PLM for the Mid-market Supply Chain

Today, an article I wrote have been posted on the Supply & Demand Chain Executive website, in the “In Depth” section.

Below is the link and full text.

http://sdcexec.com/web/online/In-Depth/PLM-for-the-Mid-market-Supply-Chain/4$11358

A better look at a behind-the-scenes catalyst

Posted: May 21st, 2009 03:58 PM EDT

By Miki Lumnitz

In today’s global economic climate, companies around the world — from large OEMs (original equipment manufacturers) to mid-market manufacturers — face enormous challenges. It is easy to write off the problems of mid-market companies as comparatively insignificant. After all, they’re smaller; doesn’t that mean their problems are smaller too?

In reality, today’s mid-market companies’ face the same challenges as large OEMs, and they face them with fewer resources, less money and less ability to absorb risk. In addition, they have to deal with the increased competition in the mid-market, the increasing demand for a shorter product lifecycle, the pressure to develop more complex products than in the past, the management of multiple parallel projects and being part of the supply chain.

The Evolving Role of the OEM

The position of mid-market companies within the supply chain has undergone dramatic changes. OEMs, which may or may not be mid-market companies themselves, require increasingly more value, efficiency and sheer output from mid-market suppliers, and tend to deal with only the highest-level core and competitive competencies internally. For instance, in some industries, approximately 65 percent of final product development is outsourced to mid-market suppliers. Given such increased demands, suppliers need to differentiate themselves competitively by bringing specific knowledge and innovation to their products and to their relationships with the OEMs — it’s a matter of survival. If OEMs don’t see the results they need as quickly as required, they’ll gladly replace one supplier with another, or possibly shrink the supply chain altogether. Add to that the unpredictability of other suppliers’ actions (which affect the entire chain), and it’s clear that PLM isn’t a luxury — it’s a necessity.

The role of the OEM is changing. Ten years ago, the OEM controlled the entire supply chain and maintained all the specifics of product development in-house. Suppliers were part of an indelible hierarchy, with efficiency viewed as happenstance, not as an overarching value. As time went by and technology advanced, OEMs saw the benefit of collaborating with tier-one suppliers who were responsible for major product components. This trend hasn’t slowed — it has progressed from involving the traditional supply chain hierarchy to networks of suppliers.

The consequence of this change is that OEMs can no longer dictate the systems and methodologies used by their suppliers, as they are connected to multiple OEMs and to other companies. In the future we will undoubtedly see more and more networks of suppliers exchanging intellectual property with multiple OEMs across industries and with each other.

PLM Adoption in the Mid-market

For the large OEMs of the world the use of product lifecycle management (PLM) is practically a standard. However, in the mid-market — the segment that contains the vast majority of the world’s manufacturers — the use of PLM is not as prevalent.

In order to succeed and thrive, high-tech/industrial mid-market suppliers have to innovate and develop new products faster (with a target time-to-market projection of three to six months for the high-tech industry) and streamline operations and communications. They need to achieve global development excellence and increase efficiency by leveraging core competencies of the value chain and ensure on-time, on-cost and good-quality product delivery. They must also integrate regulatory compliance into product lifecycle processes to reduce business risk and sell products in global markets.

Adopting PLM isn’t a chore that companies must complete; it is a way to increase innovation and stay competitive. Product lifecycle management helps streamline business and development processes, especially with regard to collaborative engineering, standardization, mechatronics (multi-disciplinary product development integrating mechanical, electrical/electronic and software components that require unified bill-of-materials management — a "single version of the truth"), change management, components engineering and IP reuse. The resulting benefits are substantial:

• Increased product innovation: By adopting new product introduction NPI methodology within a single engineering platform, from concept to manufacturing.
• Global product development excellence: By leveraging streamlined global innovation networks and concurrent multi-disciplinary mechatronics product development.
• Improved profitability: By leveraging existing products/components and creating modular new products that facilitate re-use in multiple applications.
• Shortened time-to-market and improved ROI: By lowering development, manufacturing and purchasing costs while delivering improved product performance.
• Increased control on costs, quality and delivery dates: By integrating quality and change management processes and enabling real-time decision making for all levels.
• Ensured customer satisfaction: By being demand-driven and integrating customer requirements and specifications throughout the engineering process.

The PLM vision is wide and can touch almost every hidden corner of a company. This is why a phased approach is recommended, otherwise known as: "start small and grow as you go." It’s like eating a sandwich: You’re better off taking small bites in an orderly succession, rather than to try to eat the entire thing in one bite and risk choking. Product lifecycle management should undo process clogs, not create them.

Based on past experience, most mid-market companies start preparing themselves for PLM deployment by managing their design environment. They do this by creating a solid PLM foundation with computer-aided design (CAD) data and product data, and then they expand their implementation to cover the process from concept to manufacturing using an "item-centric" approach (including collaboration around the bill of materials (BOM) and process/change management), based on the same modular PLM platform. After making sure these elements are in place, PLM can be integrated with other enterprise processes through global collaboration and effective decision-making processes.

The greater the scale of the deployment, the greater the benefits are and, hopefully, the greater the adoption/acceptance by end-users. Starting the deployment from concept to manufacturing will attract the most end-users to the process (who will see the value of collaboration) and will spur user acceptance. Even if for each business process you initially choose to deploy the most simple and intuitive solution, and not necessarily the most advanced one available, you’ll succeed and grow as you go within the same PLM platform. Your initial focus should be on managing the process and getting people on board. Once you’ve completely taken care of that, then go ahead and gradually bring more advanced, complex solutions into the fold.

Real-world Example

As an example, let’s review Pentair Water, a company that opted to create a collaborative PLM global environment using ENOVIA SmarTeam’s solution. The major motivating factor for Pentair’s decision to deploy PLM was the need for the company to unite its many worldwide branches — especially in China and India — and to create synergies among its largely autonomous divisions. Up to that point Pentair had been distributing product data by express shipping CDs, e-mailing massive files or uploading information to non-secure FTP servers. All three of these methods posed an extreme risk to security, data consistency and speed. Pentair decided to implement PLM to reduce business risks and lower the overhead involved in meeting product quality standards.

Ultimately, Pentair executives used the PLM solution to address four needs: a common 3D design system, a single centralized data repository with a common model, a collaborative platform capable of supporting multiple locations, and a common approach to business process management.

The results the company has seen have been positive. Having a single source of data and a consistent data model with revision and version management allows multiple Pentair designers to simultaneously collaborate on a project, cutting design cycles in half while improving quality. Because PLM allows the company to avoid redundancy in its designs, Pentair has seen fewer mistakes overall and a decrease in the number of changes made at the tooling stage — when they’re the most expensive. Product lifecycle management has also cut down on wasted time searching through databases for information that may not exist and has improved collaboration between U.S. offices and manufacturing centers in China and India. PLM has become Pentair’s main solution for supply chain management, customer service, quality, production and purchasing.

PLM and Emerging Industries

The benefits from adopting PLM are tangible across all industries, but not all companies in all industries are currently mature enough in how they view PLM to effectively adopt it. When we look at the PLM market (especially in the mid-market), analyzing it within a technology wave, it’s rather difficult to determine whether it’s in a "growth" phase or "maturity" phase. A closer look at segmentation is necessary to make that call. Companies from some of the manufacturing sector’s "traditional" industries (automotive, aerospace & defense, industrial equipment, high-tech, energy & process, shipbuilding, consumer goods) tend to be ready to adopt PLM, while other manufacturing industries (consumer packaged goods, construction, medical devices) aren’t so easy to read.

The markets that many would define as being emerging industries (including apparel, pharmaceuticals and business services) are still in their respective "growth" phases. This means that most of those companies in the mid-market will be ready to adopt PLM only after several years. This puts the pressure on the aforementioned "traditional" manufacturing companies to adopt PLM as they already face competitors that have implemented PLM and thus have an advantage over them.

Companies within the emerging industries, on the other hand, should understand that if they can successfully adopt PLM before their competition, they can jump ahead in their market, bringing more innovative products to the forefront in shorter amounts of time, using quicker development strategies and making better use and reuse of their company’s intellectual property.

Obviously, deploying PLM will require a culture change within the company. The challenges involved in implementing PLM will be minimal, provided that the selected solution delivers industry best practices and modular out-of-the-box packages; offers the flexibility and openness required to fine-tune the out-of-the-box packages in accordance with existing company process; and most importantly, ensures a low total cost of ownership. After all, streamlining your mid-market company’s product lifecycle management should not break the bank.

As final note, the current economic situation in the global market is indeed a momentous challenge, but it is also a huge opportunity. By the time it ends, some companies will have disappeared, but others will be there, armed with dedication to innovation and a willingness to evolve. Product lifecycle management can help your company see future opportunities that transcend current challenges.

PLM at high-tech/industrial mid-market companies

When looking at high-tech/industrial mid-market companies, in order to succeed in this market Those companies have to innovate new products faster (time to market of 3-6 months in high-tech), streamline operations and collaboration. They need to achieve global development excellence and efficiency by leveraging core competencies of the value chain to ensure on-time, on-cost and quality product delivery. Integrate regulatory compliance into product lifecycle processes to reduce business risk and sell products in global markets.

In order to achieve that, adopting PLM will streamline their processes especially across the following areas:

• Requirements & Specifications
• Collaborative Engineering
• Standardization  & IP Reuse
• Mechatronics – Multi-disciplinary product development integrating mechanical, electrical/electronic and software components
• Business Processes & Change Management
• Standard components Engineering
• Linkage between product development and Project Management
• Real-time Collaboration & IP exchange internally and across the value chain and the eco-system

The main benefits those companies will see are:

• Increase product innovation – By adopting NPI methodology within a single engineering platform, from concept to manufacturing
• Encourage global product development excellence – By leveraging streamlined global Innovation Networks and concurrent multi-disciplinary mechatronics product development
• Improve profitability – By leveraging existing products/components and creating modular new products that facilitate re-use in multiple applications
• Shorten time to market and improve return on investment – By lowering development, manufacturing and purchasing costs while delivering improved product performance
• Increase control on costs, quality and delivery dates – By integrating quality and change management processes and enable real-time decision making for all levels
• Ensure 100 percent customer satisfaction – By operate demand-driven and Integrate customer requirements and specifications throughout the engineering process

Item-Centric product data management

Lately I see more and more usage of the term ‘Item-Centric’ PDM / PLM. Is every PDM application that can support BOM (Bill of Material) also can say it is ‘Item-Centric’ ?

What do you say, ‘Item-Centric’ = BOM ?

Is it that simple ?

Item-Centric product data management – What is it really?

I will try to specify few elements that are MUST for a real Item-Centric PDM / PLM. After that you can judge yourself which application really provides Item-Centric PDM / PLM, and which just knows to have a simple BOM from the design.

 

The 1st element that is critical to understand will be the fact that when talking about Item-Centric PDM / PLM, we are talking about managing the development process from Concept to Manufacturing, and not just design to BOM. The reason I am saying that is an Item-Centric PDM / PLM means bringing a Top-Down Engineering approach which means I am starting with Item (from Concept), reusing items structures, planning top-down up to the module level and only then going to design bottom-up. any solution that starts bottom-up from the design is not Item-Centric.

Next important element will be Item Maturity Management. When working Item-Centric, the Item maturity represent the development business process maturity and unlike a design maturity (that usually will be based on Check-in/Check-out/Release/Obsolete of the design) the item maturity really represent the development maturity (e.g. In Work, Approved by Engineering, Limited Released for purchasing only (LLI support), Released to manufacturing, Delivered, In Service…). also the movement (Promote/Demote) within this maturity process need to be performed based on the company development process rules and not just sequential.

But, the most important and critical is the ability to automatically apply the company business rules needed for getting into a new maturity state, e.g.:

• Does specifications needs to be released and frozen?
• Do I allow InActive/Obsolete children?
• Do I need all children to be in minimum state (e.g. Released, Approved by Engineering)
• When I demote an Item, how can I be sure I am not breaking maturity of a parent?

Usually, this part will be where you will need to invest a lot of customization (in applications that do not support real Item-Centric).

When implementing an Item-Centric PDM / PLM you need to be able to support different configuration views (e.g. Conceptual BOM, Engineering BOM, Manufacturing BOM, Serialized BOM…) the minimum will be E-BOM (Engineering BOM) and M-BOM (Manufacturing BOM). Is this enough? when working Item-Centric I need the capability to synchronize between those different configuration views, synchronize with embedded business logic (what needs to be synched and what is not), Item-Centric means I’m managing mechatronics (Multi-disciplinary product development integrating mechanical, electrical/electronic and software components – Unified BOM including Hardware (mechanical, electrical / electronic) & Software. This means I need to be able to automatically synch the unified BOM from multiple sources concurrently (Mechanical, Electronics, Software, Standard components, Outsourcing, Excel…) = Concurrent Engineering.

Also, do not forget different configuration views needs to be frozen based on different maturity states (E-BOM needs to be frozen when ‘Approved’ by engineering, but M-BOM is still open for modifications by production engineering.

 

So, to summarized – if one is selling you an Item-Centric PDM / PLM ask him:

1. Do you support Top-Down Engineering?
2. Do you support Item Maturity?
3. Can I model my development process into the Item Maturity?
4. Does the Item Maturity support Out-Of-The-Box business rules?
5. Do you support Configuration views (E-BOM, M-BOM)?
6. Can I automatically synchronize between the Configuration views?
7. Can I manage Mechatronics? unified BOM including Hardware (mechanical, electrical / electronic) & Software?
8. Can I Freeze Configuration views based on Item Maturity?

If the answers are YES to all those questions, you’ve got a real Item-Centric PDM / PLM in hand, if NOT…

BOM management – are you using Excel?

If you needed to take a guess… just a guess.. what is the most common ‘enterprise’ application that is used for managing BOMs in SMB companies?

I am wondering whether this was the first thing you have thought about (I know, you can guess it from this post title )…

The most common ‘enterprise’ application that is used for managing BOMs in SMB companies is Excel

Is it the right way? why not, some of you will say… Excel is a great tool (agreed by the way…) it is easy to use, it is flexible, but is it controlled?

Let’s look at some critical data management aspects concerning BOM management:

• Look at the following picture, How to Identify the “Right” BOM? Can you help me…

• I need to change the screw, where is it used…

• What about increasing data reuse? or standardization of components? or security?

• And then… as always… what happened when I have a change…

 

So yes, using PLM to manage your BOMs will be less flexible as using excel and the reason for that will be that a PLM system will take care of your data consistency and your configuration control.

Because of the fact that BOM management is a major challenge in a lot of SMB companies and is very time consuming (time which most of those companies does not have…), we gave special attention to those challenges within our SNE solution (ENOVIA SmarTeam Engineering Express). I think the 3 most important benefits will be:

• Product/BOM Maturity management (with the configurable, embedded business logic to model your company business maturity process and conditions)
• BOM structures synchronization. to enable concurrent and controlled BOM editing (with the configurable, embedded business logic to model your company roles of moving from Design to E-BOM, from E-BOM to M-BOM, Reuse BOMs…)
• Easy to use BOM editing and compare

 

and in the end… do not forget… COLLABORATION !!!

Manufacturing in PLM

PLM has a role in manufacturing?

We all know and understand the strategic role PLM is playing in design and engineering, during the development process from concept to manufacturing (up to manufacturing, not included). Manufacturing sounds to most of us as an ERP arena. Is it true? does PLM ends when a product development is released from engineering?

Before we talk more about the PLM role in the manufacturing world we should agree on the main role PLM and ERP are playing in our organizations. In my days as a customer (working at ELTA systems Ltd.), implementing PLM, I had a lot of visits from other companies wanted to learn about a successful PLM implementation. One of the main questions always were (especially from companies already have ERP implemented) what are the differences, where is the line between PLM and ERP?

The line between PLM and ERP

To my perspective this line is very clear. PLM is about managing the knowledge! ERP is about execution!

ERP is about maximize profits while PLM is about increasing innovation.

I will end this section with a quote from another post by Laila Hirr, The Key Differences between PLM and ERP in meeting corporate objectives:

“…it is a myth to believe that the systems designed to manage your physical inventory with rigor and structure, could be manipulated to become the flexible systems needed to foster innovation. The PLM vendors don’t even pretend to do the business of ERP systems – why is it that ERP systems believe they know how innovation in design should be managed?”

When understanding this, it is clear that also the knowledge of the manufacturing process itself needs to be managed in PLM. The execution of the manufacturing process will be in ERP.

Manufacturing in PLM scope

So, what is the scope of manufacturing support that needed in PLM?

1. Production engineering ‘Release to Manufacturing’

• Manufacturing BOM management
• from Engineering BOM to Manufacturing BOM
• Maturity management
• BOP – Bill of Process management
• Tooling
• Assembling Instructions
• Maintenance Instructions
• Work Instructions (Root Card)
• CAM data management
• NC Management
• FT&A
• Part & Assembly Management
• Operational Sequence (Instance BOM)
• Plant, Station, Operations management
• Resources and Tools management

2. Digital Manufacturing & Production

3. Prototyping

3. “As Shipped” BOM – Packaging BOM

4. “As Build” BOM – Serialized structures