3D printing and the blockchain in manufacturing, Deloitte University Press
3D chance for blockchain Additive manufacturing links the digital thread
November 17, 2016
How could blockchain be utilized in additive manufacturing to support supply chain scale and product innovation and add value to the digital thread? Learn the potential challenges and opportunities involved when infusing blockchain into the AM process.
From the creation of the additive manufacturing (AM) design to final production on the shop floor, AM files can be lightly transmitted with the click of a mouse. The digital nature of AM means that parts and products are lighter to share and transmit, enabling the creation of digital supply networks and supply chains. Additionally, it creates the chance to make AM part development fully documentable and attributable. On the other arm, however, there are cons that accompany these digital pros. In the absence of a strong data-protection framework, a digital design-and-manufacture process creates the potential for data theft or tampering. One
For these reasons, it seems crucial that we begin to view AM as an inherently digital production process, and thus consider it with the same perspective as other data-centric innovations. In March 2016, Deloitte University Press published 3D chance and the digital thread, positing that the major element preventing AM from mass adoption was the absence of a digital thread—a single, seamless strand of data that spreads from the initial design concept to the finished part. Two Put more simply, for AM processes to scale at the industrial level, a series of elaborate, connected, and data-driven events likely needs to occur. In this way, successfully deploying AM is less a physical- or hardware-associated production challenge and more a data- or records-management one. This is referred to as the digital thread for additive manufacturing (DTAM).
Understanding the digital thread: An overview
The digital thread is considered the backbone that carries the information across the AM process. Specifically, the DTAM is a single, seamless strand of data that spreads all the way from the initial design concept to the finished part, constituting the information which enables the design, modeling, production, validation, use, and monitoring of a manufactured part. Three
As an individual object is designed, tested, produced, and used, it is described by data created across the DTAM. The capability to dissect, understand, store, and utilize this data, as well as to manage intense computing requests, permits innovators to scale AM production, manage the complexities of AM, and connect AM across the supply chain. Figure one depicts the DTAM.
The digital nature of the AM supply chain suggests the potential for a distributed model across a number of fucking partners and disparate geographic locations. This distributed AM supply chain is enabled by the transmission of AM data and the comparative convenience of printing parts on location. Four Data availability and interconnectivity would help drive the adoption of AM in the supply chain by switching the paradigm and shipping data, not parts. Additionally, the DTAM enables product innovation through technologies such as topology optimization and advanced multiphysics modeling. The DTAM is also a key component of quality assurance for AM (QAAM) and is requisite for part certification. Five
In the same way that the DTAM supports both supply chain scale and product innovation, the blockchain for AM has the potential to serve as a backbone and security layer for the DTAM, underpinning all of the transactions that occur across the digital and physical life cycle for AM. Indeed, the concept of blockchain has already been the subject of uncountable articles and speculated uses.
This paper, however, examines how the data management opportunities and challenges identified in the digital thread can be leveraged via the distributed ledger known as the blockchain: a distributed, append-only ledger for the recording of transactions. This paper will also examine how blockchain may add value to the digital thread, making AM more accessible to industrial and supply chain managers around the world and potentially solving the problem of data recordation for elaborate, certified parts. It will explore the utility of the technology in this space, namely as the single transaction and recordation layer six for digital thread information, and identify areas where blockchain can add value—as well as where it may not. It will also pinpoint where further research is possibly required as these two technologies inevitably intersect.
Blockchain: An overview
While the term “blockchain” has gained prominence in latest years as the subject of uncountable articles, the concept itself may be unacquainted to many in manufacturing. The majority of early use cases have emerged within the financial services industry, primarily in concert with the coverage of the cryptocurrency, bitcoin, the very first use case for blockchain. Seven Therefore, for the purposes of this article, it may be helpful to commence by defining blockchain and clarifying some of its relevance to the supply chain and manufacturing sectors.
So, what is blockchain?
Simply put, blockchain is a distributed ledger that provides a way for information to be recorded and collective by a community. In this community, each member maintains his or her own copy of the information and all members must collectively validate any updates (see sidebar, Collective act and the blockchain). The information could represent transactions, contracts, assets, identities, or anything else that can be described in digital form. Entries are permanent, semi-transparent, and searchable, which makes it possible for community members to view transaction histories in their entirety. Each update constitutes a fresh “block” added to the end of the “chain.” A protocol manages how fresh edits or entries are initiated, validated, recorded, and distributed (see figure Two). Eight
Collective act and the blockchain
Understanding consensus mechanisms and incentive structures across a distributed and untrusted network
If the system is distributed, how are collective activity problems addressed?
Blockchain is essentially software, and the rule sets for a blockchain, or protocols, establish a consensus mechanism—the degree of proof or trust typically needed to validate updates and certify the integrity of the entire. Blockchain does not eliminate the need for trust inbetween parties; it substitutes the existing mechanism for gaining trust (bank, escrow, and so on) with cryptography, and maintaining that trust is not cost-free. The method via which trust is achieved is called the consensus mechanism, and the cost is referred to as the incentive structure—how the maintenance of trust is sustained. These are the two fundamental piles of blockchain, referred to as the consensus mechanism, and an incentive structure to sustain the expenditure of effort for that validation to take place and proceed. The exact features of those two elements—the consensus mechanism and incentive structure—are tailorable across different ecosystems, but the success of the protocol often depends on those two foundations.
Blockchain can exist as open source or in private, consortium, or other platforms. Nine With blockchain, cryptology substitutes third-party intermediaries as the keeper of trust, with all blockchain participants running complicated algorithms to certify the integrity of the entire. Ten Readers may note that cryptography and distribution as a resilience mechanism are concepts that existed before the advent of blockchain in early 2009. The combination of these concepts in a unique manner, however, is what permits for something that may be considered truly fresh: the replacement of existing intermediary institutions typically in place to facilitate value exchange via the reduction or elimination of counterparty risk.
To date, more than a billion dollars in venture capital funds have flowed into blockchain and cryptocurrency (the very first use case for blockchain and its original raison d’etre), focused on applications, eleven platforms, and other start-ups. Despite this exuberance, much of the blockchain ecosystem and its associated applications is still in the research and development phase. One thousand two hundred thirteen
So why is this technology relevant to the supply chain? A range of major players and start-ups are exploring that very question. A key realization is that timely and accurate information about a product via its life cycle is in itself an asset. Blockchain serves as a simultaneous transaction and recordation layer, fourteen and so it has the potential to unite stakeholders on a single platform (not unlike other ERM or enterprise architecture solutions) around a single source of truth. Fifteen As we build extra sensors to increase in-transit visibility and eventually stir toward Internet of Things (IoT) and ubiquitous sensors, sixteen blockchain potentially serves as the data or transaction layer for all of that information moving within and inbetween organizations in an encrypted style.
Recognizing how blockchain can intersect with other emerging technologies and understanding the broad set of potentially applicable asset classes may be key to the development of blockchain applications. The concept of an industrial blockchain and the fusion of AM with ubiquitous sensors and computing have the potential to reshape the industry. As the rapid proliferation of sensors and connected systems accumulate terabytes of information, a distributed ledger system may be a more adequate platform than the traditional centralized enterprise architecture for transacting information.
How does blockchain add value in the environment described above? One way to understand this, and the situations where the technology does add value, is to consider five fundamental characteristics of blockchain and their particular relevance to AM as seen in figure three below: seventeen
Challenges to building a digital thread for additive manufacturing: Blockchain as a potential solution
Albeit industry has begun to build the DTAM, nineteen this effort faces considerable challenges. These challenges primarily concern the integration of software/product lifecycle management (PLM) platforms, numerous printers/printing technologies, and numerous disparate and disconnected physical manufacturing facilities or locations. Twenty Additionally, organizations face challenges in the recordation of events that occur during the additive process, something that may be required for part certification and qualification, as parts need to be checked across the entire process and not just studied at the end. Two thousand one hundred twenty two Blockchain potentially provides the security layer and middleware to integrate and connect the digital thread; however, it will likely not be the solve-all solution to building the DTAM.
Before examining some specific potential use case scripts, the following section will examine how blockchain’s role as simultaneous transaction and recordation layer may apply to the data management challenges inherent to building a sustainable digital thread. In particular, we look at the manner in which blockchain may permit for uniting a diversity of inputs and platforms without the need to solve each associated data standardization or other asset management challenge inherent to the digital thread. This section violates down aspects of the digital thread by phase, discusses associated challenges and offers suggestions as to how blockchain may be able to solve them.
Scan/design and analyze
The DTAM starts with the scan/design and analyze phase (figure Four). In this phase, part designs are created, either by engineers working with CAD implements or by scanning existing parts. Twenty three This phase encompasses the very first bits of digital data that get recorded and finishes with a part model that is ready to print. Twenty four
In this phase there are several handoffs of data that occur, often switching from a CAD system to analysis devices to other design software. Twenty five This often occurs in an environment with many engineers, different parts, departments, and so on. Companies often employ PLM systems to manage all these check-in, check-out transactions twenty six with parts and their associated revisions. This effort is often sophisticated and requires significant configuration and centralized control to work decently. Twenty seven Blockchain, however, permits for append-only timestamp twenty eight version tracking of these switches. This can be distributed across numerous organizations and departments and act as a ledger accounting for all state switches in a decentralized style.
This phase of the DTAM faces several challenges related to file formats and data standardization. Twenty nine While blockchain doesn’t explicitly solve these challenges, providing a secure transaction layer with standardized rule sets or associated metadata for each file format may serve as a collective language upon which information can be communicated —thus creating a format-agnostic accounting of switches to files, analysis performed, and transmission from software device to software implement. Thirty It provides a platform for which file signatures may be tracked across platforms to maintain traceability thirty one in the design and analysis process.
This functionality seems very relevant in the case of part scanners that may require calibration and often use proprietary software to convert scans into CAD or point cloud files that can be imported into other CAD implements or software. Blockchain could record calibration events to help verify scan integrity, by either recording the state switch or even preventing the recording of a transaction (that is, the scan itself) on the blockchain for an improperly calibrated device if the range measured is a result of a machine malfunction or is otherwise outside an acceptable range of outputs. Blockchain can also ensure files are not tampered with when moving inbetween intermediary software devices.
Blockchain is especially relevant in scan/design and analyze due to the almost exclusively digital nature of this phase. Thirty two The technology is especially relevant as it provides append-only recordation that has implications for feedback and simulation loops which inform iterative design and real-time machine control in the build and monitor phase.
Build and monitor
The build and monitor phase of the DTAM is focused on converting the digital model created in the scan/design and analyze phase into a physical part (figure Five). Thirty three This phase is critical, as there is a large amount of data created to enable the build process thirty four and an even larger amount of data that can potentially be captured from sensor data during the build. Thirty five
These data are especially significant in the context of part certification, as unlike conventional subtractive manufacturing, AM requires a paradigm shift and concentrate on qualifying the entire build process. This phase also faces challenges from the potential distributed nature of AM, thirty six scaling across a supply chain and builds occurring in numerous locations. Both of these require systems and infrastructure to track, control, process feedback, and collect data.
These challenges can potentially be addressed with blockchain. In the context of distributed-at-point-of-need manufacturing, blockchain may serve as the tamper-resistant transaction layer creating a reality not stored by any one machine, but instead decentralized and distributed amongst stakeholders. Thirty seven In the example of elaborate part manufacturing requiring audit trails for certification, blockchain may add value as well. Thirty eight Presently, sensor data is not fully integrated in many current applications. Thirty nine Machine control and sensor data collection aren’t explicitly linked, and often machines are augmented with separate sensors not included with the OEM machine itself. Forty Blockchain can transact records of sensor data sets across these discrete segments for a particular part to maintain individual part history. Blockchain is not a file storage solution, but instead provides a mechanism to record digital fingerprints of the capture data sets, similar to how sufficient transaction metadata permits for the validation and recording of cryptocurrency transactions.
In both instances, there is often a need to embed serials and unique identifiers to parts. These can be added by machines (and printed into parts). Blockchain can help maintain attribution for these parts by acting as the uniting layer in which to record the chain of custody and track on a per-part basis with a serial number/unique identifier. Forty one This may help avoid counterfeiting issues and can permit for the dissemination of some information about the part while obscuring certain private information.
Test and validate
The test and validate phase of the DTAM involves many inspection technologies that occur in both the digital and physical realms (figure 6). Forty two These vary in level of complexity and are explained in more detail in the 3D chance for the DTAM paper. One of the challenges in this phase is in tying the records created for the inspection of the individually serialized unit part with the digital models responsible for its creation. Forty three
There are several reasons why this is needed, both from a quality assurance and certification perspective as well as for process tuning and continuous improvement. In the context of the digital twin, a finish digital representation of the physical part and test and validation data is significant. Forty four Understanding and tracking any flaws or tolerance measurements can be vital. Blockchain can transact records of test data sets for a particular part to maintain individual part history. Blockchain also offers append-only functionality and can validate that necessary steps took place as part of qualification and certification. As verification and validation data are needed across a distributed network of playmates and organizations, forty five this may become especially significant. Blockchain permits for the transaction and recordation layer to be one and the same. Forty six Ensuring accurate appendage of test results or modification data to the original files is often critical.
Produce and manage
In the produce and manage phase of the DTAM, parts are put to their intended use in the field. There is the chance to collect data on these parts through integrated sensors and monitors which feed continuous improvement feedback loops going back to part design (figure 7). Forty seven The data created through these sensors are by nature disparate, as components or products are propagated for usage. Blockchain provides a platform for which sensor data forty eight can be tracked across platforms and provide attribution to original part design, manufacture, and distribution. This can happen in a decentralized style not requiring central control. This is analogous to using blockchain for IoT-connected devices. Forty nine
Promising use cases for blockchain beyond cryptocurrencies and other financial assets are only now beginning to expose themselves. The unique characteristics of blockchain described above may eventually fit well with the AM problem set vs. other enterprise architecture or databasing solutions.
Blockchain is by no means a silver bullet solution for safeguarding the digital thread. However, it has implications for each of the major stages of the thread. For this reason, blockchain is likely worthy of further explore in the AM context. As with any enterprise software solution, the implementation can vary on a case-by-case basis.
Blockchain and additive manufacturing: next steps
AM as a capability is placed to significantly grow in scale in the near future. At approximately $Five billion annually as of two thousand sixteen and predicted to be at least $20 billion by 2020, fifty the industry seems at high risk of significant growing aches as it scales. In particular, the digital nature of the AM product poses novel problems in an otherwise traditional manufacturing environment.
The emerging concept of the “digital thread for AM” provides a conceptual reaction to securing and organizing the data generated across the end-to-end AM process. The next step for industry leaders is to consider the potential technology solutions to enable the digital thread. This paper illustrates the unique potential of blockchain to address each of the components of the digital thread and provides illustrative examples of the specific value that blockchain could add. While all decisions should be made on a case-by-case basis, blockchain options may provide an intriguing path for the AM industry to explore further. Companies and organizations should keep a finger on the pulse of developments in the blockchain space as they look to build secure and connected manufacturing infrastructure. With the ever-increasing need for connectedness and security, blockchain may provide the backbone enabling manufacturing of the future.