Tags |
|
|
Links |
|
|
Hub You - Lean Principles in Action
INTRODUCTIONThe typical approach executive teams use to cascade, or roll out, their strategic direction is to produce a clear set of goals, objectives, critical success factors or a scorecard and then get each departmental or functional manager to take this on board and customize it for their part of the organisation. The trouble then begins…A TYPICAL APPROACH: EACH DEPARTMENT ADOPTS OR ADAPTS A VERSION OF THE CORPORATE STRATEGYThe first phase of most organisational planning processes is that the organisation's executives design and express a strategic direction using a framework of some kind. Commonly this framework will be something like a collection of key result areas or critical success factors or balanced scorecard (1) perspectives or triple (or quadruple) bottom line, and so on. Strategic goals or objectives will be developed within each part of this strategic framework, along with a set of key performance indicators (fondly nicknamed KPIs by the majority of the English speaking business world).For example, a Key Result Area of "Customer Focus" has a strategic goal of "raise customer advocacy to 25%", which is measured by % Customer Referrals. Another goal for this Key Result Area is "increase customer satisfaction to 95%", measured by % Customers Satisfied. For a Key Result Area of "Sustainable Profitability", a strategic goal of "increase profit by 100%" is measured by EBIT (Earnings Before Interest & Tax). Another goal for this Key Result A
At the SC plant, a number of dramatic changes were made which drove significant savings in a relatively short amount of time. Within the first 10 weeks, over 40% of the targeted 6 month goal was achieved, 30% greater than what was predicted.
Numerous changes were implemented to increase efficiency and reduce inventory. In the MCC area, a pull approach was employed to reduce WIP by employing a build trigger for the main structure. Prior to the implementation, structures and a related component were scheduled separately and were connected together at an area called plug-in. This created WIP of structures and the component waiting for their mates. By triggering the structure build when the component was done, the structure WIP at plug-in was dramatically reduced. In addition, the entire structure line was redesigned to balance the stations, shorten the cycle time, reduce space, and reduce the raw material inventory needed at the line. Production space was reduced by introducing U-shaped work cells in both the structure line and wiring areas
In the wiring area of MCC electronic work instructions were employed to allow the wirers to always have the latest revision print, reducing rework as well as part shortages.
To further drive efficiency and r
One of my favorite moments on any project is the moment when, after spending hours investigating a process, an exhausted interviewee gives an exasperated gasp and says “Well, that’s the way we’ve always done it!”Most companies with a long and storied corporate history have a similarly colorful story behind their internal processes. System limitations, management fads and product introductions have shaped everything from invoice generation to marketing campaign design. In many instances, over a matter of time these processes become a source of pride, and are even seen by some as a source of competitive advantage. People in the company that know the nuances of these processes, and are able to “finesse” a new product or management dictum into the confines of the current practice are highly regarded, and many an intelligent person is relegated to hammering square pegs into round holes, albeit to much acclaim.When a new system is implemented, there is a golden opportunity to simplify and redesign processes. Unfortunately this chance to start anew is overlooked, and much effort is expended to once again find creative ways to maintain self-inflicted problems. While competitors apply innovative talent to their product and service offerings, companies implementing new systems spend their creative efforts maintaining rather than redesigning. Whether it is due to self-inflicted time constraints, political problems or the sense of pride around the homegrown practice, “t
The electrical products industry is one characterized by fierce competition, declining margins, and legislative regulations, all that have forced the majority of electrical product manufacturers to rethink their business models. This article describes a successful story from a leading electrical products manufacturer and its journey towards lean, which to date, has saved the company over $65 Million in hard –dollar savings.
Background
Tefen has worked closely with one of the world’s leaders in Power and Control products. With worldwide consolidated sales exceeding $9 Billion in 2002, the company has roughly 200 manufacturing plants worldwide, with about half of them in North America.
In North America, Tefen has specifically worked with a division known for quality switchboards, switch gear, breakers, and other electrical components used within the energy, building, industry and infrastructure markets. The company faces stiff competition from General Electric, Siemens, and Westinghouse Electric in most categories. Given the level of world-class competition, the company has continually pursued strategies to improve its cost position, quality, and overall order fulfillment processes.
In the industry, this company is renowned for its ability to tailor its products to meet the specific needs of its clients. The ability and willingness to customize has created a competitive edge for them, while at the same time created operational challenges. Engineer to Order (ETO) products with a high degree of variability can often drive long lead time from design to production, large inventories, obsolescence, design control issues, production complexity, and inefficient scheduling, among other problems.
From 1996 to 2001, the highly competitive North America market and economic downturn drove steady margin erosion. In response, the company launched an enterprise-wide initiative to reduce manufacturing costs by 20-25% within two years at select manufacturing sites. Further, it set goals to build the skills base necessary to generate lasting continuous improvement, drive consistency in production systems, and optimize key areas of the supply chain.
A major plant in South Carolina was chosen as a key ETO facility to target for manufacturing cost improvement. With its 258,000 square feet of production space, large dollar opportunity, and products of strategic significance, it was a logical target. Tefen was engaged to understand the current state operation, define improved methods by applying Lean techniques, and then drive rapid implementation. The stated goal was to reduce conversion costs by a minimum of 20%.
The Situation at South Carolina
During the first week of the 3 week long diagnostic phase, Tefen worked with plant personnel to understand the current state of the operation. The Motor Control Center product (MCC), along with the Fabrication area (Fab), were the subjects of particular focus. Here, a number of key findings highlighted the need for dramatic operational improvement. Specifically, it was uncovered that the two areas of focus were characterized by:
- Long changeover times - Excessive WIP and Raw Material - Excessive active part numbers - Long lead times - A functional layout with poor material flow - High order variability - Inefficient labor utilization - Inefficient order entry processes - High level of overproduction and rework - High transportation costs
These underlying issues hindered the company’s performance at the plant level, which in turn, diminished the overall corporate operating result. Besides diminished cash-to-cash cycle time efficiency, the plant experienced
less than optimal order fulfillment performance, low inventory and asset turns, and high overall supply chain costs.
The Solution
During the second and third weeks of the diagnostic, Tefen defined a number of key levers to drive significant conversion cost savings. To conduct the diagnosis and quantify tangible savings, a number of tools and techniques were employed. For example, Value Stream Maps were created for both the “current state” and envisioned “future state” of the facility. Besides providing powerful visuals of the operations, these maps were used to quantify cycle times, inventory levels, number of operators, and the ratios of productive times to lead times. Another key analysis looked at the demand data to understand the volume/product/order mix. By coming to grips with the level of variation, smarter scheduling and better flow techniques could be devised. A full listing of analyses and the associated tools used to conduct them are shown below in Figure 1.
In Figure 2. the levers for savings and associated key activities are detailed. At the core of Lean is speed – process cycle-time efficiency is the overall defining Lean metric that paints the picture of a manufacturing plant’s health. By applying Lean principles, Tefen was able to identify ways to dramatically improve cycle time efficiency, which in turn, pointed the way to a 21% reduction in conversion costs. Recommendations focused on several key areas including improved material handling through a revised layout, reduced touches and dedicated handlers, reduced changeover times through standardized work, a flexible workforce operating within a flowing cellular line, and a scheduling system based on customer “pull” rather than forecasted “push.” In addition, Tefen recommended implementing a Constant Daily Output (CDO) system to produce the high volume products to a schedule. Instead of ramping production up and down in response to order volume, production of high volume material would be leveled based on order volume history.
Getting Results
Having identified what to fix, the next step was to put together a workable roll-out plan and begin implementation. Prior to the diagnostic, the pervasive culture at the SC plant was a typical one. There was a lack of urgency for improving things – inefficiencies were accepted as the normal mode of operation. One of the by-products of the three week diagnostic was an awakening among plant personnel. By including plant personnel as an integral part of the diagnostic process, new possibilities became apparent to them. Word spread and when it came time for implementation, there was more of a willingness to change. Further, Tefen’s “Go-Fast” implementation approach instilled a true sense of urgency and importance throughout the plant. The “Go-Fast” approach is designed to obtain significant results within 10 weeks, achieve more than 50% of the targeted savings within 6 months, and foster a continuous change culture.
Figure 1.
Improvement Lever Key Activities Reduce Overproduction Waste - Schedule starts based on a pull system Align Lead Time Information Flow - Define lead time across all systems Improve Material Flow - Cellular layout and elimination of excess storage Reduce Order Variability - Produce 80% of volume to a daily demand Improve Labor VA Utilization - Flexible work force, 5S discipline, shorter C/O Reduce Transportation Costs - Load consolidation and lane simplification Improve Order Processing - Develop Constant Daily Output order generator Standardize Work Methods - Improve C/O, eliminate multiple handling Improve Inventory Management - Constant daily production on top 80%, use stores
At the SC plant, a number of dramatic changes were made which drove significant savings in a relatively short amount of time. Within the first 10 weeks, over 40% of the targeted 6 month goal was achieved, 30% greater than what was predicted.
Numerous changes were implemented to increase efficiency and reduce inventory. In the MCC area, a pull approach was employed to reduce WIP by employing a build trigger for the main structure. Prior to the implementation, structures and a related component were scheduled separately and were connected together at an area called plug-in. This created WIP of structures and the component waiting for their mates. By triggering the structure build when the component was done, the structure WIP at plug-in was dramatically reduced. In addition, the entire structure line was redesigned to balance the stations, shorten the cycle time, reduce space, and reduce the raw material inventory needed at the line. Production space was reduced by introducing U-shaped work cells in both the structure line and wiring areas
In the wiring area of MCC electronic work instructions were employed to allow the wirers to always have the latest revision print, reducing rework as well as part shortages.
To further drive efficiency and re
While there are many brands and models of Wire EDM machines available today, the three most prominent manufacturers are Elox, Japax, and Mitsubishi.While each of these companies manufacture similar products, there will always be some varying features such as the User-interface with the CNC controller, the numbers of wires, be it a 4-axis or 5-axis Wire EDM machine, type of electrical current (AC vs. DC), and the gauges of wires that can be used. Another very big difference will be the size of the tank in which the manufacturing is accomplished.Some examples of specifications for one model from each of these companies are:Elox Fanuc Model M - (the Fanuc indicating the type of CNC controller that is a component of the Elox Wire EDM) has an X-axis path of 20”, a Y-axis path of 14”, and a Z-axis path of 10”Japax Wire EDM Model LDM-S - has a Y-axis path 13.8” and capable of machining a work piece with the measurements of 15.7” x 19.7” x 5.9” and a table that moves 7.9” x 13.8”Mitsubishi Wire EDM Model DWC 110 H-1 - has an X-axis of 12”, a Y-axis of 18”, and a Z-axis of 10”Each of these models only represents one of many different models offered by their respective manufacturer. Variations will be observed from model to model with some differences including the distance that each axis wire can travel, the size of product that can be manufactured and the CNC controller.When selecting a wire EDM machine, one must take into consideration
A major plant in South Carolina was chosen as a key ETO facility to target for manufacturing cost improvement. With its 258,000 square feet of production space, large dollar opportunity, and products of strategic significance, it was a logical target. Tefen was engaged to understand the current state operation, define improved methods by applying Lean techniques, and then drive rapid implementation. The stated goal was to reduce conversion costs by a minimum of 20%.
The Situation at South Carolina
During the first week of the 3 week long diagnostic phase, Tefen worked with plant personnel to understand the current state of the operation. The Motor Control Center product (MCC), along with the Fabrication area (Fab), were the subjects of particular focus. Here, a number of key findings highlighted the need for dramatic operational improvement. Specifically, it was uncovered that the two areas of focus were characterized by:
- Long changeover times - Excessive WIP and Raw Material - Excessive active part numbers - Long lead times - A functional layout with poor material flow - High order variability - Inefficient labor utilization - Inefficient order entry processes - High level of overproduction and rework - High transportation costs
These underlying issues hindered the company’s performance at the plant level, which in turn, diminished the overall corporate operating result. Besides diminished cash-to-cash cycle time efficiency, the plant experienced
less than optimal order fulfillment performance, low inventory and asset turns, and high overall supply chain costs.
The Solution
During the second and third weeks of the diagnostic, Tefen defined a number of key levers to drive significant conversion cost savings. To conduct the diagnosis and quantify tangible savings, a number of tools and techniques were employed. For example, Value Stream Maps were created for both the “current state” and envisioned “future state” of the facility. Besides providing powerful visuals of the operations, these maps were used to quantify cycle times, inventory levels, number of operators, and the ratios of productive times to lead times. Another key analysis looked at the demand data to understand the volume/product/order mix. By coming to grips with the level of variation, smarter scheduling and better flow techniques could be devised. A full listing of analyses and the associated tools used to conduct them are shown below in Figure 1.
In Figure 2. the levers for savings and associated key activities are detailed. At the core of Lean is speed – process cycle-time efficiency is the overall defining Lean metric that paints the picture of a manufacturing plant’s health. By applying Lean principles, Tefen was able to identify ways to dramatically improve cycle time efficiency, which in turn, pointed the way to a 21% reduction in conversion costs. Recommendations focused on several key areas including improved material handling through a revised layout, reduced touches and dedicated handlers, reduced changeover times through standardized work, a flexible workforce operating within a flowing cellular line, and a scheduling system based on customer “pull” rather than forecasted “push.” In addition, Tefen recommended implementing a Constant Daily Output (CDO) system to produce the high volume products to a schedule. Instead of ramping production up and down in response to order volume, production of high volume material would be leveled based on order volume history.
Getting Results
Having identified what to fix, the next step was to put together a workable roll-out plan and begin implementation. Prior to the diagnostic, the pervasive culture at the SC plant was a typical one. There was a lack of urgency for improving things – inefficiencies were accepted as the normal mode of operation. One of the by-products of the three week diagnostic was an awakening among plant personnel. By including plant personnel as an integral part of the diagnostic process, new possibilities became apparent to them. Word spread and when it came time for implementation, there was more of a willingness to change. Further, Tefen’s “Go-Fast” implementation approach instilled a true sense of urgency and importance throughout the plant. The “Go-Fast” approach is designed to obtain significant results within 10 weeks, achieve more than 50% of the targeted savings within 6 months, and foster a continuous change culture.
Figure 1.
Improvement Lever Key Activities Reduce Overproduction Waste - Schedule starts based on a pull system Align Lead Time Information Flow - Define lead time across all systems Improve Material Flow - Cellular layout and elimination of excess storage Reduce Order Variability - Produce 80% of volume to a daily demand Improve Labor VA Utilization - Flexible work force, 5S discipline, shorter C/O Reduce Transportation Costs - Load consolidation and lane simplification Improve Order Processing - Develop Constant Daily Output order generator Standardize Work Methods - Improve C/O, eliminate multiple handling Improve Inventory Management - Constant daily production on top 80%, use stores
At the SC plant, a number of dramatic changes were made which drove significant savings in a relatively short amount of time. Within the first 10 weeks, over 40% of the targeted 6 month goal was achieved, 30% greater than what was predicted.
Numerous changes were implemented to increase efficiency and reduce inventory. In the MCC area, a pull approach was employed to reduce WIP by employing a build trigger for the main structure. Prior to the implementation, structures and a related component were scheduled separately and were connected together at an area called plug-in. This created WIP of structures and the component waiting for their mates. By triggering the structure build when the component was done, the structure WIP at plug-in was dramatically reduced. In addition, the entire structure line was redesigned to balance the stations, shorten the cycle time, reduce space, and reduce the raw material inventory needed at the line. Production space was reduced by introducing U-shaped work cells in both the structure line and wiring areas
In the wiring area of MCC electronic work instructions were employed to allow the wirers to always have the latest revision print, reducing rework as well as part shortages.
To further drive efficiency and r
Customer service as its affectionately known revolves around the telephone. You have to be very particular when delivering customer service over the phone. Since they can't see you, your voice and style is pretty much all you have.Problem is, people are animals. I'm not referring in any evolutionary sense -just the behavioral. Once an animal senses you are afraid of it, it's likely to attack you. Angry people on the phone are pretty much the same:Customer: "YOU PEOPLE ARE *&$#@@#!! I DON'T BELIEVE YOU DID THIS!" (Here the caller's testing the water, to see whether the listener's afraid or not?)Customer Service Rep: 'Oh, Oh, I'm sorry, oh..umm..hmm..sir...ummm, I'm sorry' (Voice trembling with fear. Guess what? Green light - Attack me!)"YOU'RE SORRY!? I DON'T WANT YOU TO BE SORRY! I WANT YOU TO FIX THIS &^$%^%&^ PROBLEM!" (Attack mode!)Hmm, sound familiar?If this has happened to you I bet you felt really insulted by the put-down. Probably so spooked that every time the phone rings now, you're haunted by the memory of that call. On the other hand, you may have argued back and thought to yourself "HA! I showed him! No way is someone going to talk to me like that!"And it made you feel a whole lot better right? And the customer never buys from you again and tells 10 others how much you suck. So - Wrong!Here are some handy tips on how to handle phone abuse and turn the caller into a loyal customer. Customers who have their co
less than optimal order fulfillment performance, low inventory and asset turns, and high overall supply chain costs.
The Solution
During the second and third weeks of the diagnostic, Tefen defined a number of key levers to drive significant conversion cost savings. To conduct the diagnosis and quantify tangible savings, a number of tools and techniques were employed. For example, Value Stream Maps were created for both the “current state” and envisioned “future state” of the facility. Besides providing powerful visuals of the operations, these maps were used to quantify cycle times, inventory levels, number of operators, and the ratios of productive times to lead times. Another key analysis looked at the demand data to understand the volume/product/order mix. By coming to grips with the level of variation, smarter scheduling and better flow techniques could be devised. A full listing of analyses and the associated tools used to conduct them are shown below in Figure 1.
In Figure 2. the levers for savings and associated key activities are detailed. At the core of Lean is speed – process cycle-time efficiency is the overall defining Lean metric that paints the picture of a manufacturing plant’s health. By applying Lean principles, Tefen was able to identify ways to dramatically improve cycle time efficiency, which in turn, pointed the way to a 21% reduction in conversion costs. Recommendations focused on several key areas including improved material handling through a revised layout, reduced touches and dedicated handlers, reduced changeover times through standardized work, a flexible workforce operating within a flowing cellular line, and a scheduling system based on customer “pull” rather than forecasted “push.” In addition, Tefen recommended implementing a Constant Daily Output (CDO) system to produce the high volume products to a schedule. Instead of ramping production up and down in response to order volume, production of high volume material would be leveled based on order volume history.
Getting Results
Having identified what to fix, the next step was to put together a workable roll-out plan and begin implementation. Prior to the diagnostic, the pervasive culture at the SC plant was a typical one. There was a lack of urgency for improving things – inefficiencies were accepted as the normal mode of operation. One of the by-products of the three week diagnostic was an awakening among plant personnel. By including plant personnel as an integral part of the diagnostic process, new possibilities became apparent to them. Word spread and when it came time for implementation, there was more of a willingness to change. Further, Tefen’s “Go-Fast” implementation approach instilled a true sense of urgency and importance throughout the plant. The “Go-Fast” approach is designed to obtain significant results within 10 weeks, achieve more than 50% of the targeted savings within 6 months, and foster a continuous change culture.
Figure 1.
Improvement Lever Key Activities Reduce Overproduction Waste - Schedule starts based on a pull system Align Lead Time Information Flow - Define lead time across all systems Improve Material Flow - Cellular layout and elimination of excess storage Reduce Order Variability - Produce 80% of volume to a daily demand Improve Labor VA Utilization - Flexible work force, 5S discipline, shorter C/O Reduce Transportation Costs - Load consolidation and lane simplification Improve Order Processing - Develop Constant Daily Output order generator Standardize Work Methods - Improve C/O, eliminate multiple handling Improve Inventory Management - Constant daily production on top 80%, use stores
At the SC plant, a number of dramatic changes were made which drove significant savings in a relatively short amount of time. Within the first 10 weeks, over 40% of the targeted 6 month goal was achieved, 30% greater than what was predicted.
Numerous changes were implemented to increase efficiency and reduce inventory. In the MCC area, a pull approach was employed to reduce WIP by employing a build trigger for the main structure. Prior to the implementation, structures and a related component were scheduled separately and were connected together at an area called plug-in. This created WIP of structures and the component waiting for their mates. By triggering the structure build when the component was done, the structure WIP at plug-in was dramatically reduced. In addition, the entire structure line was redesigned to balance the stations, shorten the cycle time, reduce space, and reduce the raw material inventory needed at the line. Production space was reduced by introducing U-shaped work cells in both the structure line and wiring areas
In the wiring area of MCC electronic work instructions were employed to allow the wirers to always have the latest revision print, reducing rework as well as part shortages.
To further drive efficiency and r
If you know (or think you know) exactly what you want your boutique to be about, with some idea of how to get there, then congrats. You are one very big step closer to manifesting your dream.One “law of success” that is universally accepted, by people that have experienced success in any and all areas of life, is this: the more clear and specific you are about what you want and how you will get it, the quicker you will reach your goal.On the other hand, your goal may be slightly ”ambiguous”. In other words, you know you want your own business. Even more specifically, you want to have your own boutique. You want to express your unique vision and creativity through your boutique and share it with others, while earning a good living.But perhaps you don’t know exactly how it will take shape. This is perfectly fine for now, and perfectly normal. Just keep in mind, you must define it, as concretely as possible, in your mind, on paper, in every conceivable way, before you begin to create it.You need to be able to visualize what you are setting out to do, concretely in as much detail as possible. If you do not, what you end up with is being left to chance – and won’t necessarily be what you want.So, if your goal is “narrowed down” to something like “I want a really cute boutique with great clothes and a fabulous look and feel”, you are not quite there.That would be roughly equivalent to going to a restaurant and telling the server “I’m in the m
Getting Results
Having identified what to fix, the next step was to put together a workable roll-out plan and begin implementation. Prior to the diagnostic, the pervasive culture at the SC plant was a typical one. There was a lack of urgency for improving things – inefficiencies were accepted as the normal mode of operation. One of the by-products of the three week diagnostic was an awakening among plant personnel. By including plant personnel as an integral part of the diagnostic process, new possibilities became apparent to them. Word spread and when it came time for implementation, there was more of a willingness to change. Further, Tefen’s “Go-Fast” implementation approach instilled a true sense of urgency and importance throughout the plant. The “Go-Fast” approach is designed to obtain significant results within 10 weeks, achieve more than 50% of the targeted savings within 6 months, and foster a continuous change culture.
Figure 1.
Improvement Lever Key Activities Reduce Overproduction Waste - Schedule starts based on a pull system Align Lead Time Information Flow - Define lead time across all systems Improve Material Flow - Cellular layout and elimination of excess storage Reduce Order Variability - Produce 80% of volume to a daily demand Improve Labor VA Utilization - Flexible work force, 5S discipline, shorter C/O Reduce Transportation Costs - Load consolidation and lane simplification Improve Order Processing - Develop Constant Daily Output order generator Standardize Work Methods - Improve C/O, eliminate multiple handling Improve Inventory Management - Constant daily production on top 80%, use stores
At the SC plant, a number of dramatic changes were made which drove significant savings in a relatively short amount of time. Within the first 10 weeks, over 40% of the targeted 6 month goal was achieved, 30% greater than what was predicted.
Numerous changes were implemented to increase efficiency and reduce inventory. In the MCC area, a pull approach was employed to reduce WIP by employing a build trigger for the main structure. Prior to the implementation, structures and a related component were scheduled separately and were connected together at an area called plug-in. This created WIP of structures and the component waiting for their mates. By triggering the structure build when the component was done, the structure WIP at plug-in was dramatically reduced. In addition, the entire structure line was redesigned to balance the stations, shorten the cycle time, reduce space, and reduce the raw material inventory needed at the line. Production space was reduced by introducing U-shaped work cells in both the structure line and wiring areas
In the wiring area of MCC electronic work instructions were employed to allow the wirers to always have the latest revision print, reducing rework as well as part shortages.
To further drive efficiency and r
In this final installment of medical billing of electronic claims, using NSF 3.01 specifications, we're going to cover the last fields of the FB0 record. Before we do that though, there is something that should be pointed out not only about the FB0 record but about all line item detail records, which include FA0, FB0, FB1 and FB2 records.Many people in the industry feel that the amount of information transmitted in regard to line item detail is overkill. The majority of professionals who work in the field of medical billing feel that the item description, item number and price is all that should need be transmitted in addition to the patient the drug, item or procedure is being billed for. There are pros and cons to this argument that we're going to touch on briefly.The pros are obvious enough. With a decrease in the amount of information that is transmitted, the cost of medical billing will go down. While many people think that doctors are mostly responsible for rising medical costs, as well as the drug manufacturers who charge insane amounts of money for one pill, the truth is, medical billing costs are greatly responsible for the overall increase in medical costs in general. The red tape involved with processing most claims doesn't help to reduce costs any. And let's be honest, the billing companies and the companies that provide billing services and software want to get their piece of the pie too. So the more information that needs to be transmitted, t
At the SC plant, a number of dramatic changes were made which drove significant savings in a relatively short amount of time. Within the first 10 weeks, over 40% of the targeted 6 month goal was achieved, 30% greater than what was predicted.
Numerous changes were implemented to increase efficiency and reduce inventory. In the MCC area, a pull approach was employed to reduce WIP by employing a build trigger for the main structure. Prior to the implementation, structures and a related component were scheduled separately and were connected together at an area called plug-in. This created WIP of structures and the component waiting for their mates. By triggering the structure build when the component was done, the structure WIP at plug-in was dramatically reduced. In addition, the entire structure line was redesigned to balance the stations, shorten the cycle time, reduce space, and reduce the raw material inventory needed at the line. Production space was reduced by introducing U-shaped work cells in both the structure line and wiring areas
In the wiring area of MCC electronic work instructions were employed to allow the wirers to always have the latest revision print, reducing rework as well as part shortages.
To further drive efficiency and reduce unnecessary material handling, kitting and “milk run” concepts were implemented. With these techniques, fewer operators were needed as productivity rose with more time on task.
In the Fab area, the other area of particular focus in South Carolina, additional improvements were implemented. A cellular layout based on material flow and capacity analysis was created. Changeover times were greatly reduced by division of internal and external work content to maximize operator value-add time. Further, a constant daily output (CDO) scheme was implemented to help reduce the effects of variability. Level loading of Fab production was accomplished by observing the 80/20 rule where 80% of the volume is driven by 20% of the part types. For the remaining 20% of the volume, which reflected special customer orders, lead time was greatly reduced by using a Supermarket to provide a buffer to demand variability. The Supermarket technique allowed for a lead time reduction from 6 to 2 days.
Other improvements impacted the entire plant, beyond the MCC and Fab areas. Scrap reduction of over $40K month was accomplished via coil re-banding. At the plant, raw material arrives on a coil. When a part type is finished at its CDO quantity, the coil is taken off the press and re-banded instead of becoming scrap. Previously, before the re-banding implementation, 21% of raw material became scrap. Improvements in the Tool crib added another $100K in inventory reduction.
Implementation of actionable performance metrics solidified the overall gains and instilled a culture of continuous improvement. The metrics enabled a focus on reducing waste and drove operator empowerment at the cellular level. KPI’s are now tracked at the plant level, the department level and the cell level to illuminate cost/efficiency, service level, quality, and continuous improvement. Examples of KPI’s implemented include: CDO Stability, Supermarket space requirements, Planned schedule versus actual, and the percent of good parts out.
Looking forward, the outlook for further improvement is bright. About 60% of the total identified savings will be realized according to schedule. The remaining savings are on track to be realized within a year and a half of the implementation start.
About Tefen Tefen is a publicly traded, international operations consulting firm with seven offices in United States, Europe and Israel. The firm has over twenty years of experience in improving the overall operational effectiveness of Fortune 500 clients around the world. Tefen designs and implements solutions that enhance operational performance throughout an organization. The main areas of focus include operational excellence, manufacturing, quality, customer service, research and development, and supply chain management. All of Tefen's support programs are ISO 9001 and TCS (Total Customer Satisfaction) certified. Our hands-on approach has achieved success in delivering quantifiable and value-driven results. The company has remained profitable since its inception and currently employs over 250 professionals worldwide, 40 of whom are certified Six Sigma Black Belts.
HTTP = HTML link (for blogs, profiles,phorums):
<a href="http://www.iadvice.info/article/23995/iadvice-Lean-Principles-in-Action.html">Lean Principles in Action</a>
BB link (for phorums):
[url=http://www.iadvice.info/article/23995/iadvice-Lean-Principles-in-Action.html]Lean Principles in Action[/url]
Related Articles:
Business Is Like A Cup of Coffee
Bookmark it:
|