Thursday, April 2, 2015

DUA BELAS HUKUM EKONOMI JARINGAN

Sabtu, 06 Maret 2010

Perkenankan saya mengenalkan diri. Saya penulis buku
"Menuju Indonesia Pemain Utama Ekonomi Dunia (2)". Dimulai dari keprihatinan, kenapa keberingasan anak-anak, pemuda, masyarakat bahkan institusi-institusi terhormat saling beradu otot, kenapa petani, nelayan dan usaha mikro dipinggirkan. Buku sudah terbit, mencoba memberikan justifikasi eksakta lagi matematis. Akhirnya terbukti bahwa moral, kebersamaan bangsa harus ditumbuhkan. Juga diyakini bahwa teknologi, bisa diberikan pada mereka terpinggirkan ini.

Tanpa disangka teknologi dunia maya membuat kejutan, teknologi ICT ini akhirnya membuat konsep ekonomi baru, yaitu EKONOMI JARINGAN, atau NETWORK ECONOMY. Dirumuskanlah 12 Hukum Ekonomi Jaringan berikut ini. Untuk lebih detail ikuti di dunia internet ini.

12 Hukum Ekonomi Jaringan
  1. Yang pokok berteman, berkelompok dan berjaringan, wong nyatanya kalau sendirian toh kesepian dan rapuh
  2. Nilai Jaringan membesar mengikuti kwadrat jumlah anggota
  3. Nilai jaringan mengikuti hukum bunga-berbunga (eksponensial), semula merambat, mulai mengembang, kemudian meledak
  4. Di abad teknologi, penularan epidemik hanya disebabkan oleh jumlah yang cukup kecil, Jangan mengambil risiko jadi korban
  5. Bila nilai jaringan meledak dengan jumlah anggota, dengan meledaknya nilai, makin banyak lagi anggota tersedot bergabung. Lihat Facebook, Google, Blackberry
  6. Makin lama, kualitas makin baik dan makin murah. atau yang membaik mutunya, makin murah harganya
  7. Murah hati, memberi gratis pada kemanusiaan. Toh dalam membuat lebih banyak, nilai cadangan dan lebihan kan tak dihitung harganya Bermurah hatilah dan rejekipun mengalir
  8. Bergabunglah dalam jaringan dan kelompok-kelompok, di situ makin lama makin tidak mengenal siapa memimpin siapa dipimpin. Perbedaan bukan disitu, bedanya terletak apakah anda itu berjaringan/berkelompok atau tidak. Kesepian kan
  9. Patah tumbuh hilang berganti, selalu ada yang muncul. Berusahalah maksimal, jangan takut tergulung ombak
  10. Kok Mempertanyakan berjaringan itu batasnya berapa besar. Yang harus dicatat adalah bhw semuanya nanti akan berjaringan Yang sustain justru “ketidak seimbangan” itu sendiri (cokro manggilingan), innovasi dan ide baru selalu ada dan yang lamapun obselete
  11. Jangan risaukan penilaian “tidak efisien”. Dari pada menyempurnakan yang ada (tidak sumbut) lebih baik mencari peluang (ganti) unggul apa yg tersedia
Sumber: sutrisno2010.blogspot.com 





Posted on June 28, 2013by Just_Fal
Dua belas hukum ekonomi jaringan yang dikemukan Kevin Kelly memberikan 4 pengaruh besar dalam program restrukrurisasi secara global di era internet. Kelly berpendapat bahwa kemakmuran berasal dari adanya inovasi bukan berasal dari optimalisasi. Kemakmuran bukan diciptakan dengan pengetahuan/wawasan yang sempurna namun diciptakan karena keterbatasan/hamabtan dalam pengetahuan yang akhirnya mendorong terciptanya inovasi. Kemudian langkah yang paling yang ideal untuk mengatasi keterbatasan pengetahuan adalah dengan menggunakan kemampuan otak dan memperkuat jaringan. Selain itu, untuk mengalahkan keterbatasan tersebut adalah meninggalkan pengetahuan itu sendiri. Siklus terjadinya penemuan, pemeliharaan dan lenyap-nya sebuah pengetahuan dapat terjadi secara cepat dan intensif. Berdasarkan pendapat tersebut, Kevin Kelly mengemukakan 12 Hukum Ekonomi Jaringan (12 Principles of the Network (new) Economy) untuk memperkuat jaringan ekonomi di era internet sebagai berikut:
1.       The Law of Connection.
Agar ekonomi menjadi besar diperlukan adanya kelompok dan jaringan karena jika dilakukan secara individual akan mudah rapuh. Dengan membuat jaringan dan kelompok, kekurangan yang dimiliki oleh anggota dapat ditutupi oleh kelebihan yang dimiliki oleh anggota lainnya.
2.      The Law of Plentitude.
Nilai Jaringan membesar mengikuti kuadrat jumlah anggota. Semakin banyak anggota jaringan maka nilai jaringan tersebut akan semakin besar sehingga memerlukan kontrol yang lebih ketat.
3.      The Law of Exponential Value.
Nilai jaringan mengikuti hukum bunga-berbunga (eksponensial). Semula bergerak secara perlahan, mulai berkembang dan kemudian meledak. Jaringan yang semakin besar akan terus berkembang seperti perhitungan bunga majemuk, karena jumlah anggota yang semakin banyak akan mengembangkan jaringan-jaringan baru.

4.      The Law op Tipping Point.
Penularan epidemik hanya disebabkan oleh jumlah yang cukup kecil, sehingga risiko menjadi korban akan semakin besar. Dengan begabung ke dalam kelompok dan jaringan, risiko untuk menjadi korban dari penularan epidemik dapat dicegah karena sebelum terjadi penularan dimungkinkan memperoleh perlindungan dari sesama anggota jaringan.
5.      The Law of Increasing Return.
Apabila nilai jaringan meledak karena jumlah anggota yang besar makan dengan mudah akan menarik anggota baru untuk bergabung dalam jaringan. Seperi Facebook, Google, dan Blackberry, semakin besar nilai jaringan akan meningkatkan pengaruh dan menjaditrend di masyarakat, dan jika telah menjadi trend maka maka akan semakin mudah orang lain untuk bergabung dan menjadi anggota serta mengembangkan jaringan semakin besar.
6.      The Law of Inverse Pricing.
Semakin lama, kualitas produk akan semakin baik dari segi mutu dan semakin murah. Dengan berjalannya waktu, akan muncul learning time dengan sendirinya sehingga kekurangan-kekurangan yang terjadi dapat diperbaiki dengan mudah dan semakin banyak muncul produk inovatif.
7.      The Law of Generosity.
Semakin besar jaringan maka persediaan yang dimiliki juga semakin besar, dan tidak menjadi sesuatu yang material jika melakukan pemberian secara gratis kepada individu lain.
8.     The Law of the Allegiance.
Jaringan yang semakin berkembang akan mempunyai tipe anggota yang sangat beragam, sehingga sesama anggota akan saling berbagi dan saling menutupi kekurangan dengan tujuan untuk mengembangkan jaringan menjadi besar dan di dalam jaringan tidak ada batasan antara pemimpin dan anggotanya.
9.      The Law of Devolution.
Dalam setiap siklus terbentuknya jaringan akan mengalami pasang surut, sehingga tidak perlu ada kekhawatiran jika suatu jaringan mengalami kemunduran dan digantikan oleh jaringan baru yang dapat berkembang sesuai dengan keinginan masyarakat.
10.  The Law of Displacement.
Jaringan membesar tanpa batas dan akhirnya terjadi ketidak-seimbangan yang akan memunculkan jaringan-jaringan baru dan akan berulang dalam setiap siklusnya.
11.   The Law of Churn.
Perubahan dan ketidakseimbangan akan bergerak terus secara dinamis sehingga inovasi dan ide baru selalu ada untuk menggantikan produk-produk lama.
12.  The Law of Inefficiencies.
Jika terjadi ketidakefisienan, lebih baik mencari peluang yang lain karena jika kekurangan yang dimiliki oleh jaringan sulit untuk ditutupi dan ditanggulangi sebaiknya berusaha untuk mencari peluang dan kesempatan baru yang dapat menjadi kelebihan dengan pertimbangan biaya yang lebih murah.
Referensi:
sutrisno2010.blogspot.com diakses tanggal 16 Februari 2013


Sumber: http://sukasayurasem.wordpress.com/2013/06/28/dua-belas-hukum-ekonomi-jaringan/

Assembly Line

Assembly Line         
Assembly line merupakan salah satu cara optimalisasi proses pada operasi sebuah industry. Assembly line dapat menghemat banyak sumber daya dan waktu. Bayangkan butuh berapa banyak SDM dan waktu yang dibutuhkan dalam proses bagaimana manufacturing dalam banyak bidang bisa dilakukan dalam skala massal.
Pada awalnya assembly line diterapkan oleh ford pada proses produksi mobilnya yang awalnya pembuatan sebuah mobil memakan waktu 35 setelah menerapkan konsep assembly line setiap mobil hanya membutuhkan waktu produksi selama 20 menit bayangkan penghematan waktu dan sumber daya yang dilakukan. Awalnya mulanya assembly line ini diterapkan oleh salah satu manajernya, ia mendapat inspirasi pada saat melihat proses pemotongan hewan.
Bayangkan berapa waktu yang dibutuhkan dalam pembutan mobil modern yang memiliki puluhan ribu part tidak seperti mobil ford kuno yang partnya tidak begitu banyak dalam proses produksinya. Assembly line dapat menekan biaya produksi yang dibutuhkan seingga harga jual semakin rendah.
Assembly Line Balancing
Assembly Line Balancing (ALB, Keseimbangan Lini Perakitan) adalah permasalahan penyeimbangan beban pada stasiun-stasiun kerja di bagian lini perakitan. Keseimbangan pada lini perakitan adalah sangat penting karena menentukan seberapa besar kecepatan dan kedayagunaan (efisiensi) produksi.
Secara deterministik, kecepatan produksi lini perakitan ditentukan oleh stasiun kerja yang memiliki kecepatan operasi yang paling lambat (waktu operasi yang terbesar). hal ini dikarenakan stasiun kerja yang lain harus mengalami waktu menganggur (idle) baik menunggu material input maupun menunggu daerah WIP (work in process) di depannya menjadi kosong. Selain itu, jika kecepatan produksi stasiun-stasiun kerja pada lini perakitan berbeda secara signifikan, efisiensi lini perakitan tersebut menjadi rendah. Hal ini diakibatkan waktu operasi tidak digunakan sepenuhnya dalam mentransformasikan barang, akan tetapi ada waktu operasi yang terbuang dikarenakan idle (menganggur).
Pada permasalahan ini, diasumsikan ada serangkaian proses dalam lini perakitan. Setiap proses memiliki waktu operasi yang berbeda-beda. Selain itu, ada batasan keterdahuluan (precedence constraint) yakni sejumlah proses baru dapat dilakukan setelah proses prasyarat -nya (predecessor) selesai. Tujuan dari permasalahan ini adalah menentukan pengelompokan proses-proses pada lini perakitan menjadi stasiun-stasiun kerja yang akan memaksimumkan efisiensi lini perakitan tersebut. Terkadang, pada permasalahan ini juga dapat ditambahkan kendala seperti jumlah maksimum stasiun kerja atau kecepatan minimum lini perakitan (waktu operasi maksimum lini perakitan).

Henry Ford Changes the World, 1908

At the beginning of the 20th century the automobile was a plaything for the rich. Most models were complicated machines that required a chauffer conversant with its individual mechanical nuances to drive it. Henry Ford was determined to build a simple, reliable and affordable car; a car the average American worker could afford. Out of this determination came the Model T and the assembly line - two innovations that revolutionized American society and molded the world we live in today.
Henry Ford did not invent the car; he produced an automobile that was within the economic reach of the average American. While other manufacturers were content to target a market of the well-to-do, Ford developed a design and a method of manufacture that
Description: http://www.eyewitnesstohistory.com/images/ford1.jpg
Henry Ford and his first car
the Quadricycle, which he
built in 1896
steadily reduced the cost of the Model T. Instead of pocketing the profits; Ford lowered the price of his car. As a result, Ford Motors sold more cars and steadily increased its earnings - transforming the automobile from a luxury toy to a mainstay of American society.
The Model T made its debut in 1908 with a purchase price of $825.00. Over ten thousand were sold in its first year, establishing a new record. Four years later the price dropped to $575.00 and sales soared. By 1914, Ford could claim a 48% share of the automobile market.
Central to Ford's ability to produce an affordable car was the development of the assembly line that increased the efficiency of manufacture and decreased its cost. Ford did not conceive the concept, he perfected it. Prior to the introduction of the assembly line, cars were individually crafted by teams of skilled workmen - a slow and expensive procedure. The assembly line reversed the process of automobile manufacture. Instead of workers going to the car, the car came to the worker who performed the same task of assembly over and over again. With the introduction and perfection of the process, Ford was able to reduce the assembly time of a Model T from twelve and a half hours to less than six hours.
Developing the Model T
The Ford Motor Company manufactured its first car - the Model A - in 1903. By 1906, the Model N was in production but Ford had not yet achieved his goal of producing a simple, affordable car. He would accomplish this with the Model T. Charles Sorensen - who had joined Henry Ford two years earlier - describes how Ford had him set up a secret room where design of the new car would be carried out:
"Early one morning in the winter of 1906-7, Henry Ford dropped in at the pattern department of the Piquette Avenue plant to see me. 'Come with me, Charlie,' he said, 'I want to show you something.'
I followed him to the third floor and its north end, which was not fully occupied for assembly work. He looked about and said, 'Charlie, I'd like to have a room finished off right here in this space. Put up a wall with a door in big enough to run a car in and out. Get a good lock for the door, and when you're ready, we'll have Joe Galamb come up in here. We're going to start a completely new job.'
The room he had in mind became the maternity ward for Model T.
It took only a few days to block off the little room on the third floor back of the Piquette Avenue plant and to set up a few simple power tools and Joe Galamb's two blackboards. The blackboards were a good idea. They gave a king-sized drawing which, when all initial refinements had been made, could be photographed for two purposes: as a protection against patent suits attempting to prove prior claim to originality and as a substitute for blueprints. A little more than a year later Model T, the product of that cluttered little room, was announced to the world. But another half year passed before the first Model T was ready for what had already become a clamorous market...
The summer before, Mr. Ford told me to block off the experimental room for Joe Galamb, a momentous event occurred which would affect the entire automotive industry. The first heat of vanadium steel in the country was poured at the United Steel Company's plant in Canton, Ohio.
Early that year we had several visits from J. Kent Smith, a noted English metallurgist from a country which had been in the forefront of steel development...
Description: http://www.eyewitnesstohistory.com/images/ford2.jpg
The 1908 Model T. Two forward
gears, a 20 horsepower engine
and no driver doors.
They sold like hot cakes
Ford, Wills, and I listened to him and examined his data. We had already read about this English vanadium steel. It had a tensile strength nearly three times that of steels we were using, but we'd never seen it. Smith demonstrated its toughness and showed that despite its strength it could be machined more easily than plain steel. Immediately Mr. Ford sensed the great possibilities of this shock-resisting steel. 'Charlie,' he said to me after Smith left, 'this means entirely new design requirements, and we can get a better, lighter, and cheaper car as a result of it.'
It was the great common sense that Mr. Ford could apply to new ideas and his ability to simplify seemingly complicated problems that made him the pioneer he was. This demonstration of vanadium steel was the deciding point for him to begin the experimental work that resulted in Model T...
Actually it took four years and more to develop Model T. Previous models were the guinea pigs, one might say, for experimentation and development of a car which would realize Henry Ford's dream of a car which anyone could afford to buy, which anyone could drive anywhere, and which almost anyone could keep in repair. Many of the world's greatest mechanical discoveries were accidents in the course of other experimentation. Not so Model T, which ushered in the motor transport age and set off a chain reaction of machine production now known as automation. All our experimentation at Ford in the early days was toward a fixed and, then wildly fantastic goal.
By March, 1908, we were ready to announce Model T, but not to produce it, On October 1 of that year the first car was introduced to the public. From Joe Galamb's little room on the third floor had come a revolutionary vehicle. In the next eighteen years, out of Piquette Avenue, Highland Park, River Rouge, and from assembly plants all over the United States came 15,000,000 more."
Birth of the Assembly Line
A few months later- in July 1908 - Sorensen and a plant foreman spent their days off developing the basics of the Assembly Line:
"What was worked out at Ford was the practice of moving the work from one worker to another until it became a complete unit, then arranging the flow of these units at the right time and the right place to a moving final assembly line from which came a finished product. Regardless of earlier uses of some of these principles, the direct line of succession of mass production and its intensification into automation stems directly from what we worked out at Ford Motor Company between 1908 and 1913...
As may be imagined, the job of putting the car together was a simpler one than handling the materials that had to be brought to
Description: http://www.eyewitnesstohistory.com/images/ford4.jpg
The old fashioned way - limousines are
assembled at individual stations
by a Pittsburg manufacturer, 1912
it. Charlie Lewis, the youngest and most aggressive of our assembly foremen, and I tackled this problem. We gradually worked it out by bringing up only what we termed the fast-moving materials. The main bulky parts, like engines and axles, needed a lot of room. To give them that space, we left the smaller, more compact, light-handling material in a storage building on the northwest comer of the grounds. Then we arranged with the stock department to bring up at regular hours such divisions of material as we had marked out and packaged.
This simplification of handling cleaned things up materially. But at best, I did not like it. It was then that the idea occurred to me that assembly would be easier, simpler, and faster if we moved the chassis along, beginning at one end of the plant with a frame and adding the axles and the wheels; then moving it past the stockroom, instead of moving the stockroom to the chassis. I had Lewis arrange the materials on the floor so that what was needed at the start of assembly would be at that end of the building and the other parts would be along the line as we moved the chassis along. We spent every Sunday during July planning this. Then one Sunday morning, after the stock was laid out in this fashion, Lewis and I and a couple of helpers put together the first car, I'm sure, that was ever built on a moving line.
We did this simply by putting the frame on skids, hitching a towrope to the front end and pulling the frame along until axles and wheels were put on. Then we rolled the chassis along in notches to prove what could be done. While demonstrating this moving line, we worked on some of the subassemblies, such as completing a radiator with all its hose fittings so that we could place it very quickly on the chassis. We also did this with the dash and mounted the steering gear and the spark coil."
Implementation
The basics of the Assembly Line had been established but it would take another five years for the concept to be implemented. Implementation would await construction of the new Highland Park plant which was purpose-built to incorporate the assembly line. The process began at the top floor of the four-story building where the engine was assembled and progressed level by level to the ground floor where the body was attached to the chassis.
Description: http://www.eyewitnesstohistory.com/images/ford3.jpg
End of the Line. The Model T's body is joined
to its chassis at the Highland Park plant
"By August, 1913, all links in the chain of moving assembly lines were complete except the last and most spectacular one - the one we had first experimented with one Sunday morning just five years before. Again a towrope was hitched to a chassis, this time pulled by a capstan. Each part was attached to the moving chassis in order, from axles at the beginning to bodies at the end of the line. Some parts took longer to attach than others; so, to keep an even pull on the towrope, there must be differently spaced intervals between delivery of the parts along the line. This called for patient timing and rearrangement until the flow of parts and the speed and intervals along the assembly line meshed into a perfectly synchronized operation throughout all stages of production. Before the end of the year a power-driven assembly line was in operation, and New Year's saw three more installed. Ford mass production and a new era in industrial history had begun"
References:
   Charles Sorensen's account can be found in: Sorensen, Charles, E., My Forty Years with Ford (1956); Banum, Russ, The Ford Century (2002); Brinkley, Douglas, Wheels for the world: Henry Ford, his company, and a century of progress, 1903-2003 (2003).
How To Cite This Article:
"Henry Ford Changes the World, 1908," EyeWitness to History www.eyewitnesstohistory.com (2005).



















What Is Assembly Line Balancing?
Description: Balancing an assembly line can speed production or save money.
Balancing an assembly line can speed production or save money.
Description: Some companies hire outside consultants for assembly line balancing.
Some companies hire outside consultants for assembly line balancing.

Article Details
  • Written By: Jordan Weagly
  • Edited By: Angela B.
  • Last Modified Date: 18 August 2014
  • Copyright Protected:
    2003-2014 Conjecture Corporation
  •  
Top of Form
Bottom of Form
Assembly line balancing can be loosely defined as the process of optimizing an assembly line with regard to certain factors. Configuring an assembly line is a complicated process, and optimizing that system is an important part of many manufacturing business models. Maintaining and operating one is often quite costly, as well. The main focus of balancing is usually to optimize existing or planned assembly lines to minimize costs and maximize gains.
For instance, a car company might want to alter its assembly line layout in order to speed production. The company might consider the number of work stations a manufactured item must pass before it is complete and the time required at each point. Of course, each stage of this process requires a certain length of time, and the allotted time to finish a process, the number of workers, or the resource demand may also be considered, based on the specific manufacturing requirements.
The possible results of an assembly line balancing process might be maximized efficiency, minimized time to finish a process, or minimized number of work stations necessary within a certain time frame. Each manufacturing process might be quite different from another, so a company balancing unique workloads must work within the constraints and restrictions affecting its specific assembly line.

To optimize very specific operations, balancing an assembly line might require different methods, some of which include equations and algorithms concerning specific aspects of the manufacturing process. Complex manufacturing processes, such as making automobiles in large quantities, can be broken down into smaller parts, such as individual task times or the resource demands for each machine. This might be especially helpful in manufacturing processes that require the consideration of many variables, such as customized vehicles. Assembly line balancing can also guide decision-making based on the multitude of variables that can affect the manufacturing process.
Many times, this process might be used as support in decision making by offering many different models and types of data. For instance, the manager of a car manufacturer might analyze his or her operation based on the concepts of assembly line balancing using many different variables, and then make a decision based on that analysis. While this might provide the best response to an optimization effort based on one set of variables, the final decision may rest on multiple mathematical perspectives of the same problem.








assembly line
Article Free Pass
assembly line, industrial arrangement of machines, equipment, and workers for continuous flow of workpieces in mass-production operations.
The design for an assembly line is determined by analyzing the steps necessary to manufacture each product component as well as the final product. All movement of material is simplified, with no cross flow, backtracking, or repetitious procedure. Work assignments, numbers of machines, and production rates are programmed so that all operations along the line are compatible.
An automotive assembly line starts with a bare chassis. Components are attached successively as the growing assemblage moves along a conveyor. Parts are matched into subassemblies on feeder lines that intersect the main line to deliver exterior and interior parts, engines, and other assemblies. As the units move by, each worker along the line performs a specific task, and every part and tool is delivered to its point of use in synchronization with the line. A number of different assemblies are on the line simultaneously, but an intricate system of scheduling and control ensures that the appropriate body type and colour, trim, engine, and optional equipment arrive together to make the desired combinations.
Automated assembly lines consist entirely of machines run by machines, with little or no human supervision. In such continuous-process industries as petroleum refining and chemical manufacture and in many modern automobile-engine plants, assembly lines are completely mechanized and consist almost entirely of automatic, self-regulating equipment.
Many products, however, are still assembled by hand because many component parts are not easily handled by machines. Expensive and somewhat inflexible, automatic assembly machines are economical only if they produce a high level of output. However, the development of versatile machinery and the increased use of industrial robots have improved the efficiency of fully automated assembly operations.

Sumber : http://www.britannica.com/EBchecked/topic/39246/assembly-line

Robust design

Robust design
Robust design adalah aktivitas pengembangan produk untuk menyempurnakan kinerja produk sambil meminimumkan pengaruh gangguan atau noise. Dalam robustdesign, kita memanfaatkan eksperimen dan analisis data untuk mengidentifikasi robust setpoint untuk perancangan yang dapat dikendalikan.Suatu robust setpoint dapat merupakan kombinasi dari nilai-nilai parameterperancangan untuk mencapai kinerja produk yang diharapkan dalam batasan kondisioperasi dan variasi manufaktur.
Secara konseptual, robust design adalah mudah untuk dimengerti . Akan terdapat banyak kombinasi nilai-nilai parameter yang akan menghasilkankinerja yang diinginkan. Akan tetapi beberapa kombinasi ini lebih sensitif terhadap variasi yang tidak terkendali dibandingkan yang lain. Karena produk pada kenyataannya akan selalu berhadapan dengan berbagai faktor gangguan, maka sebaiknya kita memilih nilai-nilai parameter yang kurang sensitif terhadap variasi yang tidak terkendali. Proses perancangan robust dalam prakteknya menggunakan pendekatan eksperimen untuk memperoleh robust setpoint.

Variasi manufaktur akan timbul pada setiap penyetelan(setpoint) yang dipilih, sehingga nilai aktual tidak sesuai dengan yang dispesifikasikan.Robust banyak digunakan dalam fase perancangan rinci sebagai cara untuk menjamin kinerja produk yang diharapkan dalam kondisi yang bervariasi. Dalamperancangan rinci, aktivitas perancangan robust juga dikenal sebagai perancanganparameter, karena di dalam implikasinya, kita menetapkan setpoint yang tepat untuk parameter perancangan di bawah kendali kita. Parameter ini dapat meliputi ; materialproduk, dimensi, toleransi, proses manufaktur, dan instruksi operasi

REVIEW CAD dan CAM

REVIEW CAD dan CAM

Pada suatu pabrik otomotif presisi dan waktu proses yang cepat sangat diperlukan, untuk dapat memenuhi kebutuhan tersebut diperlukan CAD/CAM. CAM disini dapat berupa software seperti Auto-CAD untuk mendesain part lalu digunakan CAM untuk memproses blok-blok logam menjadi suatu part menggunakan  CNC yang memiliki ketelitian yang tinggi.
CAD (Computer Aided Design) adalah program komputer yang memungkinkan seorang perancang (designer) untuk mendisain gambar rekayasa (design  engineering) dengan mentransformasikan gambar geometris secara cepat. Sedangkan  CAM (Computer Aided Manufacturing) adalah sistem manufaktur yang mengoptimalkan kemampuan program komputer untuk menterjemahkan disain  rekayasa yang dibuat oleh CAD sehingga dapat mengontrol mesin NC (Numerical  Controlled Machines). Sistem CAD/CAM sendiri terjadi apabila spesifikasi disain secara langsung ditransfer/diterjemahkan kedalam spesifikasi manufaktur, jadi CAD/CAM merupakan penggabungan disain rekayasa dan instruksi manufaktur. Sedangkan mesin NC sendiri adalah mesin yang peralatannya dikontrol oleh komputer dengan sistem CAD/CAM.

Untuk orang awam CAD/CAM dianggap alat gambar elektronik saja yang dapat mempercepat proses menggambar, tetapi kenyataannya kemampuan CAD/CAM jauh melebihi anggapan tersebut dimana CAD/CAM mempunyai fungsi utama dalam disain, analisa, optimasi dan manufaktur. CAD/CAM biasa melakukan analisa elemen hingga (finite element analysis), analisa transfer panas (heat transfer analysis), analisa tekanan (stress analysis), simulasi dinamis dari mekanik (dynamic simulation of mechanisms), analisa cairan dinamis (fluid dynamic analysis) dan lain-lain.
Kemampuan CAD/CAM yang terdiri dari 4 teknologi dasar yaitu :
·         Manajemen Basis Data (Database)
·         Komputer Grafik
·         Model Matematis (Analisis)
·         Akuisisi Data dan Kontrol (prototipe fisik, proses produksi)


Seringkali aplikasi CAD/CAM dapat memanfaatkan keempat teknologi dasar dari CAD/CAM diatas seperti menyimpan dan memanggil basis data gambar dan atribut suku cadang, menggunakan komputer grafik untuk berkreasi dan display, memanfaatkan simulasi dan model matematis (elemen hingga) dan dapat juga dimanfaatkan untuk mengontrol proses produksi dengan kontrol numerik dan pemrograman robot. Contoh lain adalah MRP (Material Requirements Planning) yang hanya memanfaatkan teknologi dasar dari CAD/CAM yaitu Manajemen Basis Data.Selanjutnya tanda “/” didalam CAD/CAM menunjukkan 2 kemampuan yang diintegrasikan. Database alfanumerik yang diciptakan dalam disain dapat menjadi aplikasi Permintaan Bahan Baku (Bill of Material) dalam industri manufaktur. Gambar geometris diterjemahkan menjadi spesifikasi manufaktur sehingga dapat mengontrol mesin CNC (Computer Numerical Control). Selain itu kemampuan CAD dalam mendisain Wireframe Modelling berkembang menjadi Surface Modelling, Solid Modelling dan terakhir Parametric Modelling. Sedangkan kemampuan CAM dari mesin NC (Numerical Control) menjadi CNC (Computer Numerical Control) dan terakhir DNC (Direct Numerical Control).

CAM (Computer Aided Manufacturing)

CNC Programming and Computer-Aided Manufacturing/Design
APRIL 8, 2014 BY MICHAEL CHURCHMAN
Description: cnc programmingCNC programming, computer-aided manufacturing, and large-scale control systems such as SCADA — the hardware side of industrial programming is at least as important to industry as its more glamorous sibling, computer-aided design. CNC programming is what makes machine tools actually perform the complex tasks that are required of them; without it, much of today’s technology would not be possible. Software and Web design trends may come and go, but CNC and CAM skills are always in demand.
CNC: What Is It?
CNC stands for Computer Numeric Control. CNC, CAD (Computer-Aided Design), and CAM (Computer-Aided Manufacturing), together form the basis of modern-day software-controlled industrial manufacturing systems. CNC machines are software-controlled machine tools, such as lathes, mills, and cutters. They are used to perform the same tasks as traditional machine tools and mechanically-automated tools; CNC machines, however, are controlled entirely by software. CNC machines include extremely precise multi-axis milling tools and high-powered, high-precision laser and electron-beam devices which could not be operated accurately using strictly mechanical controls.
What About 3D Printing?
“Lathes and mills? I thought that 3D printers were going to replace them!”
3D printing is a rapidly-growing field, and 3D printers are already among the most important CNC tools. But they do have some built-in limitations. 3D printers are excellent with plastics and other materials which can harden by thermal or chemical processes after being formed. 3D printing with metals generally requires the metal to be sintered or melted at some point in the process, resulting in mechanical properties which may be very different from those of a piece machined from a rolled or heat-tempered alloy. And at this point, the 3D printing process simply can not match the precise tolerances of high-precision machining. For the time being, at least, the fully-automated factory floor is likely to have 3D printers working side-by-side with more traditional CNC machines, rather than replacing them entirely.
Trace It Back
Most descriptions of computer-controlled manufacturing systems focus on CAD and CAM — design and high-level programming — and treat factory-floor machine-tool control almost as an afterthought. But since we’ve been talking about CNC, let’s start with the CNC machine tools themselves, then trace the process backward to computer-aided manufacturing and design systems. After all, without the CNC machines on the factory floor, there wouldn’t be any computer-aided manufacturing. And as we’ll see, there are likely to continue to be significant opportunities for skilled machinists with a good working knowledge of low-level CNC programming, as well as high-end CAD/CAM software.
How They Work
Mechanically, many CNC machines work like traditional machine tools, with the workpiece, the cutting tool, or both rotating rapidly, and with the overall motion of the workpiece or the cutting tool precisely controlled by mechanical means. In a CNC machine, however, these mechanical actions are controlled by stepper motors or other servo-type mechanisms, which are themselves controlled by software. Besides mechanical cutting, milling, grinding, or drilling action, CNC machines can use flame, plasma, laser, electric discharge, or water-jet cutting, punches, knives, or even such specialized tools as embroidery needles.
For all of these systems, however, the actions of the tool and the workpiece are controlled by means of commands written in a CNC programming language.
CNC Programming Languages
While there is no single programming language for all CNC tools (many of which have strictly proprietary languages), G-code (or the G programming language) is the most widely used CNC programming languages, available in a variety of largely proprietary implementations. Of these, the FANUC implementation became at least a partial standard in the CNC industry in the 1990s. Initially, G-code resembled a low-level programming language, such as assembly language; later versions, however, include control structures and other features more typical of a high-level language. Current CAD/CAM softwaremakes it possible to create machine instructions at the design level, then automatically convert them into G-code for the individual tools.
G and M
G-code largely consists of two types of command: G codes and M codes. G codes consist of the letter G (designating the memory address where the command will be stored) followed by a control number (from 0 through 99). G codes are traditionally called preparatory codes, because they tell the machine how it should move. G01 is a typical G code; it tells the machine to move the cutting tool (or workpiece) in a line at a specific feed rate or distance. It will be followed by codes indicating the axis of motion and increment.
M codes are called often miscellaneous codes; they control more general machine operations (motor on/motor off, coolant on/coolant off, spindle motion, etc.), and like G codes, consist of the M prefix followed by a one to three digit numeric code. Other codes (represented by letters of the alphabet followed by integer or decimal numbers) control such things as the axis, speed, or geometry of the cut. While other, strictly proprietary CNC languages may have different commands, they generally operate on similar principles.
Higher-Level Control
As you can imagine, writing G-code directly can be a time-consuming task, and the chances of introducing serious errors into the code are fairly high. Manual G-code programming is a bit like the days of MS-DOS, when programmers had to write their own printer drivers, sending low-level escape codes directly to the printer. And just as contemporary operating systems supply their own printer drivers, relieving the programmer of the need to send commands directly to the printer, contemporary CAD/CAM systems allow manufacturing designers and programmers to create control programs in a higher-level language (or wizard-style development environment) which the CAM software then converts to G-code. (Note, however, that in many situations, programmers still need to write their own low-level G code, since CNC programming is not yet as fully standardized as desktop or mobile OS programming.)
CAD
Now let’s look at the higher end. Computer-aided design (CAD) software is used to design items to be manufactured, ranging from a fairly simple stand-alone object to a complex, high-precision system made of a large number of individual parts. Design in CAD is primarily engineering design, rather than simple graphic design, and CAD output typically includes precise dimensions, tolerances, and even material requirements; CAD is frequently integrated with computer-aided engineering (CAE). The best CAD software is extremely sophisticated (and often very expensive), and skilled CAD designers are in high demand. There are very definitely good opportunities for anyone with a good knowledge of CAD software and the ability to produce technically complex designs that meet the precise engineering requirements of today’s technology.
CAM
CAD systems may be integrated with an entire suite of software, including project management and scheduling systems, product lifecycle management software, and computer-aided manufacturing (CAM) systems. When integrated with a CAD system, CAM software can take CAD output (essentially the design and specifications for a manufactured piece) and convert it directly or indirectly into CNC programming code.
In an ideal world, this design-to-manufacturing cycle would be seamless and easy: the designer would create the design in a CAD module and send it to a fully integrated CAM module, which would then automatically convert it perfect CNC code and send it to the appropriate factory-floor machines. In the actual world of here-and-now, of course, it isn’t that easy.
Human Skills Are in Demand
In practice, the G codes generated by CAM software are still, like most machine-generated code, often not as efficient or as well-tailored to the specific situation as the hands-on product of a first-rate programmer. Generated code may be much less prone to errors, but its design is based on generalized assumptions, rather than the specific requirements of the situation. In the case of CAM-generated codes, this may mean that the output must be checked and edited by hand before it can be run, in order to take into account the particular requirements of the machinery, or of the production run.
Seeing With a Machinist’s Eyes
A CAM program can’t see the factory floor through the eyes of an experienced machinist. Actual manufacturing conditions may require some tasks to be done by hand, even if they could theoretically be done as part of the CNC manufacturing process. And it isn’t unusual at all for workplaces to include improvised processes and steps, often in order to compensate for problems that were not anticipated in the original design phase. it’s not really surprising, since manufacturing processes go on in the physical world, where things are rarely as simple as they are in the idealized world of computer design.
Some Adjustment Required
What does this mean to anyone interested in pursuing a career in machine control or operation? Basically, it means that there will probably continue to be a need for skilled, knowledgeable machinists who understands both low-level CNC programming and practical factory-floor problems. Designers may be able to produce complete, sophisticated designs in high-end CAD software, then convert them into machine control codes with the click of a mouse, but they will still need skilled machinists at the factory-floor level to make that code work (and make it work efficiently) under real-world conditions.

















CAM: Computer Aided Manufacturing
Definition: Computer-Aided Manufacturing (CAM) is the use of computer software and hardware in the translation of computer-aided design models into manufacturing instructions for numerical controlled machine tools.
Applications of Computer-Aided Manufacturing
The field of computer-aided design has steadily advanced over the past four decades to the stage at which conceptual designs for new products can be made entirely within the framework of CAD software. From the development of the basic design to the Bill of Materials necessary to manufacture the product there is no requirement at any stage of the process to build physical prototypes.
Computer-Aided Manufacturing takes this one step further by bridging the gap between the conceptual design and the manufacturing of the finished product. Whereas in the past it would be necessary for a design developed using CAD software to be manually converted into a drafted paper drawing detailing instructions for its manufacture, Computer-Aided Manufacturing software allows data from CAD software to be converted directly into a set of manufacturing instructions.
CDescription: CAMAM software converts 3D models generated in CAD into a set of basic operating instructions written in G-Code. G-code is a programming language that can be understood by numerical controlled machine tools – essentially industrial robots – and the G-code can instruct the machine tool to manufacture a large number of items with perfect precision and faith to the CAD design.

Modern numerical controlled machine tools can be linked into a ‘cell’, a collection of tools that each performs a specified task in the manufacture of a product. The product is passed along the cell in the manner of a production line, with each machine tool (i.e. welding and milling machines, drills, lathes etc.) performing a single step of the process.
For the sake of convenience, a single computer ‘controller’ can drive all of the tools in a single cell. G-code instructions can be fed to this controller and then left to run the cell with minimal input from human supervisors.
Benefits of Computer-Aided Manufacturing
While undesirable for factory workers, the ideal state of affairs for manufacturers is an entirely automated manufacturing process. In conjunction with computer-aided design, computer-aided manufacturing enables manufacturers to reduce the costs of producing goods by minimising the involvement of human operators.

In addition to lower running costs there are several additional benefits to using CAM software. By removing the need to translate CAD models into manufacturing instructions through paper drafts it enables manufactures to make quick alterations to the product design, feeding updated instructions to the machine tools and seeing instant results.
In addition, many CAM software packages have the ability to manage simple tasks such as the re-ordering of parts, further minimising human involvement. Though all numerical controlled machine tools have the ability to sense errors and automatically shut down, many can actually send a message to their human operators via mobile phones or e-mail, informing them of the problem and awaiting further instructions.
All in all, CAM software represents a continuation of the trend to make manufacturing entirely automated. While CAD removed the need to retain a team of drafters to design new products, CAM removes the need for skilled and unskilled factory workers. All of these developments result in lower operational costs, lower end product prices and increased profits for manufacturers.
Problems with Computer-Aided Manufacturing
Unfortunately, there are several limitations of computer-aided manufacturing. Obviously, setting up the infrastructure to begin with can be extremely expensive. Computer-aided manufacturing requires not only the numerical controlled machine tools themselves but also an extensive suite of CAD/CAM software and hardware to develop the design models and convert them into manufacturing instructions – as well as trained operatives to run them.
Additionally, the field of computer-aided management is fraught with inconsistency. While all numerical controlled machine tools operate using G-code, there is no universally used standard for the code itself. Since there is such a wide variety of machine tools that use the code it tends to be the case that manufacturers create their own bespoke codes to operate their machinery.
While this lack of standardisation may not be a problem in itself, it can become a problem when the time comes to convert 3D CAD designs into G-code. CAD systems tend to store data in their own proprietary format (in the same way that word processor applications do), so it can often be a challenge to transfer data from CAD to CAM software and then into whatever form of G-code the manufacturer employs.
Further information regarding computer-aided manufacturing can be found at the Berkeley CAM Research site, UC Irvine’s CAM resource site and the National Institute of Standards and Technology (NIST) (PDF).




Article Details
·         Written By: Sandi Johnson
·         Edited By: John Allen
·         Last Modified Date: 19 September 2014
·         Copyright Protected:
2003-2014 Conjecture Corporation
·          
Top of Form
Learn something new every day More Info...by email
Top of Form
Bottom of Form
Computer-aided manufacturing has come to be used as a general term to describe a variety of industrial automation technologies. Some common types of computer-aided manufacturing, also known as CAM, include numerical control (NC) machines; industrial robots; flexible manufacturing systems (FMS); and complete facility systems that incorporate CAM with computer-aided design (CAD) software, product life cycle software, and overall facilities management. Modern manufacturing facilities use CAM technologies to machine products, convert two-dimensional plans into three-dimensional schematics, monitor equipment, and even track and order raw material inventory.
In the early years of computer-aided manufacturing, CAM simply implied automation throughcomputer software. Software helped design and tool aircraft and automotive parts or helped operate robotic arms during assembly. Machinists were still needed in most CAM facilities to reset machines and reason through problems associated with tool misalignment and machine maintenance. Modern computer-aided manufacturing, however, is much more advanced that early CAM technology.
Numeric control (NC) machines, one of the oldest and most common types of computer-aided manufacturing, applies specific formulas to processing raw materials. For example, if a circle must be cut from a sheet of metal, an NC machine can determine, using mathematical calculations and numeric input, exactly where and how to cut to get a perfect circle. Additionally, using the same algorithms, the computer can determine the exact placement of cuts to produce the largest number of circles per sheet, as well as exactly how to position the metal for optimal cutting.
Industrial robots are another example of computer-aided manufacturing. Robots perform many of the repetitive tasks once performed by human hands. Computers control the robots, sending and receiving data such as the number of pieces to produce per minute, placement of robotic arms, and timing between task stations. Programmers and other computer experts thus replace human workers, who now run the computer system rather than performing the manufacturing tasks.
Flexible manufacturing systems, CAM/CAD integrated systems, and setups that integrate with various data exchange systems provide unlimited possibilities for computer-aided manufacturing. As technology continues to evolve and broaden, flexible systems can easily produce several similar products with the same equipment, assisted by CAM software. Specific changes needed for various products can be performed within the CAM software, allowing the entire production process to become automated.
Nearly every aspect of the manufacturing process, with the exception of skilled computer programmers and operators, could be controlled by CAM technologies. Rather than simply controlling the manufacturing or fabrication process, computer-aided manufacturing software can monitor supplies, track performance, order replacement parts for machines, and even notify maintenance personnel of needed upkeep or repairs. Customization of various systems and available technologies makes the different types of CAM software virtually unlimited.

Sumber: http://www.wisegeek.com/what-are-the-different-types-of-computer-aided-manufacturing.htm