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[MS5]∎ Libro Gratis 3D Printing The Next Industrial Revolution eBook Christopher Barnatt

3D Printing The Next Industrial Revolution eBook Christopher Barnatt



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Download PDF  3D Printing The Next Industrial Revolution eBook Christopher Barnatt

NOTE There is an updated version of this book called 3D Printing Second Edition.


3D Printing is about to transform our lives. While traditional laser and inkjet printers only make marks on paper, 3D printers build up solid objects in a great many very thin layers. Already pioneers are 3D printing production tools, prototypes, jewelry, sunglasses, works of art, toys and vehicle parts. But this is just the beginning, with digital manufacturing destined to change how we create, transport and store a great many things.

Within a decade, some products may be downloaded from the Internet for printout in store or even at home. Already DIY enthusiasts are building their own 3D printers, while consumer models for the rest of us are just starting to arrive. Meanwhile doctors are learning how to 3D print kidneys and other replacement human organs.

3D Printing The Next Industrial Revolution explores the practicalities and potential of 3D printing today, as well as trying to realistically foresee the impact of 3D printing on the world of tomorrow. The book is written for a wide audience, including 3D printing enthusiasts, entrepreneurs, designers, investors, students, and indeed anybody who wants to be more informed about the next round of radical technological change.
 
Particular features of the book include an extensive chapter that details every current 3D printing technology, as well as an industry overview covering 3D printer manufacturers, software providers, and bureau services. These chapters are then supported by an extensive 3D printing glossary (of over 100 terms) and a 3D printing directory.
 
Other key content includes a chapter on developments in digital manufacturing. This features interviews with a range of pioneering individuals and organizations who are already in the business of 3D printing final products or parts thereof. There are also chapters dedicated to 3D printing and sustainability, bioprinting, and personal fabrication.

3D Printing The Next Industrial Revolution eBook Christopher Barnatt

I bought this book because I had questions about what was possible with 3-D printing. This book gave a pretty good overview of what it can do, who the players are in the industry, and the prospect of future developments.

So these are the questions that I had:

What materials can it work with? The answer is that 3-D printing is most commonly done with plastics. The printhead melts plastic and applies it layer by layer to form a solid three-dimensional object. This is useful for forming models or creating die casts. One limitation of the process is that since each layer must be supported by the one underneath, a figure in which one part descends below everything else must be supported by props of one sort or another. You could build a cow from the legs up, but the udder would need a support. This doesn't seem like a tremendous shortcoming. Other limitations of plastic (melting temperature, hardness, and the fact that it is only a single material) are more significant.

What materials can be printed? For the time being, plastics are the most common. Ceramic and metal powders are also printed. They are suspended in a binder material which holds the work together as it is created. The end product is about 40% binder, 60% target material; brittle and infirm. Additional steps are used to remove the binder and infuse the product with metal (or whatever) to create a durable, solid product.

In some cases, plastics and metals can be applied in other than powdered form. They can both be melted. Certain liquid plastics can be "cured" optically, hardened by the application of light. One process has refined this to the level of individual photons; it can create incredibly detailed models. The limitations are again in the materials: they have plastic's inherent weaknesses, and they are expensive.

It appears to be difficult for the time being to mix multiple materials in the same 3-D printed object. This limitation is being overcome to some extent. Nonetheless, there was no indication that it was now possible, or would ever be possible, to print such complex devices as a motor with insulated electrical windings, or even a ball bearing. It seems that the tight tolerances, the need for lubricants or bushings and so on would make these things impossible to render with today's technology.

What is it used for today? Models, such as those to test the aerodynamic properties of race cars, prototypes so that people can look at what you propose in a design, casting masters for lost wax type for sand casting of metal parts, and direct manufacture of a few types of parts.

One of the problems with almost all 3-D printing is that it is slow. Just as an inkjet printer is slower than a LaserJet, the 3-D printing processes described here pretty much involved moving a single printhead back and forth over an area. It has to traverse two dimensions at a time, and is stepped up through the third dimension layer after layer. The process is therefore quite time-consuming in all of the methods described.

There is one exception, which is to do laser type printing of different layers, and then use a physical glue to put them together. This is mentioned as sort of an afterthought; it is not really 3-D printing.

The idea of printing living tissue into three dimensions is also mentioned. How they do it is not. We know that skin grafts and some other tissues can be grown fairly effectively in laboratories and then applied pressure. Presumably, undifferentiated skin cells could be applied by some sort of a printing process. It seems unlikely that more complex organs could be grown. They did not discuss, and I cannot imagine how one would devise something as complex as a kidney using this process. The cells within such organs are differentiated, and at this point in time 3-D printing is not able to deal with so many different materials. Perhaps they could do it by using the same cellular material and trigger different gene expressions, making the RNA generate different types of cells. They are doing some fairly magical things in biotech, but this would seem to me to be on the outer fringes.

It is well-known that there are plans downloadable from the Internet for printing firearms using 3-D printing. It does not seem to me from reading this book that it would be possible to put together rifles with rifled barrels, the kind of thing that would yield an accurate and reliable weapon. One can conceive that you could create a chamber and a barrel capable of receiving a round of ammunition and firing it. But it seems unlikely that it would be nearly the quality of a machine manufactured rifle.

That is my take away from this whole thing. There are a lot of manufactured items in today's world, but relatively few of them are simple enough to be readily adapted to today's 3-D printing technology. It does not have the ability to deal with a large number of different materials, and does not have the ability to give those materials the physical properties that one needs for most manufactured items.

3-D will be useful for the things issues for now, models. It will be useful for producing one-off parts, such as a transmission gear for a 1941 Ford. If you can describe it in a computer what is supposed to look like, and it can be made out of solid steel, it would be something that would lead itself to 3-D printing. Producing the entire transmission would not seem to be possible, because it would not be able to produce the bearings/bushings and other such parts.

My take as a technology investor is a 3-D printing will continue to grow in applications. There will be some fairly substantial annual growth among the companies in the industry. However, it will never come to a sudden, revolutionary adaptation of 3-D printing, resulting in instant fortunes of the type made on such companies as Microsoft, Oracle, Cisco and Facebook. This is an industry for the long slog. It employs a lot of great people, and there is a lot of innovation, but no single innovation is likely to arrive that will have dramatic industrywide repercussions.

As far as home use goes, despite the author's enthusiasm, it is hard for this reviewer to envision a compelling reason to own one of these. I compare it to the color printer. I didn't get a color printer until they were cheap enough that it was a choice of why not. This is unlike the laser printer. I and many others ditched our dot matrix printers for lasers the moment we could, in the 1980s. It filled a major preexisting need, and HP made a fortune. I don't see that here.

Product details

  • File Size 2510 KB
  • Print Length 276 pages
  • Simultaneous Device Usage Unlimited
  • Publisher ExplainingTheFuture.com (May 4, 2013)
  • Publication Date May 4, 2013
  • Sold by  Digital Services LLC
  • Language English
  • ASIN B00CNPF0ZK

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3D Printing The Next Industrial Revolution eBook Christopher Barnatt Reviews


The book is a semi-scientific introduction to the technology of 3D printing. It deals in detail with the methods the makers and then goes into the future. My only complaint is that the printer compounds really need a separate chapter. Good enough that I using this book as a reference in scientific articles.
"3D Printing, The Next Revolution" is an intriguing look at how 3D Printers will transform our lives by turning computer models into solid, physical objects. What can be produced is astounding; jewellery, vehicle parts, works of art, toys and sunglasses. Even the materials used are not limited and include plastics, ceramics and metals. 3D printing is a radical change from what we're familiar with today; inkjet and laser printers that produce documents or photographs.
What I found exciting was the future use of 3D printing including the fabrication of products at home, personalized to suit the consumer. This would revolutionize the face of the retail industry which is limited to what is produced by manufacturers. Even 'bioprinters' could change the face of medicine by allowing skin or human organs to be 3D printed from a culture of the patient's cells cutting out the need for organ donor lists. As the book points out 3D printing could save the planet environmentally by taking the pressure off her natural resources, although he argues that change comes with a price which could include loss of jobs and a deficiency in stringent health and safety regulations. But this is will have to be assessed in the years ahead.
In the chapters of this book the author covers all facets of 3D printing from the technologies to a closer look at the industry itself. It includes interviews from pioneers in the field as well as providing a wealth of diagrams and pictures, a glossary of 3D terminology and a 3D printing directory.
I found the book not only fascinating, filled with a wealth of information, but well-written and understandable for a layman like myself.
3D Printing The Next Industrial Revolution ...
Low on technical details and too much blue sky speculation.I would not recommend this book for those wanting to understand which 3D printer they ought to purchase.
As promised - Interesting
Very interesting and easy to read. Extremely well organized. The kindle version provided all kinds of links to the factors/players he discusses
Fast shipping, and has lots of info on 3D printing. Figured I'd do some research before I run out and buy a 3d printer..., But now I know more than I did, so the book probably was worth is..
I bought this book because I had questions about what was possible with 3-D printing. This book gave a pretty good overview of what it can do, who the players are in the industry, and the prospect of future developments.

So these are the questions that I had

What materials can it work with? The answer is that 3-D printing is most commonly done with plastics. The printhead melts plastic and applies it layer by layer to form a solid three-dimensional object. This is useful for forming models or creating die casts. One limitation of the process is that since each layer must be supported by the one underneath, a figure in which one part descends below everything else must be supported by props of one sort or another. You could build a cow from the legs up, but the udder would need a support. This doesn't seem like a tremendous shortcoming. Other limitations of plastic (melting temperature, hardness, and the fact that it is only a single material) are more significant.

What materials can be printed? For the time being, plastics are the most common. Ceramic and metal powders are also printed. They are suspended in a binder material which holds the work together as it is created. The end product is about 40% binder, 60% target material; brittle and infirm. Additional steps are used to remove the binder and infuse the product with metal (or whatever) to create a durable, solid product.

In some cases, plastics and metals can be applied in other than powdered form. They can both be melted. Certain liquid plastics can be "cured" optically, hardened by the application of light. One process has refined this to the level of individual photons; it can create incredibly detailed models. The limitations are again in the materials they have plastic's inherent weaknesses, and they are expensive.

It appears to be difficult for the time being to mix multiple materials in the same 3-D printed object. This limitation is being overcome to some extent. Nonetheless, there was no indication that it was now possible, or would ever be possible, to print such complex devices as a motor with insulated electrical windings, or even a ball bearing. It seems that the tight tolerances, the need for lubricants or bushings and so on would make these things impossible to render with today's technology.

What is it used for today? Models, such as those to test the aerodynamic properties of race cars, prototypes so that people can look at what you propose in a design, casting masters for lost wax type for sand casting of metal parts, and direct manufacture of a few types of parts.

One of the problems with almost all 3-D printing is that it is slow. Just as an inkjet printer is slower than a LaserJet, the 3-D printing processes described here pretty much involved moving a single printhead back and forth over an area. It has to traverse two dimensions at a time, and is stepped up through the third dimension layer after layer. The process is therefore quite time-consuming in all of the methods described.

There is one exception, which is to do laser type printing of different layers, and then use a physical glue to put them together. This is mentioned as sort of an afterthought; it is not really 3-D printing.

The idea of printing living tissue into three dimensions is also mentioned. How they do it is not. We know that skin grafts and some other tissues can be grown fairly effectively in laboratories and then applied pressure. Presumably, undifferentiated skin cells could be applied by some sort of a printing process. It seems unlikely that more complex organs could be grown. They did not discuss, and I cannot imagine how one would devise something as complex as a kidney using this process. The cells within such organs are differentiated, and at this point in time 3-D printing is not able to deal with so many different materials. Perhaps they could do it by using the same cellular material and trigger different gene expressions, making the RNA generate different types of cells. They are doing some fairly magical things in biotech, but this would seem to me to be on the outer fringes.

It is well-known that there are plans downloadable from the Internet for printing firearms using 3-D printing. It does not seem to me from reading this book that it would be possible to put together rifles with rifled barrels, the kind of thing that would yield an accurate and reliable weapon. One can conceive that you could create a chamber and a barrel capable of receiving a round of ammunition and firing it. But it seems unlikely that it would be nearly the quality of a machine manufactured rifle.

That is my take away from this whole thing. There are a lot of manufactured items in today's world, but relatively few of them are simple enough to be readily adapted to today's 3-D printing technology. It does not have the ability to deal with a large number of different materials, and does not have the ability to give those materials the physical properties that one needs for most manufactured items.

3-D will be useful for the things issues for now, models. It will be useful for producing one-off parts, such as a transmission gear for a 1941 Ford. If you can describe it in a computer what is supposed to look like, and it can be made out of solid steel, it would be something that would lead itself to 3-D printing. Producing the entire transmission would not seem to be possible, because it would not be able to produce the bearings/bushings and other such parts.

My take as a technology investor is a 3-D printing will continue to grow in applications. There will be some fairly substantial annual growth among the companies in the industry. However, it will never come to a sudden, revolutionary adaptation of 3-D printing, resulting in instant fortunes of the type made on such companies as Microsoft, Oracle, Cisco and Facebook. This is an industry for the long slog. It employs a lot of great people, and there is a lot of innovation, but no single innovation is likely to arrive that will have dramatic industrywide repercussions.

As far as home use goes, despite the author's enthusiasm, it is hard for this reviewer to envision a compelling reason to own one of these. I compare it to the color printer. I didn't get a color printer until they were cheap enough that it was a choice of why not. This is unlike the laser printer. I and many others ditched our dot matrix printers for lasers the moment we could, in the 1980s. It filled a major preexisting need, and HP made a fortune. I don't see that here.
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