Article | October 13, 2021
The electronics manufacturing business is adopting new technologies to create smart electronics manufacturing products for its consumer base. Next-generation technologies are shaping the future of the manufacturing industry by enabling it to create technologically advanced and user-friendly products. Matt Mong, one of the manufacturing industry's leading professionals, stated in an interview with Media7,
“Be Different. Don’t position your product in an existing category. Instead, create your category and make the competition irrelevant and obsolete.” – Matt Mong, VP Market Innovation and Project Business Evangelist at Adeaca.
The year 2022 will be a year of advancement and development for the electronics manufacturing industry.
So, manufacturers are eager to embrace new technologies and produce more innovative, more user-friendly goods that become part of consumers' daily lives and meet their needs. To make the manufacturing process manageable and deliver advanced products, we will look at the top five trends flourishing in the electronics manufacturing industry.
Top Five Electronics Manufacturing Industry Trends
Future manufacturing technologies are transforming the electronics manufacturing industry's processes and products. Let's look at the top electronics manufacturing industry trends for 2022, which will propel the sector to new heights of technological advancement.
Utilizing the Benefits of the Internet of Things
The Internet of Things is being used in both the manufacturing process and the products themselves. It enables electronic manufacturing products and processes to become more intelligent and performance-driven to fulfill business and customer needs.
In electronics manufacturing, the Internet of Things (IoT) enables businesses to solve common production challenges such as product quality issues, changing demands, and a complex global supply chain. As a result, it increases productivity and efficiency while reducing human effort.
Industrial units may gather and analyze real-time data and processes using IoT-based sensor systems. Additionally, it assists organizations in managing data and transforms traditional manufacturing into an intelligent manufacturing unit.
Using an ERP System to Maintain the Company's Competitive Edge
ERP (Enterprise Resource Planning) is a centralized management system for all operational and business activities. The software automates all manufacturing processes and enables the electronics manufacturing sector to achieve higher precision throughout the manufacturing process and product delivery.
ERP has the potential to boost productivity, improve efficiency, decrease expenses, and increase profitability. ERP enables electronics manufacturers to forecast, plan, modify, and respond to changing market demands. By using an ERP system in your manufacturing unit, you may expand your business and increase revenue.
Making Use of Big Data
The electronics manufacturing industry benefits from the use of big data to make critical business decisions. It aids in the integration of previously isolated systems to provide a comprehensive view of industrial processes. It also automates data gathering and processing, allowing for more excellent knowledge of each system individually and collectively.
Big data also assists manufacturers in discovering new information and identifying trends, allowing them to optimize operations, improve supply chain efficiency, and find variables that impact manufacturing quality, volume, or consistency. In addition, big data assists the electronics manufacturing industry in keeping up with the rapidly changing digital world.
Using AR and VR to Create Consumer-friendly Goods
AR and VR are future manufacturing technologies that are changing electronics manufacturing products and driving growth. Robotics is a crucial usage of virtual reality in electronics production. Manufacturers may use powerful virtual reality software to design goods. This implementation of virtual reality software reduces production errors and saves time and money.
AR in electronics manufacturing allows product developers to generate interactive 3D views of new products before production. AR and VR are part of Industry 4.0, the digital revolution of conventional electronics production units.
Adoption of 3D Printing on a Wide Scale
One of the essential advantages of today's electronics 3D printing is that companies can quickly prototype PCBs and other electrical devices in-house. In addition, 3D printing has simplified the electronics manufacturing process, and it is currently being utilized to manufacture multilayer printed circuit boards. It uses material jetting technology to spray conductive and insulating inks onto the printing surface.
Let's look at an example of an analogy that worked for Jinzhenyuan - The Electronic Technology Co. Ltd., managed by Mr. Huang Runyuan, Jinzhenyuan's General Manager, and based on the concept of Industry 4.0. (Reference: Forbes)
Jinzhenyuan - The Electronic Technology Co. Ltd. Takes a Significant Step Forward with Industry 4.0
Jinzhenyuan - The Electronic Technology Co. Ltd., formed in 2012, sells its products globally. In addition, it manufactures cellphones, computers, cars, and a variety of other consumer electronics. Due to changing market needs, the firm planned to upgrade its production facility to industry 4.0 by the end of 2017 to participate in smart manufacturing.
The company increased production efficiency, shortened production cycles, and cut costs due to the digital revolution. Today, Jinzhenyuan is regarded as a model of digital transformation in the community in which it works. Let’s observe the statistics for Jinzhenyuan following the deployment of Industry 4.0.
32% improvement in total production efficiency
33% cost reduction
41% decrease in R&D to production cycles
51% reduction in substandard parts rate – from 3,000 to 1,500 per million
The electronics manufacturing sector is on the verge of a digital revolution that will improve the production process efficiency and cost-effectiveness. Many of the world's biggest firms, like Apple, Microsoft, Hitachi, and Saline lectronics, are developing future agile factories to keep up with the world's digital transformation. Future manufacturing technology will help your manufacturing company make the manufacturing process more efficient and boost the business revenue.
What are the future electronics technologies?
Smart grid solutions, wearable technology devices, prefabricated goods, the Internet of Things, and robots are some of the future electronics innovations that will propel the business forward.
Is the supply chain benefiting from new technology trends?
Yes, supply chain management benefits from smart technology as well. Trucks equipped with cutting-edge technologies can get real-time data on the weather and road conditions ahead of time. It contributes to the supply chain process's reduction of possible risks.
Which manufacturers are implementing the industry 4.0 concept in their factories?
Whirlpool, Siemens, Hirotec, Tesla, Bosch, and Ocado, among others, have turned their traditional factories into digitally smart ones that incorporate all of the cutting-edge technology necessary to improve and optimize the production process.
"name": "What are the future electronics technologies?",
"text": "Smart grid solutions, wearable technology devices, prefabricated goods, the Internet of Things, and robots are some of the future electronics innovations that will propel the business forward."
"name": "Is the supply chain benefiting from new technology trends?",
"text": "Yes, supply chain management benefits from smart technology as well. Trucks equipped with cutting-edge technologies can get real-time data on the weather and road conditions ahead of time. It contributes to the supply chain process's reduction of possible risks."
"name": "Which manufacturers are implementing the industry 4.0 concept in their factories?",
"text": "Whirlpool, Siemens, Hirotec, Tesla, Bosch, and Ocado, among others, have turned their traditional factories into digitally smart ones that incorporate all of the cutting-edge technology necessary to improve and optimize the production process."
Article | October 20, 2021
Additive manufacturing has advanced significantly in recent years and is currently used in nearly every area to improve both products and processes in the manufacturing business. As a result, manufacturers have been more imaginative and innovative in offering relevant products to their target customer group due to this technological advancement.
Mr. Matt Mong, a prominent business executive, also mentioned in one of his Media7 interviews,
As technology takes over and enhances many of the processes we used to handle with manual labor, we are freed up to use our minds creatively, which leads to bigger and better leaps in innovation and productivity.
Matt Mong, VP Market Innovation and Project Business Evangelist at Adeaca
The use of additive technology provides several advantages, including creating unique shapes and low production costs. In addition, the increasing application of additive manufacturing technologies is accelerating the growth of the additive manufacturing market. According to recent research conducted by Metal AM, the value of additively produced components is expected to increase by 15% annually from $12 billion in 2020 to $51 billion in 2030. Thus, additive marketing is the way forward for all industries.
This article will cover the top five industries that utilize additive manufacturing and are advancing their businesses every day by overcoming the prevailing challenges such as production errors, downtime, and skilled labor shortage with the benefits of additive manufacturing.
Five Industries Utilizing Additive Manufacturing
Though additive manufacturing or 3D printing has penetrated almost all the industries, we have picked up a few of the prevailing industries that have started using additive manufacturing and excelling in it.
Additive Manufacturing in Aerospace
Aerospace has always been the first sector to adopt new technology. Precision is critical in this sector, as a failure of any component is not an option in aerospace. In aircraft production, dimension, weight, and temperature tolerance are critical, and additive technology provides every solution around this. As a result, additive manufacturing has evolved into a critical technology that adds value throughout the supply chain for prominent aircraft firms like Airbus, GE, Boeing, and TTM.
Additive Manufacturing in Healthcare
Healthcare or medical is one of the industries that is maximizing the benefits of additive manufacturing. Technology enables the medical sector to be more innovative, accurate, and capable of offering the most excellent medical solutions available today. It enables medical practitioners to rehearse before procedures and medical researchers to study functioning human tissues for basic biological research. In addition, it is utilized to fabricate tissues and organoids, surgical instruments, patient-specific surgical models, and bespoke prostheses. Thus, additive technology has altered the face of medicine, elevating it to a more sophisticated and solution-oriented state.
Additive Manufacturing in Architecture
As with other industries, additive manufacturing reshapes the architectural and construction sectors by eliminating conventional industrial barriers such as production time and cost, material waste, and design constraints. By utilizing 3D printing, designers can now quickly construct and demonstrate how structural parts will function and appear when combined. It also assists designers in seeing how the plan will seem subsequent execution.
Additive Manufacturing in Manufacturing
Nowadays, additive manufacturing, or 3D printing, is a significant part of the manufacturing process. For example, rather than fabricating a product from solid blocks, additive manufacturing may build a three-dimensional model utilizing fine powder, various metals, polymers, and composite materials as raw materials for constructing a 3D model with a three-dimensional printer.
Additive Manufacturing in Education
Additive manufacturing is reshaping the educational industry by introducing a new teaching trend and transforming the classroom experience for students. It is being used in various disciplines, including engineering, architecture, medicine, graphic design, geography, history, and even chemistry. They may produce prototypes, three-dimensional models, and historical objects, among other things. Thus, technology enables learners to get more practical information about their respective courses directly on the floor.
How has General Electric (GE) been pioneering the use of Additive Manufacturing for 20 years?
GE's primary competency is additive manufacturing (3D printing), and the company has made significant investments in the technology. It utilizes additive technology to manufacture a range of components for aviation and other sectors. This article will look at one of their manufacturing case studies and how additive technology enabled them to get the desired result from the end product.
CASE STUDY: OPTISYS
Optisys modified a vast, multi-part antenna assembly into a palm-sized, lighter, one-piece additive metal antenna. The antenna's aluminum material was chosen because of its surface conductivity, low weight, corrosion resistance, and stress and vibration resistance. Optisys was able to break even on machine acquisition within one year after acquiring its first Direct Metal Laser Melting (DMLM) equipment by utilizing additive technologies. (Source: General Electric)
Benefits and Outcomes
Non-recurring expenditures were reduced by 75%.
Weight loss of 95%
The size was reduced by 80%.
Part-to-part reduction of 100-to-1
Cycle duration shortened from 11 to 2 months
5 product lines were created for AM, a new market growth
Additive manufacturing benefits a wide variety of businesses. Industries must recognize the advantages of additive manufacturing and begin using the technology in their manufacturing processes to cut production time and costs while increasing product accuracy. This game-changing expansion of the additive manufacturing market across several industries is upgrading both products and production processes.
How do you define additive manufacturing?
Additive manufacturing (AM), more generally referred to as 3D printing, is a ground-breaking manufacturing technique that enables the creation of lighter, more robust components and systems. As the name implies, additive manufacturing is adding material to an item to create it.
Is additive manufacturing the same as 3D printing?
Both terms are interchangeable. Additive manufacturing and 3D printing manufacture components by connecting or adding material from a CAD file.
Which companies specialized in additive manufacturing?
American Additive Manufacturing, Forecast 3D, Sciaky, Inc., 3 Axis Development, Inc., Jonco Industries, Inc., Polyhistor International, Inc., and Caelynx, LLC are renowned companies for additive manufacturing in the United States of America.
"name": "How do you define additive manufacturing?",
"text": "Additive manufacturing (AM), more generally referred to as 3D printing, is a ground-breaking manufacturing technique that enables the creation of lighter, more robust components and systems. As the name implies, additive manufacturing is adding material to an item to create it."
"name": "Is additive manufacturing the same as 3D printing?",
"text": "Both terms are interchangeable. Additive manufacturing and 3D printing manufacture components by connecting or adding material from a CAD file."
"name": "Which companies specialized in additive manufacturing?",
"text": "American Additive Manufacturing, Forecast 3D, Sciaky, Inc., 3 Axis Development, Inc., Jonco Industries, Inc., Polyhistor International, Inc., and Caelynx, LLC are renowned companies for additive manufacturing in the United States of America."
Article | December 16, 2021
Computer-aided manufacturing (CAM) is a technology that revolutionized the manufacturing business. Pierre Bézier, a Renault engineer, produced the world's first real 3D CAD/CAM application, UNISURF CAD. His game-changing program redefined the product design process and profoundly altered the design and manufacturing industries.
So, what is CAM in its most basic definition?
Computer-aided manufacturing (CAM) is the application of computer systems to the planning, control, and administration of manufacturing operations. This is accomplished by using either direct or indirect links between the computer and the manufacturing processes. In a nutshell, CAM provides greater manufacturing efficiency, accuracy, and consistency.
As technology takes over and enhances many of the processes we used to handle with manual labor, we are freed up to use our minds creatively, which leads to bigger and better leaps in innovation and productivity.”
– Matt Mong, VP Market Innovation and Project Business Evangelist at Adeaca
In light of the numerous advantages and uses of computer-aided manufacturing, manufacturers have opted to use it extensively. The future of computer-aided manufacturing is brightening due to the rapid and rising adoption of CAM.
According to Allied Market Research, the global computer-aided manufacturing market was worth $2,689 million in 2020 and is expected to reach $5,477 million by 2028, rising at an 8.4% compound annual growth rate between 2021 and 2028.
Despite all this, each new development has benefits and challenges of its own. In this article, we'll discuss the benefits of CAM, the challenges that come with it, and how to deal with them. Let's start with the advantages of computer-aided manufacturing.
Benefits of Computer Aided Manufacturing (CAM)
There are significant benefits of using computer-aided manufacturing (CAM). CAM typically provides the following benefits:
Increased component production speed
Maximizes the utilization of a wide variety of manufacturing equipment
Allows for the rapid and waste-free creation of prototypes
Assists in optimizing NC programs for maximum productivity during machining
Creates performance reports automatically
As part of the manufacturing process, it integrates multiple systems and procedures.
The advancement of CAD and CAM software provides visual representation and integration of modeling and testing applications.
Greater precision and consistency, with similar components and products
Less downtime due to computer-controlled devices
High superiority in following intricate patterns like circuit board tracks
Three Challenges in CAM and Their Solutions
We have focused on the three primary challenges and their solutions that we have observed.
Receiving Incomplete CAD Updates
Receiving insufficient CAD updates is one of the challenges. If, for example, the part update from a CAD engineer does not include the pockets that are required in the assembly, to the CAM engineer.
SOLUTION: A modeler that enables developers of a CAM programs to create intuitive processes for features such as feature extraction and duplication across CAD version updates. A modeler is capable of recognizing and extracting the pocket's architecture and the parameters that define it. Additionally, the CAM application can enable the engineer to reproduce the pocket in a few simple steps by exploiting the modeler's editing features such as scaling, filling, extruding, symmetrical patterning, and removing.
Last Minute Design Updates
The second major challenge is last-minute design changes may impact manufacturers as a result of simulation.
SOLUTION: With 3D software components, you may create applications in which many simulation engineers can work together to make design modifications to the CAD at the same time, with the changes being automatically merged at the end.
Challenging Human-driven CAM Manufacturing
The third major challenge we have included is that CAM engineers must perform manual steps in human-driven CAM programming, which takes time and requires expert CAM software developers. Furthermore, when the structure of the target components grows more complicated, the associated costs and possibility of human failure rise.
SOLUTION: Self-driving CAM is the best solution for this challenge. Machine-driven CAM programming, also known as self-driving CAM, provides an opportunity to improve this approach with a more automated solution. Preparing for CAM is simple with the self-driving CAM approach, and it can be done by untrained operators regardless of part complexity. The technology handles all of the necessary decisions for CAM programming operations automatically. In conclusion, self-driving CAM allows for efficient fabrication of bespoke parts, which can provide substantial value and potential for job shops and machine tool builders.
Computer Aided Manufacturing Examples
CAM is widely utilized in various sectors and has emerged as a dominant technology in the manufacturing and design industries. Here are two examples of sectors where CAM is employed efficiently and drives solutions to many challenges in the specific business.
Virtual 3D prototype systems, such as Modaris 3D fit and Marvellous Designer, are already used by designers and manufacturers to visualize 2D blueprints into 3D virtual prototyping. Many other programs, such as Accumark V-stitcher and Optitex 3D runway, show the user a 3D simulation to show how a garment fits and how the cloth drapes to educate the customer better.
Aerospace and Astronomy
The James Webb Space Telescope's 18 hexagonal beryllium segments require the utmost level of precision, and CAM is providing it. Its primary mirror is 1.3 meters wide and 250 kilograms heavy, but machining and etching will reduce the weight by 92% to just 21 kilograms.
What is the best software for CAM?
Mastercam has been the most extensively utilized CAM software for 26 years in a row, according to CIMdata, an independent NC research business.
How CAD-CAM helps manufacturers?
Customers can send CAD files to manufacturers via CAD-CAM software. They can then build up the machining tool path and run simulations to calculate the machining cycle times.
What is the difference between CAD and CAM?
Computer-aided design (CAD) is the process of developing a design (drafting). CAM is the use of computers and software to guide machines to build something, usually a mass-produced part.
Article | December 16, 2021
Lean manufacturing is an operational approach used to create value. Businesses adopt lean manufacturing to improve productivity, reduce waste, increase customer value, and employee satisfaction.
Many businesses are accelerating their adoption of lean principles and practices due to the emergence of the industry 4.0 transformation. As a result, companies such as Caterpillar, Intel, Textron, Parker Hannifin, and John Deere are all reaping the benefits of lean manufacturing.
So, where did the idea of "lean manufacturing" first originate? In this article, you'll learn about the origins of lean manufacturing and its key principles.
The Origins of Lean Manufacturing
The principles of lean manufacturing were developed in Japan in the mid-20th century. Toyota, a famous Japanese automaker, experienced major delivery issues at the time. Its production chains were excessively long; thus it couldn't supply enough products on time. As a result, Toyota needed a new Performance measurement system. The company's managers identified a solution.
They created a new project management method called the Toyota production system. Its basic idea was to improve product distribution by reducing waste. It was a good concept. It helped the company shorten manufacturing chains and deliver products faster. Toyota's production method created a simple and effective waste definition. Any step that did not improve the end product's functionality was called a waste.
Later, other manufacturing industries adopted the system. It was renamed as lean manufacturing. It's now a global phenomenon and is used by large and small businesses worldwide.
When should you implement the Lean Manufacturing Method in your business?
Lean is a waste-reduction methodology, approach, and a lifestyle. While it is commonly used in manufacturing, lean techniques are applied to reduce waste while keeping high quality in any business.
Waste reduction of 80% plus
Reduced production expenses by 50%
Decreased inventories by 80-90%
Producing quality items is 90% less expensive.
Workforce productivity improved by 50%
If you want your business to get the above benefits, you need to adopt lean manufacturing principles.
Five lean Manufacturing Principles
Lean manufacturing benefits businesses in multiple ways, and this lean lifestyle has the potential to empower any organization and increase its market competitiveness. So, let us observe the five fundamental principles of lean manufacturing.
For the first principle of defining customer value, it is vital to understand what value is. For customers, value comes from what they're willing to pay for. The customer's actual or hidden demands must be discovered. Customers are not aware of what they want or cannot express it. When it comes to new items or technologies, this is a regular occurrence.
Assume nothing; ask about the pain points being experienced and then craft a unique value proposition. Never force a solution into a problem that does not exist.”
– Thomas R. Cutler, President & CEO at TR Cutler, Inc.
For example, you can use various methods to find out what customers value, such as surveys and demographic information. With these qualitative and quantitative methodologies, you may learn more about your clients' needs, their expectations, and their budgets.
Identifying and mapping the value stream is the second lean principle. By starting with the consumer’s perceived value, all activities that contribute to that value may be identified. Waste is anything that does not benefit the client in any way. It can be divided into two categories: non-value-added and unnecessary waste. The unnecessary waste should be removed, while the non-value-added should be minimized. You can ensure that clients get exactly what they want while minimizing the cost of creating that product or service by removing unnecessary processes or steps.
The next operations must proceed smoothly and without interruption or delays after removing wastes from the value stream. Value-adding activities can be improved by breaking down tasks, reorganizing the manufacturing process, distributing the workload, and educating personnel to be flexible and multi-skilled.
The fourth lean principle requires a pull-based manufacturing system. Traditional production systems use a push system, which starts with purchasing supplies and continues manufacturing even when no orders are placed. While push systems are simple to set up, they can result in vast inventories of work-in-progress (WIP).
On the other hand, a pull method pulls a customer's order from delivery, causing new items to be made and additional materials to be acquired. Kanban, one of the lean manufacturing tools, can help organizations develop a pull system to control material flow in a production system.
An efficient pull system maximizes available space, reduces inventory, eliminates over-and under-production, and eliminates errors caused by too much WIP.
While completing Steps 1-4 is a great start, the fifth and possibly most critical step is incorporating lean thinking and process improvement into your organizational culture. As benefits accumulate, it is vital to remember that lean is not a static system that requires continuous effort and awareness to perfect. Each employee should get included in the lean implementation process. Lean experts sometimes state that a process is not truly lean until it has undergone at least a half-dozen value-stream mapping cycles.
How Nike Demonstrated the Benefits of Lean Principles
Nike, the world-famous shoe and clothing powerhouse, has embraced lean manufacturing principles and practices. Nike experienced less waste and increased consumer value, as did other businesses. It also shared some unexpected benefits. It is proven that lean manufacturing can minimize terrible labor practices at a company's overseas manufacturing unit by up to 15%. This result was mostly due to implementing the lean manufacturing practice of valuing the workers more than earlier routine labor practices. It provided greater significance to an employee and, as a result, greater significance to the organization as a whole.
Implementing lean manufacturing principles is a good way to run any organization. Businesses that build their operations on the two pillars of lean manufacturing, constant improvement, and personnel respect, are well on their way to becoming a successful and productive organizations in the modern era. To become a lean company, an organization must fully grasp the benefits and added value that it may get by adopting lean manufacturing principles.
What is Five S's of lean manufacturing?
The 5S of lean manufacturing are Sort, Set in Order, Shine, Standardize, and Sustain, and they give a framework for organizing, cleaning, developing, and maintaining a productive work environment.
What are the two pillars of lean manufacturing?
Lean, as modeled on the Toyota Way values, has two pillars, first is ‘Continuous Improvement’ and second is ‘Respect for People’.
Why are lean principles beneficial for any business?
Lean manufacturing is a business strategy that has proven to be highly successful since it can help you decrease costs, remove waste, enhance production, maintain excellent quality, and thus increase business profit significantly.