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How to Buy the Right 3D Printer: A 2019 Guide

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How to Buy the Right 3D Printer: A 2019 Guide

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3D Printing trends and the possible future in 2019

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3D Printing trends and the possible future in 2019. We already know the little bit about 3D Printing.
We are still in the learning process. Nobody is perfect and we are also don’t know several things:)
We learn new things every day. We are so curious to explore what are the new material, products, and any new kind of printer.
Even though we buy everything, what is the importance of those things.
I think reading more books can satisfy our curiosity.

3D Printing Trends That Will Shape Our Future in 2018 – 2019: Takeaways & Statistics from 27 Different Studies

  • https://www.amazon.com/Ultimate-Designing-Prototyping-Manufacturing-Product-ebook/dp/B06X3VG25X/ref=tmm_kin_swatch_0?_encoding=UTF8&qid=1487362581&sr=8-5

3D Printing Business

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How to Start a Successful 3D Printing Business.

3D Printing Business: How To Start A Successful 3D Printing Business

<iframe type=”text/html” width=”336″ height=”550″ frameborder=”0″ allowfullscreen style=”max-width:100%” src=”https://read.amazon.com/kp/card?asin=B00JZ6QL0I&preview=inline&linkCode=kpe&ref_=cm_sw_r_kb_dp_NmlbCb7XAFQCS&tag=sv3dprinter-20″ ></iframe>

 

3D Printing market forecast until 2030

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3D Printing market forecast until 2030.
According to Cramer, says”Before you buy any stock, please, please, do your homework”. I found a book online, the books and education will prevent us from more exposure regarding 3D printing. When we read more we will be more educated ourselves about 3D printing.
We will be more aware the benefits related other important things and the future prospectives.

“How “Fabbing” Will Change Different Industries Until 2030. The Future of 3D Printing in Aerospace, Retail and Healthcare.
Please tell us about your views:)

 

How “Fabbing” Will Change Different Industries Until 2030. The Future of 3D Printing in Aerospace, Retail and Healthcare

https://www.thestreet.com/video/cramers-investing-rule6-do-your-homework-14610072

https://www.reportlinker.com/p03711132/3D-Printing-Metal-Market-by-Form-by-Type-by-Application-and-by-Region-Global-Forecast-to.html

https://www.amazon.com/Different-Industries-Printing-Aerospace-Healthcare/dp/3668027137/ref=sr_1_1?ie=UTF8&qid=1536601481&sr=8-1&keywords=How+%22Fabbing%22+Will+Change+Different+Industries+Until+2030.+The+Future+of+3D+Printing+in+Aerospace%2C+Retail+and+Healthcare

SV3DPrinter’s vision for the ‘99% ENVIRONMENTAL FRIENDLY and GREEN’

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SV3DPrinter’s vision for the environment or ‘GREEN’
Nothing is completely green. 3D printing also not 100% environmental friendly or ‘ GREEN’. When we use the word ‘GREEN’ it is coming from the environment we use technology to make it word GREEN.
We all are contributors to make the world not so ‘GREEN’ or ‘POLLUTION’. We are the polluters.
The same thing for 3D Printing we use different material and printers. Using printers we need energy, same kind of energy we use to grow our raw food.
When we use ‘BIODEGRADABLE’ bags for garbage, the companies make those bags and basket, and paper bags too. Making those kinds of things we contribute more pollution.
Some of us eating raw we feel we are green but not. This is the reason people use the broom to sweep outside and inside of their house. They spread more dust and contributed more pollution to the atmosphere.
Whenever new products come in the market we always attract those things and get rid of the old thing, buy new thing even we don’t really need that.
Some of us taking the dogs for the walk, they are contributing more pollution to the atmosphere.
This is similar to use cell phone doing any other regular thing or cooking food at home.
With the 3D printing, we don’t try to waste the material can reuse the material and make any useful thing out of the waste material.
Every day we have some kind of material we call it waste or recycle. We receive junk mail, frozen food boxes, any kind of drinks bottle, or we drive to buy grocery or walk to buy things.
In my opinion, using 3D Printer may be not 100% ‘GREEN’ or environmental friendly but we can try to make it ‘99% ENVIRONMENTAL FRIENDLY and GREEN’. We need to have more understanding about Additive Manufacturing:)

Silicon Valley’s SV3DPrinter’s vision

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3D-printed lattice for bone repair

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When I was a little kid, one of my foot had the plaster cast for 2 months, I was unable to walk properly because it was stiff and thick.
I think it will be good for people who need a cast for any injury.
Some of the comments on the video, I am using different video and different comments for my post.

I am giving you just an idea.
Please check the link for more information. I can’t find the video for those things.
The biggest problem with this is the holes in the cast. I recently have a broken scaphoid and they cut a hole in the cast as a port for a bone stimulator. They had to fashion a plug for the hole and I need to wear a tensor bandage there to keep the swelling from pushing out at the hole. A cast doesn’t have holes in it for a very good reason – to contain swelling. No Doctor would design this.
This is just another use of a 3D printer, that’s all and it is not ‘revolutionary’ at all. Moreover, you’d need to scan the patient’s limb – we are all different. Then there is time. A hospital will have this done in ten minutes, so how long before this comes out of the printer? Another thing is that you have to clean up a 3D print, or it has rough edges left on it – rather you than me! Then ether is the cost. Are they trying to tell us that this much 3D print filament costs less than plaster?
According to Dr Jeffers and Renishaw, which is one of the world’s leading engineering and scientific technology companies, with expertise in precision measurement and healthcare, the partnership between Imperial College London and Renishaw is creating really exciting data on new materials that can control the way bone repairs itself these materials could change the way orthopaedic implants are designed in the future, and certainly provide an opportunity to improve patient outcomes by repairing the musculoskeletal system with materials that can invoke the desired response in bone.
On display at the show will be a portfolio of additive manufacturing builds to showcase what can be achieved on the Renishaw platform with Beta type capability. The builds include lattice structures which are more complex, in terms of resolution and density, than anything that can usually be achieved using traditional manufacturing techniques”.

http://www.renishaw.com/en/engineering-at-renishaw–40474

A Farewell to Printrbot

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It’s with a heavy heart that we must report Printrbot has announced they are ceasing operations. Founded in 2011 after a wildly successful Kickstarter campaign, the company set out to make 3D printing cheaper and easier. Their first printer was an amalgamation of printed parts and wood that at the time offered an incredible deal; when the Makerbot CupCake was selling for $750 and took 20+ hours to assemble, the Printrbot kit would only run you $500 and could be built in under an hour. Printrbot got their foot in the door early, but the competition wasn’t far behind. The …read more

via A Farewell to Printrbot — Hackaday

3D, 4D 5D Printing Vocabulary

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3D Printing—-

Through computer programmed deposition of material in successive layers to create a three-dimensional object. 

4D printing—–

4D printing adds the dimension of transformation over time.

5D Printing—–

Stereolithography for 3D printing —-

stereolithography apparatus, optical fabrication, photo-solidification, or resin printing) is a form of  3D printing technology used for creating models, prototypes, patterns and production parts in a layer by layer fashion using photopolymerization, a process by which light causes chains of molecules to link, forming polymers.

Stereolithography for 4D printing——

4D printing is fundamentally based in stereolithography, where in most cases ultraviolet light is used to cure the layered materials after the printing process has completed.

Fiber Architecture—-

 Most 4D printing systems utilize a network of fibers that vary in size and material properties. 4D printed components can be designed on the macro scale as well as the micro scale.

Hydro-reactive Polymers/Hydrogels for 4D printing—–

Skylar Tibbits is the director of the Self-Assembly Lab at MIT and worked with the Stratasys Materials Group to produce a composite polymer composed of highly hydrophilic elements and non-active, rigid elements. The unique properties of these two disparate elements allowed up to 150% swelling of certain parts of the printed chain in water, while the rigid elements set structure and angle constraints for the transformed chain. Tibbits et al. produced a chain that would spell “MIT” when submerged in water and another chain that would morph into a wireframe cube when subjected to the same conditions.

Cellulose Composites for 3D printing-———-

Cellulose-based material that could be responsive to humidity.  Wood composite materials that change shape based on their printed grain direction and anisotropic swelling when water is absorbed. This work is 3D printed and studied on the macro scale rather than micro scale, with layer heights at fractions of millimetres rather than microns. 

Thermo-reactive Polymers/Hydrogels for 4D printing—–

Thermo-responsive material.  This new type of 4D printed hydrogel is more mechanically robust than other thermally actuating hydrogels and shows potential in applications such as self-assembling structures, medical technology, soft robotics, and sensor technology. A fluid controlling smart valve printed from this material was designed to close when touching hot water and open when touching cold water. 

Digital Shape-Memory Polymers for 3D printing-———

SMPs are able to recover their original shape from a deformed shape under certain circumstances, such as when exposed to a temperature for a period of time. Depending on the polymer, there may be a variety of configurations that the material may take in a number of temperature conditions. Digital SMPs utilize 3D printing technology to precisely engineer the placement, geometry, and mixing and curing ratios of SMPs with differing properties, such as glass transition or crystal-melt transition temperatures.

Stress Relaxation for 4D printing———-

4D printing is a process in which a material assembly is created under stress that becomes “stored” within the material. This stress can later be released, causing an overall material shape change.

Thermal Photo-reactive Polymers for 4D printing-——–

This type of polymeric actuation can be described as photo-induced stress relaxation.

3D Modeling-——-

CAD, 3D scanner

3D printing-——

Before printing a 3D printing model from an STL file, it must be examined for an error. Most CAD applications produce errors in output STL files.

STL files-

Repair fixes in the original model.

3D scanner——

A 3D scanner is a device that analyses a real-world object or environment to collect data on its shape and possibly its appearance

G-code

G-code is a language in which people tell computerized machine tools how to make something. The “how” is defined by g-code instructions provided to a machine controller (industrial computer) that tells the motors where to move, how fast to move, and what path to follow.

Laser printing—–

Laser printing is an electrostatic digital printing process. It produces high-quality text and graphics (and moderate-quality photographs) by repeatedly passing a laser beam back and forth over a negatively charged cylinder called a “drum” to define a differentially charged image. The drum then selectively collects electrically charged powdered ink toner, and transfers the image to paper, which is then heated in order to permanently fuse the text and/or imagery. As with digital photocopiers, laser printers employ a xerographic printing process.

Injection moulding

Injection moulding Bre or Injection moulding Ame is a manufacturing process for producing parts by injecting material into a mould. Injection moulding can be performed with a host of materials mainly including metals, glasses, confections, and most commonly thermoplastic and thermosetting polymers. Material for the part is fed into a heated barrel, mixed, and forced into a mould cavity, where it cools and hardens to the configuration of the cavity

https://en.wikipedia.org