How to rise in the IIoT Maturity Model for the manufacturing industry

| May 27, 2019
HOW TO RISE IN THE IIOT MATURITY MODEL FOR THE MANUFACTURING INDUSTRY
This Industrial IoT Maturity Model forms the foundation of future plans for the IoT journey in the manufacturing industry: from Digitalisation to Industry 4.0. Discover how you can become a fully mature IoT enterprise. Use the Industrial IoT Maturity Model to evaluate your current position and set a clear objective. Understanding your company’s current maturity state and willingness to adapt for greater business value is critical for IoT adoption.

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MC Electronics

Founded in 1982, MC Electronics, LLC is a leader in Electronics Manufacturing Services and Solutions. Servicing our customers worldwide from our Northern California and Juarez Mexico manufacturing and warehousing facilities, MC Electronics provides full integration of electronic products ranging from wiring harnesses/cable assemblies to turnkey system assembly/sub-assembly.

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Technologies to Adopt Now to Enable the Smart Warehouse Concept

Article | December 8, 2021

Why should warehouses be left behind as everything gets smarter in the manufacturing world? The future warehouse will be smarter and more innovative to speed up supply chain management procedures and assist businesses in intelligently segregating their raw materials and manufactured goods. So, what does it mean to have "a smart warehouse"? A smart warehouse is a big infrastructure that stores raw materials and manufactured goods and employs machines and computers to handle routine warehouse tasks that humans previously performed. Smart warehouses are inspired by smart factories and operate in a data-driven environment. It is the ability of the system in the warehouse to make it more efficient and productive by utilizing networked, automated technology. “I advocate business leaders get to know more about what AI can do and then leverage AI in proofs of concept.” – Michael Walton, Director, Industry Executive (Manufacturing) at Microsoft According to EASYECOM, nine out of ten businesses intend to include commercial service robots into their operations in some form. By 2025, it is projected that there will be roughly 23,000 robotic warehouses in the United States alone, up from only 2,500 in 2018. Furthermore, the global smart warehousing market is expected to grow at a CAGR of 11.5 percent from USD 14.8 billion in 2021 to USD 25.4 billion in 2026, according to GlobeNewswire. As can be seen, the current warehouse automation trends are scaling up the worldwide market for smart warehouses, and the value of the smart warehouse business has a long way to go in the future. So, what are the technologies that are changing traditional warehouses into intelligent warehouses? Continue reading this article to get a better understanding of this. Top 5 Warehouse Technologies to Take On Numerous manufacturing and non-manufacturing organizations, including IKEA, NIKE, and WALMART, utilize smart warehouses to streamline their overall operations. The technologies listed below assist many of them in implementing the modern warehousing idea. A Warehouse Management System Warehouse Management Systems, or WMSs, are comprehensive software systems that consolidate all of your critical data onto a single platform that can be easily accessed by team members and selected supply chain partners. This data compartmentalization allows for lightning-fast reporting, which allows for super-efficient planning, even for unexpected events. Overall, the use of warehouse management systems complements the use of other automated aspects perfectly. Automated Picking Tools The days of error-prone picking are long gone; now, when picking automation elements are integrated into the flow, warehouses can profit from near-perfect picking rates. In addition, picking procedures can be aided by various techniques, including voice-automated order picking, pick-to-light, and robotic order picking. These technologies also use cutting-edge barcoding choices that easily interface with your selected management software to provide the quickest and most accurate automated reporting experiences. Automated Guided Vehicles (AGVs) AGVs, or automatic guided vehicles, are the best approach to speeding up storage and retrieval processes. AGVs are becoming more robust as technology advances, but older models have proven safer and more cost-effective than manual labor. Their functions include pallet, rack, and other container storage and controlling and automating the entire receiving process. Platforms for Automated Inventory Control Automated inventory control platforms, when combined with a few other technological cornerstones, such as asset and inventory tags, may eliminate labor, guesswork, and unnecessary time from traditional inventory control. In addition, there are several advantages to using these platforms, including their ability to automatically count inventories and synthesize data for real-time reporting that can be viewed remotely. IoT Implementation The Internet of Things (IoT) is used by some of the world's most efficient smart warehouses, such as Amazon, as an entire concept rather than a specific technology. All of your automated and manual operations may be optimized when IoT is used to control all of your moving parts, both automated and manual. This innovative technology helps optimize a warehouse's inventory control systems, workforce planning, and, of course, the overall customer experience. While implementing technology improves the notion of a smart warehouse, it isn't always possible for every warehouse to do so instantly, especially since implementing technology takes significant financial and infrastructure changes. That's why warehouses are adopting the concept of collaborative robots (cobots). These are the autonomous elements that work with existing human workers. Cobots allow warehouses to preserve many of their existing procedures and infrastructure while gaining the benefits of fully autonomous elements. Amazon's Smart Warehouses Integrates Humans and Robots Amazon acquired Kiva Systems for $775 million in 2012, highlighting its interest in warehouse robotics. Kiva Systems was the sole known producer of warehouse robots, serving many different logistics organizations. Amazon bought Kiva Systems' machines, constructed and used them all. Amazon Robotics is a new business unit that the company has developed. Amazon recently established a semi-automated warehouse with human workers and robots. As a result, simple chores like moving parcels and scanning barcodes are automated. However, organizing goods and carrying complex objects (like bottles) is still part of human work. Amazon's automated warehouse employs over 400 robots and hundreds of human employees. Amazon's rise in two crucial areas – online shopping and logistics – has been accelerated by warehouse robots. Final Words Modern warehousing is a new trend in the manufacturing industry that automates numerous procedures required for keeping manufacturing materials and products organized. Technology trends in warehousing are making manufacturers' jobs easier and promoting the future warehouse model in 2022. Implement the cutting-edge technology outlined above to stay current with warehousing trends and boost productivity, efficiency, accuracy, and flexibility for your personnel and their operations. FAQ What are the key benefits of a smart warehouse? A smart warehouse improves the warehouse's productivity, efficiency, and accuracy. It also allows personnel and procedures to be flexible. What exactly is WMS? A warehouse management system (WMS) is a software solution that handles the supply chain from the distribution center to the retail shelf. What is COBOT? Cobots are designed to work with people rather than replace them. Cobots are also known as people-focused robots. They can help humans simplify and improve their work. { "@context": "https://schema.org", "@type": "FAQPage", "mainEntity": [{ "@type": "Question", "name": "What are the key benefits of a smart warehouse?", "acceptedAnswer": { "@type": "Answer", "text": "A smart warehouse improves the warehouse's productivity, efficiency, and accuracy. It also allows personnel and procedures to be flexible." } },{ "@type": "Question", "name": "What exactly is WMS?", "acceptedAnswer": { "@type": "Answer", "text": "A warehouse management system (WMS) is a software solution that handles the supply chain from the distribution center to the retail shelf." } },{ "@type": "Question", "name": "What is COBOT?", "acceptedAnswer": { "@type": "Answer", "text": "Cobots are designed to work with people rather than replace them. Cobots are also known as people-focused robots. They can help humans simplify and improve their work." } }] }

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Which Additive Manufacturing Process Is Right for You?

Article | December 6, 2021

Additive Manufacturing (AM) uses computer-aided design (CAD) or 3D object scanners to create accurate geometric features. In contrast to traditional manufacturing, which frequently involves milling or other processes to eliminate superfluous material, these are produced layer by layer, as with a 3D printing process. The global additive manufacturing market is expected to grow at a 14.42 percent annual rate from USD 9.52 billion in 2020 to USD 27.91 billion in 2028, according to reports and data. Overall, the worldwide 3D printing industry is gaining traction due to various reasons, some of which are listed below. Significantly, greater resolution Reduced manufacturing costs as a result of recent technology breakthroughs Ease of creating customised goods Increasing possibilities for printing with diverse materials Funding by the government for 3D printing ventures Additive manufacturing is available or may be implemented in various procedures, which is the primary objective of this article. First, we'll look at the seven additive manufacturing processes and which one is the best to use. So let us begin. “Don’t be afraid to go outside of your industry to learn best practices. There might be something that surprises you or inspires you to try in your line of work.” – Emily Desimone, Director of Global Marketing at SLM Solutions Additive Manufacturing Processes There are numerous diverse additive manufacturing processes, each with its own set of standards. Here are the seven additive manufacturing procedures that many manufacturers consider based on their benefits from each process, or whichever approach best suits their product requirements. Material Jetting This additive manufacturing process is quite similar to that of conventional inkjet printers, in which material droplets are selectively placed layer by layer to build a three-dimensional object. After completing a layer, it is cured with UV radiation. VAT Photo Polymerization This procedure employs a technology called photo polymerization, in which radiation-curable resins or photopolymers are utilized to ultraviolet light to generate three-dimensional objects selectively. When these materials are exposed to air, they undergo a chemical reaction and solidify. Stereo lithography, Digital Light Processing, and Continuous Digital Light Processing are the three primary subcategories. Binder Jetting Binder jetting is a process that deposits a binding agent, typically in liquid form, selectively onto powdered material. The print head deposits alternating layers of bonding agent and construction material and a powder spreader to create a three-dimensional object. Material Extrusion S. Scott Crump invented and patented material extrusion in the 1980s using Fused Deposition Modeling (FDM). The continuous thermoplastic filament is fed through a heated nozzle and then deposited layer by layer onto the build platform to produce the object. Powder Bed Fusion Powder bed fusion procedures, particularly selective laser sintering, were the pioneers of industrial additive manufacturing. This approach melts the powdered material and fuses it using a laser or electron beam to form a tangible item. The primary kinds of powder bed fusion are direct metal laser sintering, selective laser sintering, multi-jet fusion, electron beam melting, selective laser melting, and selective heat sintering. Sheet Lamination Sheet lamination is a catch-all term encompassing ultrasonic additive manufacturing, selective deposition lamination, and laminated object manufacturing. All of these technologies stack and laminate sheets of material to form three-dimensional objects. After the object is constructed, the parts' undesirable areas are gradually removed layer by layer. Directed Energy Deposition Directed energy deposition technology employs thermal energy to melt and fuse the materials to form a three-dimensional object. These are pretty similar to welding processes, but are much more intricate. Which Additive Manufacturing Process is best? Why? Based on three fundamental factors, additive manufacturing techniques are categorized into seven types. First, the way material is solidified is determined first by the type of material employed, then by the deposition technique, and finally by how the material is solidified. The end-user often chooses an additive manufacturing technique that best suits his requirements, followed by the explicit material for the process and application, out of the seven basic additive manufacturing processes. Polymer materials are commonly used in AM techniques because they are adaptable to various procedures and can be modified to complicated geometries with high precision. Carbon-based compounds are used to strengthen polymers. Polymers, both solid and liquid, have been widely used due to the variety of shapes, formability, and end-use qualities available. Wherever the light-activated polymer contacts the liquid's surface, it instantly solidifies. Photo polymerization, powder bed fusion, material jetting, and material extrusion are the most common additive manufacturing procedures for polymers. The materials employed in these processes can be liquid, powder, or solid (formed materials such as polymer film or filament). How BASF is Using Additive Manufacturing BASF is a chemical company. BASF, one of the world's major chemical companies, manufactures and provides a range of 3D printing filaments, resins, and powders within its extensive material portfolio. The company, well-known in the 3D printing sector, has formed major material agreements with several 3D printer manufacturers, including HP, BigRep, Essentium, BCN3D, and others. BASF went even further in 2017 by establishing BASF 3D printing Solutions GmbH (B3DPS) as a wholly-owned subsidiary to expand the company's 3D printing business. In addition, BASF stated last year that B3DPS would change its name to Forward AM. BASF's role in the 3D printing business, however, is not limited to material development. BASF has made several investments in 3D printing companies over the years, including the acquisition of Sculpteo, one of the significant French 3D printing service bureaus, last year. BASF sees 3D printing as having a bright future. With the growing popularity of professional 3D printers, all of these systems will eventually require robust, high-quality polymer materials to perform at their best – and BASF has been paving the way to becoming one of the leading solution providers. Final Words All additive manufacturing procedures are unique and helpful in their way. Still, some have additional advantages over others, such as the material used, highresolution, precision, and the ability to build complicated parts. Because of these added benefits, photopolymerization, material jetting, powder bed fusion, and material extrusion are preferred over others. Therefore, choose the AM process that is best suited to your manufacturing business and will assist you in achieving the desired final product output. FAQs What are the benefits of additive manufacturing? AM enables manufacturers to reduce waste, prototyping costs, and customization while conserving energy and increasing production flexibility. Additionally, it benefits the supply chain and the environment, encouraging businesses to increase their manufacturing sustainability. What is the major challenge in additive manufacturing? Many businesses are struggling with the current difficulty of producing large and odd-sized parts using additive manufacturing. So, this can be considered a significant challenge in additive manufacturing. What are the steps of additive manufacturing? The additive manufacturing steps are divided into four steps as below, Step1 - Design a model with CAD software Step2 -Pre-processing Step3 -Printing Step4 - Post-processing { "@context": "https://schema.org", "@type": "FAQPage", "mainEntity": [{ "@type": "Question", "name": "What are the benefits of additive manufacturing?", "acceptedAnswer": { "@type": "Answer", "text": "AM enables manufacturers to reduce waste, prototyping costs, and customization while conserving energy and increasing production flexibility. Additionally, it benefits the supply chain and the environment, encouraging businesses to increase their manufacturing sustainability." } },{ "@type": "Question", "name": "What is the major challenge in additive manufacturing?", "acceptedAnswer": { "@type": "Answer", "text": "Many businesses are struggling with the current difficulty of producing large and odd-sized parts using additive manufacturing. 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This Is How You Can Lower Your Manufacturing Overhead

Article | December 21, 2021

When it comes to developing a budget for the following financial year of your manufacturing business, many operations managers start with direct labor and material expenditures. But, what about manufacturing overhead costs? Manufacturing overhead is any expense not directly tied to a factory's production. Therefore, the indirect costs in manufacturing overhead can also be called factory overhead or production overhead. Outsourcing and globalization of manufacturing allows companies to reduce costs, benefits consumers with lower-cost goods and services, and causes economic expansion that reduces unemployment and increases productivity and job creation. – Larry Elder So, this article focuses on some highly effective overhead cost reduction methods that would help you build a healthy budget for the following year. Manufacturing Overhead Costs: What Is Included? Everything or everyone within the factory that isn't actively producing items should be considered overhead. The following are some of the variables that are considered overhead costs: Depreciation of equipment and productionfacilities Taxes, insurance, and utilities Supervisors, maintenance, quality control, and other on-site personnel who aren't producing signs Indirect supply from light bulbs to toilet paper is also included in the overhead cost. Manufacturing Overhead Costs: What Is Excluded? Everything or everyone within or outside the factory that is actively producing items should be excluded from the overhead costs. Factory overhead does not include the following: Product materials Employee costs for those making the goods daily External administrative overhead, such as a satellite office or human resources Costs associated with C-suite employees Expenses associated with sales and marketing - include pay, travel, and advertising How to Calculate Overhead Costs in Manufacturing To know the manufacturing overhead requires calculating the manufacturing overhead rate. The formula to calculate the manufacturing overhead rate i.e. MOR is basic yet vital. To begin, determine your overall manufacturing overhead expenses. Then, add up all the monthly indirect expenditures that keep manufacturing running smoothly. Then you can calculate the Manufacturing Overhead Rate (MOR). This statistic shows you your monthly overhead costs as a percentage. To find this value, divide Total Manufacturing Overhead Cost (TMOC) by Total Monthly Sales (TMS) and multiply it by 100. The final formula will be: Assume your manufacturing overhead expensesare $50,000 and your monthly sales are $300,000. You get.167 when you divide $50,000 by $300,000. Then increase that by 100 to get your monthly overhead rate of 16.7%. This means your monthly overhead expenditures will be 16.7% of your monthly income. Being able to forecast and develop better solutions to decrease production overhead. Five Ways to Reduce Manufacturing Overhead Costs A variety of strategies may be used by manufacturing organizations to reduce their overhead costs. Here is a summary of some of the most important methods for reducing your manufacturing overhead costs. Value Stream Mapping – A Production Plant Process Layout A value stream map depicts the entire manufacturing process of your plant. Everything from raw material purchase through client delivery is detailed here. The value stream map provides you with a complete picture of the profit-making process. This overhead cost-cuttingmethod is listed first for a reason because every effort to reduce manufacturing overhead costsstarts with a value stream map. Lean manufacturingis also one of the techniques of eliminating unnecessary time, staff, and work that is not necessary for profit and has gained undue favor in the manufacturing process. You must first create a value stream map of the whole manufacturing process for this technique to work. Once the lean manufacturing precept is established, the following strategies for decreasingmanufacturing overhead expenses can be examined. Do Not Forget Your Back Office Management Before focusing on factory floor cost reduction techniques, remember that your back offices, where payment processing and customer contacts occur, may also be simplified and increase profitability. Fortunately, automation can achieve this profitability at a cheap cost. Manufacturers increasingly use robotic process automation (RPA) to sell directly to customers rather than rely on complex supply networks. This automation eliminates costly human mistakes in data input and payment processing by automatically filling forms with consumer data. Moreover, the time saved from manual data input (and rectifying inevitable human errors) equates to decreased labor expenses and downtime. Automating Your Manufacturing Plant For a long time, manufacturers saw factory automation as a game-changer. As a result, several plant owners make radical changes in their operations using cutting-edge technologydespite knowing it realistically. Over-investing in technologies unfamiliar to present industrial personnel might be deemed a technology blunder. Investing in new technology that doesn't generate value or is too hard for current staff to use might be a mistake. It's usually best to start small when implementing newtechnology in manufacturing. Using collaborative robots in production is one way to get started with automation. They are inexpensive, need little software and hardware, and may help employees with mundane, repeated chores that gobble up bandwidth. It is a low-cost entry point into automation that saves labor expenses and opens the door for further automation investments when opportunities are available. Reuse Other Factory Equipment and Supplies Check with other factories to see if they have any unused equipment or supplies that may be "redeployed" to your manufacturing plant. Redeployment would save you time and money by eliminating the need to look for and install new equipment while lowering your overhead costs. Outsourcing a fully equipped factory, equipment, or even staff can also assist in lowering overhead costssince you will only pay for what you utilize. As such, it is a viable method to incorporate into your production process. Employ an In-house Maintenance Expert An in-house repair technician can service your equipment for routine inspections, preventive maintenance, and minor repairs. This hiring decision might save money on unforeseen repair expenses or work fees for an outside repair provider. Having someone on-site who can do emergency repairs may save you money if your equipment breaks after business hours. Final Words Manufacturing overhead costis an essential aspect of every manufacturing company's budget to consider. Smart manufacturingis intended to be productive, efficient, and cost-effective while effectively managing production expenditures. Calculating the manufacturing overheadcan provide you with a better understanding of your company's costs and how to minimize them. Depending on the conditions or geographical needs, each manufacturing plant's overhead expensesmay vary. As a result, identify your production overhead costsand concentrate on reducing and improving them. FAQ What are manufacturing overheads? Manufacturing overhead cost is a sum of all indirect expenses incurred during production. Manufacturing overhead expenses usually include depreciation of equipment, employee salaries, and power utilized to run the equipment. What is a decent overhead percentage? When a business is functioning successfully, an overhead ratio of less than 35 % is considered favorable. How can I calculate the cost of manufacturing per unit? The overall manufacturing cost per unit is determined by dividing the total production expenses by the total number of units produced for a particular time.

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The Future of Additive Manufacturing: Trends and Predictions

Article | January 21, 2022

3D printing technology and its role in future manufacturing are grabbing the interest of industry experts. In terms of elevating future products, future additive manufacturing has a lot to offer the business. Additive manufacturing is developing and stretching its wings on a daily basis, becoming an integral part of every industry, including manufacturing, healthcare, education, and more. In this article, we'll shed some light on the 3D printing future trends, which will assist the business in deepening its impact across industries. Furthermore, we will explore whether the additive manufacturing business is worth investing in as well as who the major players are that have already invested in the future of 3D printing. Future Trends in the Additive Manufacturing Industry Enhanced Machine Connectivity Making AM solutions (including software and hardware) easier to integrate and connect to the factory floor is one of the key AM trends we predict to advance in the coming years. It has been a long time since the AM hardware market has been filled with closed, or proprietary, systems. These systems generally function with materials and software given or approved by the machine OEM and are not easily integrated with third-party alternatives. Closed systems are important for process dependability, but they also restrict collaboration and connectivity. Companies expanding their AM operations will need to connect their machines and software to their production environments. When it comes to additive manufacturing, using siloed solutions is a surefire way to fail. Importantly, we see hardware manufacturers increasingly focusing on solutions that can be integrated with the production floor. For example, a 3D printing market leader like Stratasys is a good illustration of the trend. In December, the business announced an extension of its previously closed machines' connection.Consumers may now integrate and control their additive production using software programs of their choosing, not just Stratasys' systems. For AM facilities, system connectivity is no longer an option. It's exciting to see the AM industry players recognize and solve this requirement. AM and AI Continue to Converge AM growth is incorporating AI and machine learning. AI can help with material development, machine setup, part design, and workflow automation. So, in the future, we anticipate seeing more AI and AM technology integration. Combined with AM systems, AI will improve process control and accuracy. For example, Inkbit is currently working on an AI-powered polymer vision system. This technology can scan 3D printing layers and anticipate material behavior during printing. Generative design, already generally recognized as a key digital advance in AM, may tremendously benefit from AI and machine learning. It has so far been utilized to improve load routes when strength and stiffness are dominant. It can also be utilized to optimize thermal or vibration. AI and machine learning will advance generative design, allowing new concepts to be completely suited to AM.While we may be a few years away from fully developing the capacity to automatically adapt designs to process, we anticipate significant breakthroughs this year that will bring us closer. AM Will Drive Decentralization In order to future-proof their supply chains, many manufacturers are following new supply chain models and technology that allow them to cut prices or switch goods more easily. Increasing flexibility and agility will necessitate distributed, localized production, assisted by additive manufacturing.To reduce the number of steps required to manufacture complex metal or polymer structures, shorten lead times, and enable digital inventory management, digital inventory management can be automated. These advantages make it ideal for the distributed manufacturing model. We believe that in the near future, more businesses will actively explore distributed manufacturing with AM. According to a recent HP survey, 59% of organizations are now considering hybrid models, while 52% are looking into localized digital manufacturing. 3D Printing Future: Major Predictions In Jabil's 2021 3D printing trends survey of over 300 decision-makers, 62% of participants claim their organization is actively using additive manufacturing for production of their product components, up from 27% in 2017. Many such manufacturers are on the lookout for the latest additive manufacturing trends and forecasts. So let's begin. Increasing Flexibility and Customization Customized goods are a popular consumer trend, impacting several sectors. Rather than buying a mass-produced item, customers are increasingly demanding a custom-made item that meets their specific needs. Additive manufacturing's low-volume production capabilities simply enable personalization and customization. 3D printing allows for more responsive design options, particularly for additive manufacturing. Manufacturers can afford to make smaller batches, allowing designers and engineers to alter product ideas and develop them cost-effectively when inspiration strikes, the public mood is understood, or customer feedback drops in. Materials Drive the Future of Digital As the additive manufacturing ecosystem grows, the importance of materials cannot be overstated. Besides high equipment costs, materials and limited additive manufacturing ecosystems have hindered the 3D printing industry's growth. The market is flooded with 3D printing materials, but few are advanced enough to fulfill industry standards.Due to volume constraints in most sectors, suppliers and manufacturers aren't motivated to develop innovative materials for new uses. However, the future of 3D printing is in engineered and application-specific materials. Various sectors have unique difficulties that demand unique solutions. New designed materials will revolutionize new uses, including highly regulated sectors. Industries will reward those who can promptly introduce 3D printing materials adapted to specific industrial and engineering needs. This will allow more 3D printing applications to be supplied and the whole digital manufacturing flywheel to start spinning. 3D Printing and a Sustainable Future Finally, additive manufacturing promotes sustainability and conservation. Besides decreasing trash, 3D printing saves energy. The Metal Powder Industries Federation studied the difference between making truck gear using subtractive manufacturing (17 steps) and additive manufacturing (6 steps). 3D printing uses less than half the energy it takes to produce the same product. 3D printing also reduces the need for moving products and materials, reducing the amount of carbon emitted into the environment. So we can see that digital and additive solutions already contribute to a more sustainable future. Is Investment in the Future of Additive Manufacturing Worth It? In recent years, there has been an explosion of investment in industrial 3D printing. Hundreds of millions of dollars have flowed into the industry in recent years, assisting new businesses. Desktop Metal ($160 million), Markforged ($82 million), and 3D Hubs ($18 million) have all received significant funding in the past. According to a recent report and data analysis, the global additive manufacturing market will hit USD 26.68 billion by 2027. A rising level of government support for additive manufacturing across regions is driving market demand. For example, America Makes, the foremost national initiative in the US since 2012 dedicated to additive manufacturing (3D printing future technology), received USD 90 million in support from the government, commercial, and non-profit sectors. Given the industry's expenditures and the expanding need for 3D printing, investing in the additive manufacturing industry or 3D printing is certainly encouraged. Final Words Additive manufacturing is being used in practically every industry, and companies are researching how technology might be used in their specific fields. The numerous advantages and sustainability that 3D printing provides are the major benefits that manufacturers and other industry professionals notice with 3D printing.Future manufacturing will be significantly more accurate and simple to run thanks to 3D printing technologies. Considering the trends and projections listed above, you may have a better understanding of 3D printing's future and make an informed investment decision. FAQ What is the future of 3D printing? 3D printing, or additive manufacturing, has the potential to empower everything from food to coral reefs. 3D printers may soon be seen in homes, companies, disaster zones, and perhaps even outer space. Why is 3D printing important to society? 3D printing results in waste reduction and so eliminates the need for periodic waste reduction, reuse, and recycling. So it helps society with no carbon footprint. Why is it known as additive manufacturing? The term "additive manufacturing" refers to the fact that the building process adds layers rather than removes raw materials.

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Spotlight

MC Electronics

Founded in 1982, MC Electronics, LLC is a leader in Electronics Manufacturing Services and Solutions. Servicing our customers worldwide from our Northern California and Juarez Mexico manufacturing and warehousing facilities, MC Electronics provides full integration of electronic products ranging from wiring harnesses/cable assemblies to turnkey system assembly/sub-assembly.

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