再工業(yè)化拯救發(fā)達國家？

掃街

18世紀下半葉和20世紀初的兩次工業(yè)革命在使人們變得更加富裕的同時也推動了城市化進程。如今，第三次工業(yè)革命已經悄然開始。這次以數字化生產為代表的革命不僅會極大改進現今的生產方式，改變商業(yè)及其他領域，更會為發(fā)達國家?guī)�來重新崛起的機遇。

當制造業(yè)走向數字化，世界正在加速邁向第三次劇變。擁有了新材料、新工藝、新機器人、新的網絡協同制造服務，生產會更加經濟、高效、靈活、精簡。人類進步的車輪正駛離大批量生產，轉向個性化定制生產，低端生產人員需求下降。而這種轉變可以將曾經流失到發(fā)展中國家的工作機會帶回發(fā)達國家。

過去的一個世紀里，美國一直引領著全球制造業(yè)，但是現在，美國的制造業(yè)就業(yè)人數下降了三分之一。外包和離岸生產的興起、復雜供應鏈的發(fā)展讓制造商將車間選擇了在中國、印度等低工資國家落腳。

受全球金融危機的影響，一些西方的政策制定者正計劃著開展“再工業(yè)化”，以創(chuàng)造就業(yè)機會、避免更多的生產技術流失到國外。因為制造業(yè)對一個國家的經濟來說非常重要，而且制造企業(yè)的回歸可以創(chuàng)造新的就業(yè)機會。

歐洲模具展是世界最重要的的大展之一。在去年11月的歐洲模具展上，出現了一種新機器：3D打印機。制造零件再也不用敲敲打打，3D打印機通過加蓋涂層制造產品，即“添加生產”。記者親眼見證了一個美國3D制造商用3D打印機造出了一個錘子———金屬錘頭和干凈的木頭手柄，與傳統的錘子一模一樣。

未來的制造業(yè)就是這樣，以智能軟件作為工廠的運行者。油乎乎的錘子和臟兮兮的工作服已經不見蹤影。這絕不是天方夜譚，3D打印技術已經用于生產助聽器和軍用飛機的精密零件。同時，供應鏈的構成將因此發(fā)生巨變，找不到零件的日子一去不復返。

眾多非凡的科技成果將日趨融合，包括智能軟件，新材料，更加靈巧的機器人，新工藝流程，尤其是三維打印技術和整個基于網頁的各種服務。過去的工廠以快速大量制造相同產品為理念。看看福特在汽車外殼涂漆上一句經典語句便知道了，“只要是黑色的，深黑淺黑隨你挑�！钡�是，隨著生產少量多批次產品(即接受消費者定制)的成本日益下降，未來的工廠將會把精力放在處理大規(guī)模的消費者定制品的訂單上面。屆時的工廠可能就不是福特的流水線模式，而更像是一個個織布房舍了。

制造業(yè)的數字化會使工廠的技術培訓更加簡單。學員不用再圍著機器打轉，計算機可以在虛擬環(huán)境里模擬生產系統和產品。在英國，華威大學用一個高分辨率的巨型屏幕作為虛擬現實的3D實驗室，模擬產品開發(fā)。

如今一輛汽車在投產之前很可能早就做成了3D“數字樣車”———可以在一個模擬器里試駕，分拆到虛擬工廠里研究如何生產。而且此類軟件可以用于公司的其他部門，甚至是負責銷售的廣告部門。硅谷歐特克軟件公司的經理GrantRochelle表示，從數字樣車上采集圖片非常精良，在新車出廠前就可以用于推銷冊或電視廣告里。

當年，紡紗機淘汰掉手工織布機，福特的流水線工人搶了馬蹄鐵匠的飯碗，如今，歷史稍改面目后重新上演，數字化革命正在撼動傳媒和零售業(yè)。當看到未來的工廠，很多人會心中打顫。歐洲募集展上，來自世界各地、干凈錚亮的高度自動化機床接踵而至。如今，展會上清一色是由穿著全套工作服的新一代技師操作的無油性機械。技師無論男女，只用坐在電腦前操作。智能軟件和虛擬現實將會逐漸替代人力操作。

十幾年之后，很多汽車生產商的生產率是現在的兩倍。大多數工作崗位也從工廠車間轉移到附近的辦公室，里面坐滿了設計師、工程師、IT專家、后勤專家、銷售員工和其他專業(yè)人士。未來的制造業(yè)崗位將會要求員工掌握更多的技術，很多枯燥的，重復性的工作將一去不復返，不需要鉚釘產品，不需要鉚釘工。

此次工業(yè)革命不僅會影響到器件的制造流程，而且會影響到制造地點的選取。以往工廠習慣于將廠址選在勞動力廉價的國家，以此控制勞動力成本。但是勞動力成本因素正在變得越來越不重要。一部499美元的iPad僅僅包括33美元的制造成本，并且最后在中國的組裝成本僅僅只有8美元。

越來越多的海外工廠正逐漸搬回到富裕國家，這不是因為中國勞動力成本正在上升，而是因為時下許多公司為了將工廠建在離消費者更近的地方，以使其對需求的變化變得更加敏感。并且現在很多產品變得太過復雜，最好還是讓設計師和制造工人在同一個地方工作。

誕生于第二次工業(yè)革命的批量生產可以顯著降低生產成本，但是在未來，規(guī)模生產對3D打印機這類新技術來說影響不大。3D打印機的軟件可以設計出任何東西，而且可以無間斷運行。裝配生產機器的成本跟產量無關；就像2D打印機無論打印多少頁不同的文件，每一頁的打印成本是相同的，我們只用關心墨盒是不是空了，打印紙夠不夠。

由于自動銑床實現了自動監(jiān)測和多方向切割，工廠的生產效率正在飛速提高。日產汽車在英國桑德蘭建立的工廠始于1986年，其產量現已達到歐洲第一。1999年，工廠有4594名員工，年產量為271157輛。而去年工廠員工為5462人，產量卻達到480485輛。

雇傭的生產工人數量下降使企業(yè)的生產成本中勞動力成本所占比例也相應下降。這促使制造商將很多工廠搬回了發(fā)達國家�！耙郧澳欠N人滿為患的大工廠時代已經不復存在�！眲谒谷R斯的工程技術總監(jiān)ColinSmith說。

“如果制造業(yè)依然重要，那么我們需要保證足夠的培訓和教育�！眲谒谷R斯制造總監(jiān)Smith先生認為，未來工廠車間里僅存的工作對工人技術的要求會更高。公司的員工都在他的考慮之中，因為很多公司由于經濟不景氣削減了技術培訓的開支。為了找到最好的工人，勞斯萊斯開辟了新的學徒學院，將每年能培訓的員工數量翻倍，達到400人。

工業(yè)集群是最成功的企業(yè)孵化器，其中最著名、最受追捧的范例就是硅谷。促使企業(yè)集群的原因有很多：獲取技術更加方便，對專業(yè)服務的需求，投資者的風險投資更加有目的性等等。通常集群地區(qū)附近會有大學城或實驗室，因此新想法的誕生后可快速將其投產。在新生產技術的促進下，這種轉換變得更加緊密。

“以前只有具備足夠的生產能力我們才能探索相應的創(chuàng)新技術，但現在我們已經擁有了這樣的技術。”麻省理工學院“創(chuàng)新經濟的生產”研究帶頭人SuzanneBerger說道。在硅谷，這樣的事情并不罕見。

波士頓的生物技術集群產區(qū)由一些大大小小的制藥企業(yè)組成，這些企業(yè)大部分是被當地醫(yī)院和大學組織的研究吸引過來的。

舉例來說，在一些波士頓的實驗室，制藥方式已經有了新的飛躍。由麻省理工學院和瑞士諾華制藥公司合資的試用生產線開拓了制藥行業(yè)的連續(xù)性生產———原料從機器一頭塞進去，藥片就從另一邊掉出來。該項目負責人StephenSofen說，實驗成果非常令人滿意———制藥涉及的離散操作從22個減少到13個，操作時間(包括運送原料的時間在內)從300小時銳減到40小時，而且制造出的每一粒藥都受到監(jiān)測，以確保它符合要求，免除了每批材料都需測試的繁冗任務。

連續(xù)性生產正在徹底改變制藥行業(yè)。“你的目標可以是成長為區(qū)域性的‘小植物’，而非能支持全球市場的‘參天大樹’�！盨tephenSofen說。

這樣的小工廠可以更迅速地響應當地需求。這條實驗生產線能直接裝進一個集裝箱里，因此可以被運到任何地方。生產線24小時能生產10米長的藥片，也很有可能被用來生產為特定患者量身定制的藥物。

過去不少經濟學家認為制造業(yè)無甚特別，服務業(yè)具有同樣的生產力和創(chuàng)新力。但是根據最近美國布魯金斯學會的報告顯示，制造業(yè)工人的平均收入高于服務業(yè)從業(yè)者。

而且，與其他公司相比，制造業(yè)公司對創(chuàng)新的渴望更加強烈。制造業(yè)只貢獻了11%美國的GDP，但是美國國內的研發(fā)經費的68%都來源于制造業(yè)。上述報告稱，與服務業(yè)相比，制造業(yè)的工作薪水更高，這正是創(chuàng)新的巨大動力，從而有助于減少貿易赤字，并為日益成長的“綠色經濟”創(chuàng)造機會。

波士頓咨詢集團預計，美國從中國進口的運輸、計算機、金屬制品、機械等產品中10%-30%在2020年時可實現回歸美國本土生產，這將為美國每年帶來20億-55億美元的收入。這為美國大力支持制造業(yè)提供了充分的理由。

盡管中國在追趕美國，但美國完成與中國同樣的產出使用的工人數量只是中國的10%，麻省理工學院校長SusanHockfield如是說。

重振制造業(yè)被發(fā)達國家提上議程，而制造業(yè)和服務業(yè)的界限漸漸模糊———制造業(yè)的工作性質正在改變。

但是，制造業(yè)究竟能提供多少工作，尤其白領類型的工作？由于技術進步，制造車間需要的工人越來越少，車間內常常顯得冷清，而辦公室里反而擠滿了設計師、IT專家、會計師、物流專家、營銷人員、客戶關系經理，甚至還有廚師和清潔工。

“我們必須在美國推廣最新的制造工藝，盡管車間雇傭工人減少，新技術將催生一個巨大的供應鏈，可以提供大量的就業(yè)機會和豐厚的經濟利益�！盨usanHockfield說。

很多公司對“再工業(yè)化”持樂觀態(tài)度。通用電氣公司全球研究中心高新技術部總管MichaelIdelchik說，“我們正站在新一輪制造業(yè)革命的潮頭”，他認為，人們對制造業(yè)的工作有些短視，推進第三次工業(yè)革命的思想可以來自世界各地，制造業(yè)是個非常大的就業(yè)領域。

xiaoyetongxu

沙發(fā)，                                                      

hotvg

機械工業(yè)是個積累很嚴重，技術相對封閉的狀況，中國很難啊。

icedtan

數字化革命我們又落后了一程。

brianshao

創(chuàng)造力被釋放的力量，我們可能會被重拳打倒，能還手的寥寥

神龍斗士

工業(yè)發(fā)展的很快啊，這個越來越先進了啊

荒原獵豹

看中國的歷史和世界史，幾次工業(yè)革命中國都滯后于世界的腳步，這是事實，也許這和中國人的性格和儒家思想的熏陶造成的吧

老畢sz

Special report: Manufacturing and innovation
In this special report
A third industrial revolution
Back to making stuff

The boomerang effect

Forging ahead

Solid print

Layer by layer

All together now

Making the future

Sources & acknowledgements
Reprints
A third industrial revolution
As manufacturing goes digital, it will change out of all recognition, says Paul Markillie. And some of the business of making things will return to rich countries
Apr 21st 2012 | from the print edition
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OUTSIDE THE SPRAWLING Frankfurt Messe, home of innumerable German trade fairs, stands the “Hammering Man”, a 21-metre kinetic statue that steadily raises and lowers its arm to bash a piece of metal with a hammer. Jonathan Borofsky, the artist who built it, says it is a celebration of the worker using his mind and hands to create the world we live in. That is a familiar story. But now the tools are changing in a number of remarkable ways that will transform the future of manufacturing.

One of those big trade fairs held in Frankfurt is EuroMold, which shows machines for making prototypes of products, the tools needed to put those things into production and all manner of other manufacturing kit. Old-school engineers worked with lathes, drills, stamping presses and moulding machines. These still exist, but EuroMold exhibits no oily machinery tended by men in overalls. Hall after hall is full of squeaky-clean American, Asian and European machine tools, all highly automated. Most of their operators, men and women, sit in front of computer screens. Nowhere will you find a hammer.

In this special report
»A third industrial revolution

Back to making stuff
The boomerang effect
Forging ahead
Solid print
Layer by layer
All together now
Making the future
Sources & acknowledgements
Reprints

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

Related topics
Europe
United States
United Kingdom
Apple iPhone
Frankfurt
And at the most recent EuroMold fair, last November, another group of machines was on display: three-dimensional (3D) printers. Instead of bashing, bending and cutting material the way it always has been, 3D printers build things by depositing material, layer by layer. That is why the process is more properly described as additive manufacturing. An American firm, 3D Systems, used one of its 3D printers to print a hammer for your correspondent, complete with a natty wood-effect handle and a metallised head.

This is what manufacturing will be like in the future. Ask a factory today to make you a single hammer to your own design and you will be presented with a bill for thousands of dollars. The makers would have to produce a mould, cast the head, machine it to a suitable finish, turn a wooden handle and then assemble the parts. To do that for one hammer would be prohibitively expensive. If you are producing thousands of hammers, each one of them will be much cheaper, thanks to economies of scale. For a 3D printer, though, economies of scale matter much less. Its software can be endlessly tweaked and it can make just about anything. The cost of setting up the machine is the same whether it makes one thing or as many things as can fit inside the machine; like a two-dimensional office printer that pushes out one letter or many different ones until the ink cartridge and paper need replacing, it will keep going, at about the same cost for each item.

Additive manufacturing is not yet good enough to make a car or an iPhone, but it is already being used to make specialist parts for cars and customised covers for iPhones. Although it is still a relatively young technology, most people probably already own something that was made with the help of a 3D printer. It might be a pair of shoes, printed in solid form as a design prototype before being produced in bulk. It could be a hearing aid, individually tailored to the shape of the user’s ear. Or it could be a piece of jewellery, cast from a mould made by a 3D printer or produced directly using a growing number of printable materials.

But additive manufacturing is only one of a number of breakthroughs leading to the factory of the future, and conventional production equipment is becoming smarter and more flexible, too. Volkswagen has a new production strategy called Modularer Querbaukasten, or MQB. By standardising the parameters of certain components, such as the mounting points of engines, the German carmaker hopes to be able to produce all its models on the same production line. The process is being introduced this year, but will gather pace as new models are launched over the next decade. Eventually it should allow its factories in America, Europe and China to produce locally whatever vehicle each market requires.

They don’t make them like that any more

Factories are becoming vastly more efficient, thanks to automated milling machines that can swap their own tools, cut in multiple directions and “feel” if something is going wrong, together with robots equipped with vision and other sensing systems. Nissan’s British factory in Sunderland, opened in 1986, is now one of the most productive in Europe. In 1999 it built 271,157 cars with 4,594 people. Last year it made 480,485 vehicles—more than any other car factory in Britain, ever—with just 5,462 people.

“You can’t make some of this modern stuff using old manual tools,” says Colin Smith, director of engineering and technology for Rolls-Royce, a British company that makes jet engines and other power systems. “The days of huge factories full of lots of people are not there any more.”

As the number of people directly employed in making things declines, the cost of labour as a proportion of the total cost of production will diminish too. This will encourage makers to move some of the work back to rich countries, not least because new manufacturing techniques make it cheaper and faster to respond to changing local tastes.

The materials being used to make things are changing as well. Carbon-fibre composites, for instance, are replacing steel and aluminium in products ranging from mountain bikes to airliners. And sometimes it will not be machines doing the making, but micro-organisms that have been genetically engineered for the task.



Everything in the factories of the future will be run by smarter software. Digitisation in manufacturing will have a disruptive effect every bit as big as in other industries that have gone digital, such as office equipment, telecoms, photography, music, publishing and films. And the effects will not be confined to large manufacturers; indeed, they will need to watch out because much of what is coming will empower small and medium-sized firms and individual entrepreneurs. Launching novel products will become easier and cheaper. Communities offering 3D printing and other production services that are a bit like Facebook are already forming online—a new phenomenon which might be called social manufacturing.

The consequences of all these changes, this report will argue, amount to a third industrial revolution. The first began in Britain in the late 18th century with the mechanisation of the textile industry. In the following decades the use of machines to make things, instead of crafting them by hand, spread around the world. The second industrial revolution began in America in the early 20th century with the assembly line, which ushered in the era of mass production.

As manufacturing goes digital, a third great change is now gathering pace. It will allow things to be made economically in much smaller numbers, more flexibly and with a much lower input of labour, thanks to new materials, completely new processes such as 3D printing, easy-to-use robots and new collaborative manufacturing services available online. The wheel is almost coming full circle, turning away from mass manufacturing and towards much more individualised production. And that in turn could bring some of the jobs back to rich countries that long ago lost them to the emerging world.

from the print edition | Special report