We have just introduced a revolutionary new industrial-grade 3D printer – the Sakuu AM Platform, which is the world’s first and only multi-material, multi-process 3D printer. This allows us to 3D print completely different multi-materials – including ceramics and metal – in a single layer capability, enabling the easier and faster creation of functional devices with internal channels and cavities. In a nutshell, this scalable platform will open up the capability for faster, more-cost effective production of complex active devices at industrial rates.
Our initial application area is solid state batteries (SSBs) for the e-mobility market, thanks to the way in which our production process directly addresses and overcomes some of the most inherent problems with the manufacture of such batteries. Specifically, our short-term focus is on the two-, three- and smaller four-wheel electric vehicle market and we already have partners actively sampling our SSBs for these vehicles. These partners include Honda-affiliate, Musashi Seimitsu.
We are changing completely the way in which SSBs are constructed and manufactured. Right now, they are a holy grail technology, but a major setback is that they are very difficult to make. Our Sakuu AM Platform eradicates the shortfalls inherent with existing alternatives – typically low energy density SSBs that are unsuitable for high-volume production and characterised by thick, brittle ceramic layers and poor interface. By harnessing the flexibility and efficiency-enhancing capabilities of our 3D printing process, we are enabling battery manufacturers and EV companies to overcome these pain points and produce higher energy density SSBs with thin monolithic layers and perfect interface.
Another important consideration is that our SSBs (which will be KeraCel™ – branded) will use around 30-50 per cent fewer materials. These can also be sourced locally, significantly reducing production costs.
Insofar as production quantities, our platform will be able to deliver 180,000 18650 type batteries every month (at 90 per cent utilisation). The agility of our AM process also means that, if desired, customers can easily switch production to create different battery types and sizes – for example to achieve double the energy in the same space or the same energy in half the space.
Our platform enables fast and high-volume production of 3D printed SSBs that, compared to lithium-ion batteries offer some crucial advantages. As I mentioned previously, we can deliver twice the energy capacity as we’re packing 1,200 watts per litre in the same volume size. Or if we keep the same energy density, the cost will be halved because the size is halved.
Looking at Tesla’s example puts some context on this. They use 8000 batteries and it gives them 500km (310 miles) range. Our platform will provide double the range with the same number of batteries, or as an alternative e-mobility companies could get the same range on half the number of batteries.
Taking all that into account, it was logical for us to start with the two-, three- and smaller four-wheel EV market because our SSB proposition delivers an obvious and desirable combination of small form factor, low weight and improved capacity benefits.
In addition to this, a major reason why SSBs are praised so highly is by how they overcome safety risks that are prevalent in lithium-ion batteries, by excluding flammable materials. This ultimately enables the implementation of ultra-fast charging technology, without the danger of battery fires. The sooner we can get SSBs implemented into EVs, the sooner common consumer worries surrounding EVs, like range anxiety, can be eliminated.
This is an important issue for us, and I’m pleased to say that we can demonstrably offer improved sustainability benefits. First of all, we’re dealing with only half the level of materials to begin with, and everything we are creating is done so in powder form, so it is all recyclable. This powder-to-powder process means that once a KeraCel™ battery is at the end of its life, we can reclaim almost all of the materials. Unlike the case with lithium-ion options, there is no requirement to extract graphite and the absence of polymer means no incineration or burial in landfill. All in all, this ensures a recycling process of ceramics and metals, that is both cheaper and easier compared to conventional methods.
I think our proposition alleviates disruption for active device manufacture in many ways. Fundamentally, since the production process itself is based on 3D printing, users are harnessing the agility inherent within that technology – which enables localised, on demand manufacturing. That means digital 3D print files can be sent around the world or pulled from a virtual inventory, so that SSBS or other functional devices can be printed where they are needed.
Via our technology proposition, and the fact that materials can be sourced locally rather than from faraway countries, like China, we’re granting users the agility and self-sufficiency to operate ’local’ factories. This ultimately helps drive more efficient production operations and shorter supply chains, which spells great news for manufacturers at any time – not just when they’re dealing with a pandemic or geo-political issue that could significantly impact them.
EVs and other e-mobility vehicles are not a passing fad. With governments around the world constantly seeking more planet-friendly methods of travel to reduce emissions, these vehicles are another necessary solution towards supporting this ongoing quest. So, they’re here to stay and gradually we will see a greater uptake among consumers, in parallel with an increased discouragement by governments for ‘dirty’ fuelled cars – as we’re already seeing with diesel vehicles and older less economical petrol cars.
For this uptake to increase, a few things need to happen. First, the range of EVs needs to increase – range anxiety is very much a pain-point that remains an issue for many consumers. This is something that e-mobility manufacturers need to look at, especially when you consider that not everyone lives in towns or cities, and so do not have easy access to charging stations. Secondly, the cost of EVS is also an issue; they’re too expensive for many consumers to own, let alone upkeep, which coupled with the range problem makes for an important combination that wields a lot of weight insofar as influencing the buying decision.
Thanks to the way in which Sakuu is addressing these crucial issues, I do think our own technology will support an acceleration to greater uptake by making EVs more accessible.
Certainly, based on the current situation, SSBs as they are now will likely be only ready to begin implementation into vehicles by 2030. But I believe that our AM platform will speed up the entire process, so for me, full adoption of EVs via very high-volume sales could occur by 2025/2026.
I am encouraged by the direction in which many major automakers are moving in their commitments towards phasing out diesel options and gradually bringing EV alternatives into their ranges. We saw this again just recently when Ford unveiled its new F-150 Lightning EV. Who would have thought that, even just a few years ago, America’s biggest selling truck would ultimately be available as an EV?
I would like to emphasize that, as a cheaper, faster, local, customisable and more sustainable method of producing SSBs – which as a product deliver much higher performance than currently available alternatives – we expect the potential of our new platform to offer tremendous opportunities to the e-mobility market.
But while SSBs for EVs are our focus in the immediate timeframe as an application that clearly demonstrates our technology capability, they are just the start. Beyond energy storage, our ability to harness true multi-material-in-a-single-layer print capability opens complex end device markets previously closed off to current 3D printing platforms. These include active components like sensors and electric motors for aerospace and automotive; power banks and heatsinks for consumer electronics; PH, temperature and pressure sensors within IoT; and pathogen detectors and microfluidic devices for medical, to name a few.
We’re very excited about what this new and unique proposition is delivering and the way in which it could transform manufacturing as we know it.
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