between high-speed scanning and more accurate tactile measurement. This variability means the system will always be able to perform measurement of difficult-to access areas, such as openings, in a way that would simply not be possible for a less bespoke solution.

Extended use for the FIVE U-nique fixturing system

The smart cells also contain two workstations with rotary tables that use the flexible magnetic FIVE U-nique fixturing system, which allows accurate fixtures to be rapidly built for an unlimited number of part configurations to provide support and reference to the workpiece. The FIVE U-nique system provides considerable flexibility to automated measurement processes due to its reduced installation time, allowing for fast changes between configurations. 

The reference position of each part-holding fixture is automatically determined from the CAD data of the part. The robot enters this position with a special tool from the tool changer and thus determines the final position and height of the fixture for the location. Thanks to this, a quick readjustment of the jigs for all measured parts is ensured, which significantly reduces the financial demands of acquiring and storing individual fixed configuration jigs for every part.  

The accuracy of the jig placement is defined by the accuracy of the measuring system, in this case a high accuracy laser tracker and scanner. This system measures the position of the robot as it positions the part-holding fixtures, and subsequent iteration ensures zero deviation from the reference position. The well-established FIVE U-nique system has previously been used to position parts exclusively in coordinate measuring machines, but this new concept developed especially for Å KODA AUTO demonstrates how this trusted solution can still play a role in the world of smart manufacturing.

Service and support as standard

Following this successful implementation, Å KODA AUTO continues to credit their strong partnership with Hexagon to the constant support of Hexagon’s service technicians and application engineers, supported by an accessible and user-friendly training system.

https://www.hexagonmi.com/solutions/case-studies/automotive/automated-optical-measurement-as-an-engine-of-modernisation-and-innovation 







Productivity through Flexible Manufacturing System - Case Study - Prince Industries

Industrial Engineering ONLINE Course - Main Page

Industrial Engineering Case Studies Collection

Prince Industries Uses Flexible Manufacturing System 


THE CHALLENGE

Prince Industries of Carol Stream, Ill., is a precision contract manufacturer of machine components, assemblies, hydraulic valves and fabrications. 

The company wanted to expand through a flexible manufacturing system in order to reduce setups  and have the ability to deliver a completed part from the design to production stage in a shorter period of time.

The company invested in these five machines:

   •  A MMC2 modular machining complex with 161 pallet stations

   •  Two a61 horizontal machining centers with automatic tool changers

   •  Two a71 horizontal machining center for heavier machining on cast iron

   •  A S33 vertical machining center with dual pallet changer

In one work cell at Prince, there are two a61 machines, an a71 and the MMC2 system. This flexible manufacturing cell is used for high-mix and low- to medium-volume orders.

The S33 machine provides Prince with a flexible mini-cell for quick setup and changeovers. This cell is used for running short, flat parts of 10 to 15 count batches with the automatic pallet changer.

Benefits obtained

Prince runs 24 full pallets of work around the clock, seven days a week. A part has never been rejected, and all scrap has been eliminated. Every part comes off of the cell and goes straight to the customer.

Productivity per hour increased by 50 percent as Prince is able to go from producing three to four parts per hour on stand-alone machines to six parts per hour. 

If the company receives an order from a customer, it can acquire material the same day, provide one setup and then start production immediately. In addition, customers with lower volume jobs receive the same part cost as they had with mass production runs.

Quality has increased. Prince can manage three-dimensional parts having tight tolerances on several different positions, with diameter tolerances of 0.00052 inches. The company estimates it’s saving 20 to 30 percent in cycle time on tool changes alone. It runs a flexible manufacturing system for 22 hours a day and has yet to have one rejected part come across its machines.

The new cell requires less setup and  labor. Operator intervention has been reduced from one operator per machine per shift to one operator per three to four machines per shift. Prince can run three jobs simultaneously while the operator prepares the next three jobs within the cell.

It is estimated that  the MMC2 and associated horizontal machines will have paid for themselves in one and a half years.

The tools that were added to the S33 mini-cell eliminate post-production deburring, saving on benchwork, cleanup washing and post-production time. This efficiency gain eliminates another 5 to 10 percent in cycle time.

 

https://www.makino.com/resources/content-library/case-study/archive/prince-industries-uses-flexible-manufacturing-system-to-quickly-bring-products-to-market-/624


https://www.competitiveproduction.com/articles/crowning-achievement/




Flexible Manufacturing System A Modern Approach To Manufacturing Technology

April 2016

http://www.irjes.com/Papers/vol5-issue4/C541623.pdf


Implementation Of Flexible Manufacturing System (FMS) And Its Quantitative Analysis For Pump

Industries

MARCH 2020

http://www.ijstr.org/final-print/mar2020/Implementation-Of-Flexible-Manufacturing-Systemfms-And-Its-Quantitative-Analysis-For-Pump-Industries.pdf


FMS productivity variables

1) Training;

2) Financial incentive;

3) Unit labour cost;

4) Effect of tool life;

5) Customer satisfaction;

6) Reduction in scrap percentage;

7) Reduction in rework percentage;

8) Reduction of rejection;

9) Equipment utilization;

10) Trained worker;

11) Manufacturing lead time & setup time;

12) Unit manufacturing cost;

13) Throughput time;

14) Set up cost;

15) Automation ;

16) Use of automated material handling devices;

17) Reduction in material flow;

18) Reduced work in process inventory;

19) Capacity to handle new product;

20) Ability of manufacturing of variety of product

Modelling and analysis of FMS productivity variables by ISM, SEM and GTMA approach

Article  in  Frontiers of Mechanical Engineering · September 2014 


Context-sensitive optimisation of the key performance indicators for FMS
Mohammad Kamal Uddin,Juha Puttonen &Jose Luis Martinez Lastra
International Journal of Computer Integrated Manufacturing 
Volume 28, 2015 - Issue 9, Pages 958-971 
https://www.tandfonline.com/doi/ref/10.1080/0951192X.2014.941403

UD -21 May 2021

Pub 19 May 2021







Sunday, September 26, 2021

Comau Automation Success Stories - Customer Case Studies

 


Chinese sheet metal fabricator Taren automated its turret punch line using Comau robots. Equipped with integrated material thickness checking and able to deliver 1-min. changeovers, the system produced an estimated 50 percent total cycle time savings.

Welding and plasma equipment manufacturer Cebora partnered with Comau on a robotic cutting application. Compared to a traditional CNC plasma table, the custom configuration is far more flexible and able to handle a wider range of workpiece shapes and sizes.

Automaker Maserati invested in an automated manufacturing system from Comau to assemble and finish the aluminum doors on its SUV line. With 82 robots and integrated material handling, the system can produce multiple vehicle models simultaneously without interruption.

Comau worked with Guangdong Cuifeng Robotics Technology Co., in Dongguan, China, to implement a fully automatic press brake system. It offers real-time production tracking together with material picking, workpiece transfer and palletizing in a single application.

https://weldingproductivity.com/article/purely-automatic/

https://weldingproductivity.com/issues/

https://www.comau.com/en/success-stories/

Comau has integrated innovative arc welding and spot-welding solutions into Vespa’s body production line to ensure high quality products, a perfect finish and flawless aesthetics.

https://www.youtube.com/watch?v=LeWgcrd0iJA

Virtual commissioning  by Comau Using Siemens Software
https://www.plm.automation.siemens.com/global/en/our-story/customers/comau/17585/

Smart Sensors - Comau
https://www.ncbi.nlm.nih.gov/pmc/articles/PMC6387237/

Friday, September 24, 2021

Blog "Industrial Engineering Knowledge Center" Registers 1.5 Million Page Views




24.9.2021. Happy. "Industrial Engineering Knowledge Center" Blog now gets 200 page views per day.


Thank you for the support.
  
Per Week  Pageviews     Unique Pageviews Avg. Time on Page      Entrances
1,405                               1,269                       00:03:39                       939


100,000+ Users

Over the period: May 4 2015-May 10, 2021

According to Google Analytics

New Users: 106,034

Sessions: 138,148

Pageviews: 210,104

Avg. Session Duration: 00:01:37


9 May 2021 - Blog "Industrial Engineering Knowledge Center" has registered 1.5 million page views(hits) in Google Blogger Statistics

https://nraoiekc.blogspot.com


Blog "Industrial Engineering Knowledge Center" - GLOBAL NUMBER ONE BLOG IN INDUSTRIAL ENGINEERING


May 2021 - Last 12 Months

Top 20 Industrial Engineering Online Articles - Most Read

Industrial engineering Principles, Methods Tools and Techniques
http://nraoiekc.blogspot.com/2012/03/industrial-engineering-principles.html

Value Engineering - Examples, Cases and Benefits
http://nraoiekc.blogspot.com/2012/03/value-engineering-examples-cases-and.html

Industrial Engineering ONLINE Course

Principles of Motion Economy -  Details - R.M. Barnes
http://nraoiekc.blogspot.com/2012/02/principles-of-motion-economy-some-more.html

Industrial Engineering - History


Work Study - Work Content Analysis - Basic and Excess Work Contents

2021 Machine Shop Engineering & Technology - Productivity Improvement & Cost Reduction News and Case Studies 


2020 Machine Shop Engineering & Technology and Cost Reduction News

Apple Inc. - Industrial Engineering Activities and Jobs

Toyota TPS - Industrial Engineering Activities and Jobs

Predetermined Motion Time Systems (PMTS)

Functions and Focus Areas of Industrial Engineering - Brief Explanation

Online Handbook of Industrial Engineering - Prof. Narayana Rao

Procter & Gamble - Industrial Engineering & Productivity Activities and Jobs

Top 10 Blogs on Industrial Engineering

Method Study - ILO

Method Study - Case Studies

Application of motion economy Principles to Jig and Fixture Design




Sunday, September 19, 2021

Research Handbook on Work and Well-Being - Burke & Page - Book Information

 

Research Handbook on Work and Well-Being


Ronald J. Burke, Kathryn M. Page

Edward Elgar Publishing, 24-Feb-2017 - Business & Economics - 544 pages


Almost every person works at some point in their lives. The Research Handbook on Work and Well-Being examines the association of particular work experiences with employee and organizational health and performance.


https://books.google.co.in/books?id=i-wTDgAAQBAJ









Friday, September 17, 2021

Two Year M.Tech Industrial Engineering Curriculum

 


I Semester


Introduction to Industrial Engineering

Productivity Science

Process Planning

Design of High Productivity Special Purpose Machines and Automation

Material Handling and Warehousing

Inspection and Quality Control Systems

Productivity Management

Industrial Engineering Economics and Productivity Project Planning 


II Semester


Productivity Engineering

Process Industrial Engineering

Product Industrial Engineering

Human Effort Industrial Engineering

Production Planning and Control

Application of Mathematics and Statistics in Industrial Engineering

Information Technology and Systems for Industrial Engineering

Artificial Intelligence Applications in Industrial Engineering


Summer Term

Institute Industrial Engineering Projects


III Semester

Industry Project

Online Elective Courses (3 can be done in semester 3 or semester 4)

Online Audit Courses


IV Semester


Computer Aided Industrial Engineering

Industry 4.0 Production Systems

Production System Planning

Strategic Planning for Productivity and Industrial Engineering

Managing Industrial Engineering Department

Online Electives  (3 can be done in semester 3 or semester 4)

Online Audit Courses


Online Courses

Simulation and Modelling

Computer Aided Design

Computer Integrated Manufacturing

Productivity Improvement of Additive Manufacturing

Data Analysis for Productivity

Management of Training

Ergonomics

Organizational Behaviour 


 Online Course Modules Created  by Me


Module  of Industrial Engineering ONLINE Course

Modules

 

Saturday, September 11, 2021

Automation Projects in SWEP - Case Study

 The dawn of automation secures SWEP’s heat transfer advancement

September 09, 2021


Industry 4.0 and automation is changing the production landscape for SWEP, world-leading supplier of brazed plate heat exchangers and prefabricated energy transfer stations.


With 30 years of experience and growth, now a global corporation, we are still driven by the same spirit and conviction: to challenge efficiency and make a difference with Brazed Plate Heat Exchangers (BPHEs) that are part of a sustainable future.

A willingness to explore

SWEP has always been willing to test new technologies in the manufacturing process. Early in the company history SWEP choose their own way for the production equipment. One example is pressing steel plates together with the copper foil. We experimented made it work. Another example was the home-made stacking box that was an early automation equipment for press lines solving the straightening, turning, and stacking operations integrated with the press line with huge capacity and productivity increase to follow.

Even if there have been automated functions linked to individual machines, like press lines and test equipment’s it is only in the last 5 years that the real automation journey has taken off, and with quite some pace. Over 20 industrial robots built into automatic assembly lines with vision systems, advanced grippers, sensors, and conveyor systems have been commissioned and more is in the pipeline for the near future and the coming years.

A focus on automation

The strategy behind this automation journey is a clear vision.  Try out in smaller scale, learn from mistakes, and use the experience in new projects to build up internal competence but continue to work with external partners in parallel. To design and own key components and all source code and build the robot cells in modules that can be scaled up and down is important for SWEP to be able to standardize, copy and implement to any of SWEP’s five plants around the world.

Designing and implementing a project

A typical automation project usually starts with internal brainstorming in a small technical group with resources from earlier automation projects and the future owner of the cell. The outcome are early visualizations and simulations models for discussion and comparison. Then external partners get involved with idea input and solution suggestions followed by defined work interfaces and formalized project team. Usually SWEP do the robot programming, design and manufacture key components like grippers, use external consultants for PLC/safety program and external partners for most of the hardware. The philosophy is to build deep and wide internal competence but still utilize external partners that built and seen so many more installations in different industries. External partners also help keeping up the high pace and low prices on robots, for instance, as they source many more than SWEP.

Learning is a constant battle

Another learning in the automation journey is the importance of the planning, logistics and the whole picture. Only machines and automation cells forming islands in production will not give the expected productivity increase and this is where Industry 4.0 come into play, connecting the dots. Here new visualization and simulation tools or digital twins will play an important role. How to plan and balancing the flows, dimensioning the equipment correct, monitor, and communicate between the machines, robot cells and business systems. Building a model of a production flow as it is today can help optimize production output through machine utilization, changed order sequence and bottle neck analyses. Completely new scenarios of the future vision can be built up and analyzed to make the correct investment decisions, choosing the right technologies and dimensioning machines, robot cells, stock, buffers, and carrier capacity. This will be very valuable when entering the world of automated guided vehicles, AGV, which will be the next big automation step for SWEP.

Source

https://www.swep.net/company/news-and-media/news/2021/09/the-dawn-of-automation-secures-sweps-heat-transfer-advancement/

Industrial Engineering of Systems - System Industrial Engineering



First published in this blog. Saturday, September 22, 2012

Industrial Engineering of Systems - System Industrial Engineering

Industrial engineers work on functional designs created by various engineers and managers and make them more efficient by improving resource use efficiency. Industrial engineers are to be associated with systems design or engineering process to make systems more efficient right from the first design stage. Presentation at a Global Conference on the topic (made in 2010 in Tokyo) is included in the article.


Author: Narayana Rao

All Rights Reserved

Last edited Version 8: 05 Aug 2010 on Knol

Original URL: http://knol.google.com/k/-/-/  2utb2lsm2k7a/ 2037


 

Have you industrial engineered your systems?

 The Toyota man,  Ohno said industrial engineering is profit engineering. If you have not industrial engineered your systems, you are leaving potential profit on the table. Industrial engineering is a set of techniques to evaluate your systems' functional designs for efficiency. Wherever there is scope, IE will improve the system's efficiency. What is efficiency? Efficiency or productivity is output/input. A functionally designed system is expected to achieve certain output. Actually the system is designed for a specific installed capacity. Industrial engineers work on this functional design and reduce resource input.

 

What is Industrial Engineering? 

"Industrial Engineering is Human Effort Engineering and System Efficiency Engineering. It is an engineering discipline that deals with the design of human effort and system efficiency in all occupations: agricultural, manufacturing and service. The objectives of Industrial Engineering are optimization of productivity of work-systems and occupational comfort, health, safety and income of persons involved."

Industrial engineers make special efforts to confirm that no quality deterioration takes due to increasing output from machine-man combinations. They demonstrate that same quality is produced after increase in productivity and reduction in cost of production and product. 

The definition emphasizes human effort engineering and system efficiency engineering. 

What are techniques of Industrial Engineering?

 

Human Effort Industrial Engineering - Techniques

 

1. Principles of Motion Economy

2. Motion Study

3. Workstation Design

4. Application of Ergonomics and Biomechanics

5. Fatigue Studies

6. Productivity/Safety/Comfort Device Design

7. Standardization of  Methods

8. Operator training

9. Incentive Systems

10. Job Evaluation

11. Learning effect capture

 

 

System (Engineering) Efficiency Improvement Techniques of Industrial Engineering 

 

1. Process Productivity Analysis - Machine Work Study - Human Work Study

2. Operation Analysis 

3. Time study for Process Cost Reduction

4. Value engineering

5. Statistical quality control

6. Statistical inventory control and ABC Classification Based Inventory Systems

7. Six sigma

8. Operations research

9. Variety reduction

10. Standardization

11. Incentive schemes

12. Waste reduction or elimination

13. Activity based management

14. Business process improvement

15. Fatigue analysis and reduction

16. Industrial Engineering Economy Analysis

17. Learning effect capture and continuous improvement (Kaizen, Quality circles and suggestion schemes)

18. Standard costing

19. 5S

20. SMED

21. IoT Implementation

22. Digital Twin Implementation

23. Automation - Autonomation

24. Seven Wastes Model

 

 

References

 

Industrial Engineering - Knols of Narayana Rao K V S S

 

 

I made presentation on the topic in the GloGift 2010 conference organized at the Keio University, Yokohama City, Tokyo. The presentation is given below (new version is to be added).

 



 Industrial Engineering of Systems