Article | July 27, 2021
Filmmaking is manufacturing. To date, no one has made the direct correlation between the two. As many entertainment professionals know, the budget gap between indie productions and big studio blockbusters continues to grow. The day of mid-budget, independent (indie) movies is disappearing as fast as the middle class in the American economy. According to newbiefilmschool, the average budget is barely at $2 million for these pictures and producers have been forced to adapt by discovering creative ways to decrease costs, while maintaining a high production values for a sophisticated audience with high expectations.
Though there are many ways to cut costs, any business professional will agree to go with the options that bring down the budget the most. Just as dog is man’s best friend, here are three reasons why manufacturers have become the same for a filmmaker by saving money and time for every type of production.
Film equipment manufacturers
No long may a film lack quality in picture, sound, and bad acting. Once acceptable, these older movies were produced with the technology and film equipment constraints and from limited funding. Film equipment manufacturers from cameras, sound equipment, and computers cost less to achieve high production values. Film equipment companies face increasing competition, which has driven down the purchase price. Better equipment with significant technology improvements has reframed the indie film industry with high-level sound and image capture quality.
The transition of cameras from film to digital was a notable shift for manufacturers. Many industry-insiders believe that digital is free, and film is expensive, but there is more the manufacturing construct. Digital cameras, when compared to film cameras in the same market price bracket, are much more expensive than analog counterparts. It is true that film costs money and is single-use. Digital memory cards are relatively expensive and can be reused. Film also needs to be developed and there is a cost associated with that production cost. There are other ways in which digital modalities save filmmakers.
Across all industries, efficiency always wins. Innovative manufacturers have developed machines to make numerous jobs easier for everyone. Machines have been assisting filmmakers since the invention of the camera. AI (artificial intelligence) is poised to change film even more and continues to augment human creativity. Storytellers work with computers during every process of creating a motion picture which has sped up the time it takes to complete each-step in film making.
Automating pre-production processes, such as creating a budget and writing a script, is analogous to an ERP (enterprise resource planning) software for a traditional manufacturing operation. The Movie Magic budgeting software by Entertainment Partners has made creating a budget more efficient and accurate. Screenwriter programs vary from the downloadable Final Draft, and the purely cloud based, Celtx, are the reasons automated scriptwriting is the norm. These programs also automatically format writing to industry standards, facilitating the creative process.
Automation in post-production is equally advanced through editing software for video, sound, effects, and colors all the way to distribution and promotional content. Editing footage from digital rather than film saves time and money. Industry favorites include Adobe Premiere Pro and Apple’s exclusive Final Cut Pro and are used on almost all well-known movies and TV shows.
The impacts of COVID-19 on entertainment manufacturers
Without question, the pandemic has affected every industry by creating an unanticipated production standstill. Entertainment manufacturers have sacrificed countless productions, lost billions of dollars, and major talent agencies have furloughed hundreds of employees. This negative impact is not just difficult for indie filmmakers, big studios are suffering just as much with production delays and cancellations still happening as this article goes to press.
Any way back to the set is better than no set at all. A new necessity for productions to safely reopen includes epidemiologists and other public health specialists; they provide detailed strategies dealing with large crews who work in cramped spaces, makeup artists who get face-to-face with actors who kiss, hug, and fight on set. These COVID-19 consultants rely on the manufacturing industry for PPE supplies and carry out regular PCR tests. Face coverings and hand sanitizing stations have also become the norm, just like most other manufacturing operations.
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.
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 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.
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 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.
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.
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
Step4 - Post-processing
"name": "What are the benefits of additive manufacturing?",
"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."
"name": "What is the major challenge in additive manufacturing?",
"text": "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."
"name": "What are the steps of additive manufacturing?",
"text": "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"
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 | March 30, 2021
The past 12 months have been especially challenging for the manufacturing industry. The pandemic affected in-person manufacturing jobs as well as supply and demand, causing many manufacturing companies to shut their doors or lay off valuable employees. Recognizing the vulnerable state of manufacturing companies, cybercriminals saw manufacturing as an easy target. In fact, the manufacturing industry saw an 11 percent increase in cyberattacks in 2020.
And even more concerning, our recent State of Software Security v11 (SOSS) report found that, when compared to other industries, the manufacturing industry ranks last for fix-rate and median time to remediate security flaws. That means that the manufacturing industry has security flaws in applications that aren???t getting resolved in a timely manner. And more lingering flaws mean more opportunity for a cyberattack.