Article | December 8, 2021
The manufacturing production schedule is a critical aspect that enables the manufacturing business to complete each production activity precisely and on time. Allocating different raw materials, resources, or processes to distinct project phases is called a production schedule. Its goal is to make your manufacturing process as efficient and cost-effective as possible in terms of resources and labor — all while delivering products on schedule.
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
So, how is the overall production schedule managed?
According to businesswire, the global APS (Advanced Production Planning and Scheduling) software market was valued at $1,491.22 million in 2020 and is anticipated to raise $2,941.27 million by 2028 expanding at an 8.86 percent CAGR from 2020 to 2028.
Some software and tools are available to assist manufacturing organizations in properly scheduling production planning, including MaxScheduler, TACTIC, MRPeasy, and Gantt charts. Though there are numerous software programs available on the market for production scheduling, the most crucial aspect is determining which elements to consider when planning production.
This blog will look at the five most important factors to consider while planning the production schedule.
Five Elements to Consider When Scheduling Production
As we saw in the introduction, production scheduling is used in the manufacturing process to assign plant and machinery resources, schedule human resources, plan production processes, and purchase materials.
So, what are the primary components or stages of this production scheduling process? Let's take a quick look at each of them.
Planning to Make the Best Use of the Company's Resources
The role of planning in production scheduling is to use the company's resources to maintain a regular production flow. As a result, downtime is decreased, and bottlenecks are minimized, allowing production to be optimized. For production scheduling, two forms of planning can be used:
Dynamic Planning: Dynamic planning is carried out under the idea that process stages will alter. So, materials must be ready, but production cannot begin until demand is decided.
Static Planning: Static planning is done keeping in mind that all process steps will be completed on schedule and without adjustments.
Routing to Determine the Order of Actions
A “bill of materials” is used in discrete manufacturing to specify what things are needed and in what quantities.
Routing determines the path and sequence of required phases of the process. It may involve in-house operations, but it may also comprise sub-contracted components that must be returned to the production flow for final assembly.
Scheduling to Make Use of Predetermined Planning Levels
To manufacture products from components or raw materials, scheduling makes use of the previously set planning level. As a result, it is time-dependent and must meet the demand outlined at the planning level.
Each department, product, and procedure can have their own unique set of timetables. Sub-schedules for sub-assemblies or mixes and blends may be defined by department-specific master production schedules, utilized at the highest level to define product timeframes.
Dispatching to Decide on Immediate Actions
Dispatching assigns the following jobs to be done from a subset of the production queue. Dispatching is utilized to make quick decisions. This is in contrast to planning, which involves the planning of future actions. Dispatching is utilized in both pull and push production systems.
Execution to Ensure that all Processes are Carried out Correctly
Production scheduling must rely on proper execution to ensure that all processes are completed appropriately and in the sequence planned.
It requires everyone to know what they are expected to do and when they are expected to do it. Execution requires knowledgeable management decisions, well-trained employees, correct data in the manufacturing plan and schedule, and consistent sales statistics and forecast numbers. All must be present for the organization to carry out its production plan and fulfill orders.
How MRPeasy – A Production Scheduling Software Assist Manufacturing Companies in Scheduling Their Production?
MRPeasy is a cloud-based material requirements planning (MRP) application explicitly designed for small manufacturing units. Its primary functions are purchase order management, forecasting, and inventory management.
This software simplifies the process of scheduling production. It enables you to evaluate all of your anticipated manufacturing orders (MO). The bill of materials (BOM), purchasing, and stocking are all maintained in one location, allowing you to quickly book inventory and increase purchase orders (PO) for acquired parts.
MRPeasy enables you to:
Obtain all of the detailed information on all of your MOs
Consider MOs as a single block or as distinct operations.
Drag-and-drop operations and operations to reschedule
Calendar or Gantt chart views are available for monitoring scheduled orders.
Additionally, you can manage MOs smoothly. With the production planning component, you may create, amend, and update MOs. This app compiles an exhaustive list of all your MOs. You can track their progress based on the status of an order or a part's availability. Additionally, you can search for, filter, and export your MOs.
How to schedule production for your organization requires extensive research, planning, and analysis of overall product demand as well as a grasp of the time required to meet the demand. Production scheduling techniques such as job-based planning, batch method, flow method, and others help develop a productive manufacturing production schedule. Include the elements mentioned above in your manufacturing scheduling to get the best possible benefits, such as better production efficiency, lower production costs, and on-time product delivery for your manufacturing in 2022.
How production planning differ from production scheduler?
Production planning and scheduling are often mixed. But there is a difference. Planning decides what and how much work must be done, whereas scheduling specifies who and when the work will be done.
What is real-time manufacturing scheduling?
Real-Time Scheduling is a production planning, scheduling, and tracking tool that enables manufacturing organizations to improve customer satisfaction and achieve optimal operational performance cost-effectively.
How can scheduling be improved?
Communication with staff is a great way to improve scheduling. This is true for all businesses, software or otherwise. However, management should not burden employees with ambiguous or unclear communication, and vice versa.
"name": "How production planning differ from production scheduler?",
"text": "Production planning and scheduling are often mixed. But there is a difference. Planning decides what and how much work must be done, whereas scheduling specifies who and when the work will be done."
"name": "What is real-time manufacturing scheduling?",
"text": "Real-Time Scheduling is a production planning, scheduling, and tracking tool that enables manufacturing organizations to improve customer satisfaction and achieve optimal operational performance cost-effectively."
"name": "How can scheduling be improved?",
"text": "Communication with staff is a great way to improve scheduling. This is true for all businesses, software or otherwise. However, management should not burden employees with ambiguous or unclear communication, and vice versa."
Article | December 6, 2021
Aerospace manufacturing and design are getting advanced with additive manufacturing. However, the limitations of traditional manufacturing techniques sometimes make it incompetent to produce technologically oriented products. Additive Manufacturing (AM)helps the aircraft system run more efficiently by creating lightweight aircraft parts.
This is one of the reasons that additive manufacturing is gaining traction in aerospace and other industries. According to recent analysis and data, the global additive manufacturing market is expected to grow from USD 9.52 billion in 2020 to USD 27.91 billion in 2028. The expanding technologies and materials used in additive manufacturing will indeed stimulate industry growth shortly.
It’s important to note that there isn’t one channel that is the silver bullet. Most of the time, a combination of different channels will help drive a more powerful outcome.”
– Wendy Lee, Director of Marketing at Blue Prism
However, the aerospace industry encounters some challenges with additive manufacturing, which is the focus of this article. Scalability, multi-material capabilities, professional workers, high-cost materials, and quality compliance norms are all constraints that aerospace professionals are dealing with. Here we will discuss the top three challenges of additive manufacturing in aerospace and their solutions.
Future of Additive Manufacturing in the Aerospace Industry
Even though additive manufacturing has been around for a while, it has only lately become advanced enough to be used in the aerospace sector.
In the aerospace business, additive manufacturing has the potential to deliver significant benefits. Cost savings, design freedom, weight reduction, shorter time to market, fewer waste materials, better efficiency, and on-demand production are just some of the benefits.
Although additive manufacturing cannot make every part, it provides an exciting opportunity to explore feasible alternatives, either supplementing or replacing traditional manufacturing processes. However, it must be taken into account early in the development phase. Additionally, knowledge must be embedded in aircraft design teams to ensure the successful use of additive manufacturing.
However, in recent years, AM has become more prevalent in end-to-end manufacturing. According to Deloitte University Press, the future of AM in aerospace may include:
Directly embedding additively produced electronics
3D printing engine parts
Making battlefield repair components
Top 3 Additive Manufacturing Challenges in the Aerospace Industry and Solutions
While problems are inherent in any new technology, experts overcome them by identifying solutions. Let's look at the top three challenges that the aerospace industry is currently facing and the solutions to overcome them.
Lack of Qualified Experts
Using 3D printers in production and automating work processes are skills that are lacking. However, the obstacles are natural, and the skilled manufacturing workforce is aging and reluctant to adapt to new design models. This is creating the skills gaps surrounding manipulating AM technology.
How to Overcome
Less time spent educating employees is better for business. For example, the US National Additive Manufacturing Institute and the European ADMIRE initiative offer accelerated courses via remote learning websites.
Of course, you'll need to provide numerous additive manufacturing opportunities to attract the key technologists, either on-site or off-site. They will oversee new hires' activities and help them translate their knowledge of 3D printing into designs and final items.
Over Budget Material
The typical cost of AM equipment is $300,000. Industrial consumables cost between $100 and $150 per item (although the final price is formed after choosing the material; plastic, for example, is the most budget-friendly option).
How to Overcome
To overcome this obstacle, you must plan a long-term implementation strategy based on the manufacturing-as-a-service model. On-demand manufacturing reduces manufacturing costs and speeds up product development. You can also go with cheap 3D printers that use cheap welding wire that hasjust come onto the market. They cost $1,200 and may suit your needs.
Fresh Quality Compliance Guidelines
As 3D printing and CNC manufacturing technologies constantly evolve, there are no established norms or regulations for 3D printed objects. However, 3D printed solutions do not always match traditional quality, durability, and strength. For example, a 3D-printed mechanical part. Can someone order 500 similar parts a few months later? Consistency standards and product post-processing may have a negative impact in such circumstances. So, in such a case, traditional manufacturing wins over 3D printing.
How to Overcome
You might endeavor to set quality criteria for your 3D-printed products to ensure they are comparable to traditional ones. You can also apply the ANSI AMSC and America Makes standards, which define quality criteria for 3D printed products.
How Boeing Applies Additive Manufacturing Technology?
Boeing is focusing its efforts on leveraging and speeding up additive manufacturing to transform its manufacturing system and support its growth. The company operates 20 additive manufacturing facilities worldwide and collaborates with vendors to supply 3D-printed components for its commercial, space, and defense platforms.
Boeing is now designing missiles, helicopters, and airplanes using 3D printing technology. A small internal team contributes roughly 1,000 3D-printed components to the company's flight projects. Boeing claims that addressing design as an "integrated mechanical system" considerably improves manufacturability and lowers costs.
Additive manufacturing is altering the way the aerospace industry designs and manufactures aircraft parts. Aerospace advanced manufacturing is making aircraft production easier. We've explored solutions to some of the snags that you may encounter. However, other concerns, such as limited multi-material capabilities and size constraints, require solutions, and industry specialists are working on them. Despite these challenges, additive manufacturing is still booming and rocking in a variety of industries.
Why is additive manufacturing used in Aerospace?
It allows the industry to build quality parts quickly and inexpensively. Reduce waste and build parts for aircraft that are difficult to manufacture using existing methods.
How does additive manufacturing help in Aerospace applications?
Environmental control system (ECS) ducting, custom cosmetic aircraft interior components, rocket engine components, combustor liners, composite tooling, oil and fuel tanks, and UAV components are examples of typical applications. 3D printing helps in producing solid, complicated pieces with ease.
Which aerospace firms use additive manufacturing/3D printing?
Boeing and Airbus are two of the many aircraft businesses that use additive-created parts in their planes. Boeing incorporates additive manufacturing (AM) components into both commercial and military aircraft. Airbus also employs AM metal braces and bleed pipes on the A320neo and A350 XWB aircraft.
"name": "Why is additive manufacturing used in Aerospace?",
"text": "It allows the industry to build quality parts quickly and inexpensively. Reduce waste and build parts for aircraft that are difficult to manufacture using existing methods."
"name": "How does additive manufacturing help in Aerospace applications?",
"text": "Environmental control system (ECS) ducting, custom cosmetic aircraft interior components, rocket engine components, combustor liners, composite tooling, oil and fuel tanks, and UAV components are examples of typical applications. 3D printing helps in producing solid, complicated pieces with ease."
"name": "Which aerospace firms use additive manufacturing/3D printing?",
"text": "Boeing and Airbus are two of the many aircraft businesses that use additive-created parts in their planes. Boeing incorporates additive manufacturing (AM) components into both commercial and military aircraft. Airbus also employs AM metal braces and bleed pipes on the A320neo and A350 XWB aircraft."
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 8, 2021
The new manufacturing industry outlook for 2022 is what businesses desire. Due to COVID-19, the sector has seen several ups and downs in recent years. But the industry overcame the most difficult situation by adopting innovations as their working hands.
But all this upgrading and digitalization in manufacturing isn't for everyone. Some manufacturers may struggle with this change, while others may not. So, taking into account all industry segments, we have compiled a list of potential manufacturing challenges for 2022.
“Many companies simply are not willing to change or think they are done once they make a change. But the truth is that technology, consumer demands; the way we work, human needs and much more are constantly changing.”
– Michael Walton, Director, Industry Executive (Manufacturing) at Microsoft
The summary of manufacturing industry challenges and industry outlook for 2022 are presented in the stats below.
According to the National Association of Manufacturers (NAM), four million manufacturing jobs will likely be needed over the next decade, and 2.1 million will likely go unfulfilled unless we motivate more people to pursue modern manufacturing occupations.
According to PTC, 70% of companies have or are working on a digital transformation plan.
According to Adobe, 60% of marketers feel technology has increased competitiveness.
The statistics show that while digitalization facilitates the process, it also poses several challenges that must be addressed in the coming years. Let's explore what obstacles manufacturers may face in 2022.
The Manufacturing Industry Challenges in 2022
The manufacturing business has had a difficult few years as a result of the current economic downturn, and 2022 may not be even that smooth. Thought, technology, and current trends make the operations of upscale manufacturers easier, but not everyone is on the same page.
Let's look at some of the manufacturing challenges that businesses will face in the next year.
Skilled Labor Shortage
The manufacturing industry is facing a workforce shortfall as a skilled generation prepares to retire. Industry experts say that by 2025, there will be between 2 and 3.5 million unfilled manufacturing jobs. As a result of the advancement of new technologies, manufacturing organisations are finding themselves with fewer personnel. They do, however, require individuals with a diverse range of abilities, such as mathematicians and analytic thinkers, to accomplish the tasks with precision.
Specific manufacturing tasks have been automated to save time and money. Industry has adopted machine sensors to capture large amounts of data. With this kind of innovation, the industry's job structure is changing and the desire to hire an untrained or trainable workforce is slowly fading in the industry. However, using augmented reality and virtual reality, manufacturers can easily train personnel for the job and save money.
Lack of Ability to Mine Data
Manufacturing is progressively using IoT. The majority of businesses have already installed or are planning to install Internet of Things machines. These smart machines let businesses collect data to improve production and conduct predictive maintenance. But getting data is a simple task. The difficult aspect is analyzing and aggregating data.
Despite possessing the machines, most companies lack the systems to analyze and retrieve the data recorded by the systems. In this way, the industries are missing a vital opportunity. The industry must improve data mining capabilities to make better decisions in real-time.
Using IoT for analytics and predictive maintenance is critical. Monitoring technologies can help the sector examine data quickly. It can also help predict an asset's maintenance period. As a result, the industry will move from replacement to predict and fix.
Self-service Web Portals That Is Extremely Detailed and Precise
Manufacturing businesses usually strive for on-time order delivery and optimum revenue. However, consumer self-service, which has been in the industry for a long time, has never proven to be a simple walk for clients. Clients are frequently required to pick up the phone and contact manufacturers in order to track their orders and receive delivery estimates. This is hardly the service one would expect from a manufacturer, even more so in today's digital era.
The term customers in manufacturing include partners, end-users, and subcontractors. These three clients have distinct requirements and concerns about collaborating with the manufacturer. Companies can better serve their customers if their partner and end-customer portals are linked to a central hub which we can mention as self-service web portals.
All of the information and updates they need about their orders will be available to them through this new system. They can track, accept and amend their tasks. They'll also use the self–service portal to contact the manufacturer.
In this way, manufacturers can better serve their customers. A system like this will ensure that all parties have access to timely information in a digital format.
Meeting the Deadline for the Project
Product launch timelines are extremely demanding, tight, and stringent. Every project in the assembly line is about cost, time, and quality. Ultimately, these projects are rigorous and well-controlled. Manufacturers who fail to meet deadlines risk losing millions in potential revenues and sales.
Due to rigidity and stringent control, companies are less able to change project scopes or make adjustments as projects develop. The majority of initiatives begin with a design commitment. As new facts or change criteria emerge, adjustment flexibility decreases. This can be aggravating for a team that expects high-quality results. Deadlines are always a constraint.
Effective Business Digital Marketing Strategy
An industry's key digital transformation challenges are driving leads, sales, and MRR through digital channels. Many manufacturing organizations struggle to efficiently use marketing channels like paid media, enterprise SEO, local SEO, content strategy, and social media. In our opinion, one of the most significant issues these organizations have is their digital experience, website design, and overall brand presentation. They can't ignore them if they want to keep enjoying the manufacturing revival.
Visibility of the Supply Chain
Manufacturers must respond to the growing demand from customers for greater transparency. In order to meet customer demand across the customer experience and product lifecycle, they must first understand that precise and real-time visibility throughout the supply chain is essential.
All details must be taken into consideration by the manufacturers. They must be aware of any delays in the arrival of products on the market. Keeping abreast of such developments would give them a leg up in terms of adjusting or rectifying the situation.
Manufacturing industry challenges have long been a part of the industry. However, industry leaders and professionals have always confronted and overcome any challenges that have come their way. The year 2022 will also be a year of achievements, setting new records, and growth for the manufacturing industry, since it will be a year in which it will develop solutions to all of the aforementioned challenges.
What is the future of manufacturing?
Manufacturers should start using AI, block chains, and robotics today. The combination of these new technologies will reshape manufacturing. A new workforce capable of augmenting these technologies is developing and will become the future of manufacturing.
How will automation affect manufacturing in 2022?
When applied properly, automation can greatly assist manufacturing. These benefits include shorter production times, faster and more efficient work than human labor, and lower production costs.
How is the manufacturing industry’s market likely to upsurge in the future?
According to BCC Research, the global manufacturing and process control market is expected to grow at a CAGR of 6.3 percent from $86.7 billion in 2020 to $117.7 billion in 2025.
"name": "What is the future of manufacturing?",
"text": "Manufacturers should start using AI, block chains, and robotics today. The combination of these new technologies will reshape manufacturing. A new workforce capable of augmenting these technologies is developing and will become the future of manufacturing."
"name": "How will automation affect manufacturing in 2022?",
"text": "When applied properly, automation can greatly assist manufacturing. These benefits include shorter production times, faster and more efficient work than human labor, and lower production costs."
"name": "How is the manufacturing industry’s market likely to upsurge in the future?",
"text": "According to BCC Research, the global manufacturing and process control market is expected to grow at a CAGR of 6.3 percent from $86.7 billion in 2020 to $117.7 billion in 2025."