Newtecnic reveals some exciting options that have generated new business ideas and opportunities.

By Andrew Watts, FICE, FIED, FIET, FRSA, RIBA

3D printers are used extensively in automotive, aerospace, and consumer goods industry applications to validate form. During the last three decades, considerable business and technical experience has been built up in enterprises that use this technology. On this foundation, and now that prices are falling, many more machines are being put into service.

Not only have 3D printers become less expensive, their capabilities have evolved. Machines that can print titanium, aluminum, silver, and now carbon fiber, are revolutionizing many businesses, including for example, jewelry making, by enabling production of shapes and designs that could not be made by conventional techniques. The opportunity to show people what a design will look like — even make a plastic example first — allows people to acquire often-unique pieces with no risk of disappointment or surprise at the outcome.

The same idea is current in the life sciences industry where dentists will soon be able to produce perfect crowns on demand from in-house machines while other types of medical implants could be made to measure. There are opportunities throughout these developments for new types of services that will evolve to help companies make the most of the technology. Manufacturing is entering a renaissance where start-ups can produce brilliantly designed, high-quality products without the need for a factory.

Onsite manufacture

Newtecnic’s design engineering partnerships with U.S. university engineering departments are aimed at developing new building products and assembly methods that see them accurately and efficiently manufactured and installed on some of the world’s most iconic buildings.

Rather than design components and have them made in remote factories to be delivered and then assembled onsite, Newtecnic facilitates the use of Construction Labs where local skilled craftspeople, using locally sourced materials, deploy very advanced production machinery in temporary factories. These small but efficient manufacturing cells that incorporate 3D printing are dedicated to producing mass-customized components. And as robots become more advanced, they will interact with Construction Labs, generating, moving, and installing both new and replacement building parts.

Work station

Aspects of The King Abdullah Financial District (KAFD) Metro Hub in Riyadh, Saudi Arabia, have been design engineered by Newtecnic in the U.S. Inspection, monitoring, and precise measurement of concealed areas behind panels, and within the completed building’s fabric, can be executed by small flying LiDAR- and camera-equipped drones and robots. High-resolution building and system performance data collected this way can be shared with, and coupled to, onsite Construction Labs equipped with 3D printers that fabricate components that perfectly fit the as-built structure. Other projects around the world that the company is engineering are planned to deploy Construction Labs from the earliest stages of construction. In this way, mid-20th century methods and devices of mass-production are being replaced by new automated, very flexible, highly controllable and adaptable sets of tools efficiently operated at a local level.

Envisioned in 2038 at Changsha International Culture and Arts Centre, 3D printers are deployed in a Construction Lab to manufacture replacement building components. Image: Newtecnic

Light bulb moment

In the past, to have an idea for a product was one thing, but to have it made was quite another. 3D printers have changed that, so now a single product can be made, small batches are easy to produce, and individual customization has become practical. If demand increases, more machines can be simply added to meet it.

Existing manufacturing can easily adapt to accommodate 3D printing and many successfully deploy it extensively. New types of companies are also emerging that exploit the reduced cost base of 3D printing set-ups. These offer innovation through flexibility that is hard to match in a more traditional manufacturing environment.

There are opportunities too in the spares industry. Companies that are obliged to provide spare parts for many years — such as in the automotive, aerospace, and increasingly the construction industry — face storage and logistics costs with “dead” stock. With 3D printing, it is simple to maintain “digital spares” that are printed to order. That means that any amount of digital spare parts can be held in stock indefinitely. This effectively extends products’ lives with all the reputational and environmental benefit that brings.

Fast and faster

Aerospace, F1, consumer product, life science, and construction companies are increasing their 3D printer deployment to help them innovate faster. And in areas of economic under development where manufacturing industry has not taken a foothold, 3D design and printing offer great business innovation potential. Creating products locally means that new agile businesses can start with low investment, minimal infrastructure, and potentially high returns. The ability to manufacture to demand is very appealing in poor areas of the world that view 3D printing as a way to leapfrog the industrial world’s production and development cycles. Innovative manufacturers are benefiting from this development by siting machines across the world to take advantage of operating conditions and energy costs.

The construction industry sees 3D printing as a way to avoid lengthy spare parts procurement supply chains by making parts and equipment onsite. Newtecnic is currently working in partnerships with American commercial and university engineering departments to develop, test and validate these methods.

Robot builders in space

Many people believe that our future includes colonizing other planets. Development of technologies for mining asteroids is already underway and in 20 years mining and living in space may be a reality. Robotized 3D printing in space would be a viable alternative to sending product supplies from Earth. It is predicted that the first permanent off-Earth dwellings will be built by robots using 3D printing techniques developed for the materials and conditions that are found on other planets. This long-term business opportunity has already spawned several development companies with Richard Branson and Google’s Larry Page as investors.

Currently my company’s technology is instrumental in the design, construction, and simplification of complex buildings. Engineering for habitation on other planets is a daunting prospect but one that can be resolved by innovatively evolving current design engineering and manufacturing practices.

It’s the year 2038 and inside the Newtecnic Construction Lab additive manufacture is used to make replacement façade panels for the King Abdullah Financial District Metro Hub in Riyadh, Saudi Arabia. Each component fits perfectly because it is developed from data collected using LiDAR scans from the as-built structure. Image: Newtecnic

Fab gear

Started as an outreach project from MIT’s Center for Bits and Atoms (CBA), Fab Labs (www.fablabs.io) aim at developing programmable molecular assemblers able to make almost anything. Projects in Fab Labs include solar and wind-powered turbines; computers and equipment for agriculture and health care; housing; and printing complete working machines — including 3D printers. Not surprisingly, there are many business opportunities and new enterprise scenarios being developed around Fab Labs and their intensive use of 3D design technology.

Another idea is for people to use designers’ basic forms to customize their own products. This means that people without design skills can partner with designers to create new products. As 3D printing prices fall, this market, driven by “collective intelligence,” will inevitably grow. Scanning an item with your phone and making a part is also not far away. This means, for example, people could scan, make, repair, and replace parts rather than discard products because one component is faulty. The financial argument is strong because there is immediate return through money saved. Roadside breakdown repairers could even manufacture parts on the way to a vehicle that has communicated directly with a 3D printer on-board the recovery vehicle.

Deploying modular and “cassette” building façade design methodology means buildings can easily be modified to take advantage of new technologies as they arise. In coming years, high-performance concrete and steel components will have evolved to become stronger, lighter, and more durable. New building materials will also be developed and faster 3D printers working onsite or offsite will make optimized components to be fitted by new types of robots. Many building owners and operators will, by these means, simply adapt, refresh, and renew buildings throughout their lives to suit contemporary needs.

In the coming years, 3D printing is set to grow exponentially and, as it does so, new construction industry opportunities will abound. Correctly positioning a business to capitalize on that prospect presents many exciting ways for enterprises to flourish in this inspiringly innovative technological era.


Andrew Watts, FICE, FIED, FIET, FRSA, RIBA, is CEO of Newtecnic (www.newtecnic.com), an engineering design house that undertakes the engineering design of building structures, façades, and MEP installations in partnership with leading international developers, architects, and contractors. In partnership with the Engineering Departments of Cambridge University, Newtecnic’s R&D team analyzes, develops, tests, validates, and specifies new building technologies and methods. Newtecnic has offices in the U.S., UK, and Saudi Arabia.

X