# Introduction he ready-made garment (RMG) is one of the most essential sectors in Bangladesh in terms of foreign export earnings, economic advancement, employment, and its contribution to Gross Domestic Product (GDP). It is one of the leading exporting industries in Bangladesh. To achieve the overall objective in minimizing defects and rejection of finished products, it is required to set up a document and maintain a system able to ensure that products are conformance to the standards specifications. Considering the reasons above, that means this study attempts to explore the use of DMAIC (define, measure, analyze, improve and control) methodology of six sigma in a selected garment factory to minimize the defect percentage. DMAIC methodology of six sigma is a problemsolving method where six sigma tools are used to analyze the process data, and finally, the root causes behind the defects produce in the product are identified. Six Sigma is a quality improvement process of the final product by reducing the defects, minimizing the variation and improving capability in the manufacturing process. Six Sigma initiated from the terms associated with statistical modeling of manufacturing processes. # a) Objectives Quality Management is an operational strategy oriented towards achieving the shortest possible cycle time by eliminating wastes. The term Quality Management is coined to represent half the human effort in the company, half the manufacturing space, half the investment in tools and half the engineering hours to develop a new product in half the time. Any industry can achieve these benefits if they religiously follow this concept in their organization. In simple terms, lean manufacturing is without waste. Thus the objective of this study is to find out how we can use Quality Management to achieve the following: 1. To meet customer demand on time by eliminating nonvalue added work from the process. 2. To minimize the work in process inventory. 3. To create the flexibility of style changeover. 4. To reduce rework percentage. 5. To create a pool of multi-skilled operators who can respond quickly for changing the style. # II. # Literature Review a) Quality management It is the act of overseeing all activities and tasks needed to maintain a desired level of excellence. Quality management includes the determination of a quality policy, creating and implementing quality planning and assurance, and quality control and quality improvement. Quality management ensures that an organization, product or service is consistent. It has four main components: quality planning, quality assurance, quality control and quality improvement. Quality management is focused not only on product, and service but also on the means to achieve it. # b) Lean Lean is a systematic approach to identifying and eliminating waste through continuous improvement of the product at the demand of the customer. Taiichi Ohno once said that "Lean Manufacturing is all about looking at the time line from the moment the customer gives us an order to the point when we collect the cash. And we are reducing that time line by removing the non -value added wastes" (Ohno, 1988) Identify all the steps along the process chain -This means identifying the value stream. It can be used to identify activities where the value adds to the product and those do not. Make those processes flow -The value-added product must flow continuously from start to finish without interruptions, detours, backflows, waiting, scrap and stoppages. Make what is pulled by the customer -The customer should pull the product from the source as needed rather than process pushing the products onto the customer. Strive for perfection -After implementing the above steps, the team should continuously remove wastes as they are in uncover condition and pursue perfection through continuous improvement. Lean uses practically proven tools and techniques to systematically eliminate the wastes. If these are correctly applied, it will bring improvements to quality, cost, and delivery of the final product. Those tools help in implementing, monitoring, and evaluating Lean efforts and their results. Without proper understanding of lean approaches, it can spoil Lean efforts in one's organization garment, component or style. # d) Toyota Production System It is a manufacturing system developed by Toyota in Japan after World War II, which aims to increase production efficiency by the elimination of waste. The Toyota production system was invented and made to work, by Taiichi Ohno. While analyzing the problems inside the manufacturing environment; Ohno came to conclude that different kinds of wastes (nonvalue added works) are the main cause of inefficiency and low productivity. Ohno identified waste in several forms, including overproduction, waiting time, transportation problems, inefficient processing, inventory, and defective products. # Pareto Diagram: The Pareto diagram is a graphical overview of the process problems, in ranking order from the most frequent, down to the least frequent, in descending order from left to right. Thus, the Pareto diagram illustrates the frequency of fault types. Using a Pareto, one can decide which fault is the most serious or most frequent offender. # Fishbone Diagram: A framework used to identify potential root causes leading to poor quality. Histogram: A graph of variable data providing a view of the distribution of data around the desired target value. Scatter Diagram: A graph used to display the effect of changes in one input variable on the output of an operation. # e) Just in Time Just-in-time manufacturing is a Japanese management philosophy applied in manufacturing. It involves having the right items with the right quality and quantity in the right place at the right time. In general, Just in Time (JIT) helps to optimize company resources like capital, equipment, and labor. The goal of JIT is the total elimination of waste in the manufacturing process. Although the JIT system is applied mostly to the manufacturing environment, the concepts are not limited to this area of business only. The philosophy of JIT is a continuous improvement that emphasizes on prevention rather than correction and demands a companywide focus on quality. # III. # Method and Materials # J The methodology adopted for this study is a case study and brain storming. The case study conducted on a garment factory named Ananta Apparels Ltd. Located at Narayanganj. At first preliminary investigation was carried out at cutting, sewing, washing, finishing and packing section to identify the area where most of the defects occur. It finds that, the sewing section is highly suffered from defect and rework problems. For this reason, the sewing line is identified to conduct research work. The work # a) Data Collection Data sheets collected for garment item such as polo shirt for three months. The data collected by the end line quality inspectors from two production lines of sewing section. We checked 3500 polo shirts, and 470 pieces were found defective. # b) Application of Six Sigma DMAIC Methodology Define Phase: Define is the first phase of the DMAIC methodology of Six Sigma. The purpose of this phase is to define the problem, the goal of the project and the process that needs to be improved to get a higher sigma level. There are different six sigma tools are available for define phase. Here SIPOC tool was applied. Problem Statement: The garments manufacturer experience high volume of rejections of their products owing to defects. Goal Statement: To decrease the percentage of the defect to the lowest level and thereby to reduce production cost and increase quality and productivity. SIPOC: This is a process map that includes Suppliers, Inputs, Process, Outputs and Customers. Quality is judged based on the output of a process. Table 1 shows the SIPOC flow of the selected factory. # J aims to minimize the defect percentage by using the DMAIC approach of Six Sigma methodology. Secondary data of the sewing section collected from the management of the factory. The data collected for polo shirts only. According to our observation and using the end line quality data provided by the management, then we identified some repetitive defects that occur in the sewing section. The information and data collected were arranged so that further study and analysis could perform. The suggestions were made based on the brain storming session which was arranged by the management of the factory. Experts of the factory from different areas were present in that session. Due to time constraint, management could not be able to implement all of the suggestions together. But they implemented some of the suggestions in short time-frame on their pilot line and found some improvement. # Table 3: Frequency of Defects of the Inspected Polo Shirts Analyze phase: Two problem solving six sigma tools used at analyzing phase and these were: Brainstorming and cause and effect diagram. Brainstorming: Brainstorming is one of an essential problem-solving tools. The goal of this tool is to identify the issues, solutions and opportunities. To find out the potential causes of the defects and their respective solutions, we arranged a brainstorming session where they applied the Round Robin method with the presence of the following members that are shown in table 4. Through brainstorming with sewing operators, line supervisors, end line quality inspectors, engineers, and floor manager, we recognized various probable causes. Then we identified the potential causes by online inspections and root cause analysis. Improve Phase: The purpose of the DMAIC Improve phase is to discover a solution to the problem that the task aims to address. This improve phase involves brainstorming potential solutions, selection of solutions to test and evaluating the results of the implemented solutions. Often a pilot implementation is conducted before a full-scale rollout of improvements. # Cause and effect diagram: Suggested Solutions: This study tried to suggest some potential solutions to minimize the causes of defects through Brainstorming, direct observation and literature review. Table-5 gives necessary solutions with their corresponding causes. # Method Incorrect size of the needle and thread for operation Ensure that the correct thread type and size rightly feeds both the needle and bottom (looper) positions. Comparatively long stitch for the type of fabric in work. Shorten the stitch length using the stitch regulator, especially when sewing fine fabrics Year 2019 J c) Implementation of the Solutions Based on the solutions provided by this study, we took some corrective actions mentioned in table-6. We implemented it into one of their pilot sewing line. The pilot line had a total of 105 sewing machines. # Table 6: Corrective Actions and Its Amount Control Phase: After the implementation of the solutions, we shared the progressive outcomes with the management. The main defects were recognized and partially reduced in amount. Now the challenge is to withstand the progress and to refine the system continuously. For this purpose, a control plan is prepared. # Control Plan: The management needs to take the initiative on the following obligatory activities to withstand the progress after Six Sigma implementation: i. Arrange training continuously for the garments operators on the issue of quality. ii. Always use quality threads, needles, and other garment accessories. iii. A sound incentive scheme should take for highquality performance. iv. Preventing defects will be given more priority than correcting defects. v. Enforce strict quality control in the line. vi. The organization should develop a proper Quality Management System. IV. # Results and Discussions We implemented all the suggested solutions into one of their pilot sewing lines. After the implementation of solutions percentage of defectives, then we calculated DPMO and Sigma Level by using the previous sigma level formula and reported on table 7. # Conclusion Minimizing defect is very important for ensuring the quality of products. Manufacturing the quality product is mandatory to sustain in this global competitive market. This study follows the DMAIC methodology of Six Sigma to find out the major defects, their root causes and then suggests logical solutions to minimize those defects. This study identified some defects (broken stitch, skip stitch, raw edge, uneven stitch, down stitch, process missing, puckering and joint stitch) those were responsible for more than 80% of total defects occurring in the sewing section of the garment factory for the item of a polo shirt. After finding the major defects, brainstorming tool was used to identify the probable causes and then we identified potential root causes by online inspections and root cause analysis. A significant improvement of the Sigma level found in the industry. So this method is very operative to the minimization of defects. If many garment factories in Bangladesh follow the six sigma concept, then they can minimize most of the defects in the sewing section. Year 20192( ) Volume XIx X Issue III Version IJournal of Researches in EngineeringGlobal© 2019 Global Journals 1Measure Phase: At this phase, the percentage ofOpportunities) and calculation of the Sigma Level of thedefects,existingDPMO(Defect per Millionselected factory indicated in table 2.Now, Table-2 shows the DPMO and Sigma level of Existing process- 2Year 20193Suppliers -Acotex Bangladesh Ltd. -Fabian GroupInputs Unstitched cloth Machinery Thread NeedlesProcesses Cutting Sewing Washing IroningOutputs T-shirt Polo shirt PantCustomers -H&M -Tesco -ZARA( ) Volume XIx X Issue III Version I-D.H FashionButton Zipper Label Total Checked pieces Finishing Packaging 3500 No. of Defectives % Defectives 13.42 0.1342 DPO 470Global Journal of Researches in EngineeringDPMO134285Sigma level2.6063© 2019 Global JournalsCalculation of the Sigma level by using the following formula in Ms. Excel: .5; Where, Defects-470, Total Opportunities -3500, Sigma shift= 1.5.Sigma Level-Normisnv (1-Defects/Total opportunities) +1 4DefectsReal OccurrencePercentage (%) of OccurrenceSkip Stitch459.57Down Stitch377.87Broken Stitch13428.51Raw Edge428.94Joint Stitch357.45Uneven Stitch388.09Spot/Oil stain255.32Hole/Damage153.19Puckering398.30Reject71.49Slanted51.06Uncut Thread20.43Reverse194.04Size Mistake40.85Process Missing234.89Total470100.00AttendantsNumbersSewing Floor Manager1Industrial Engineer2GPQ (Growth, Production, and Quality)2End Line Quality Inspector3Line Supervisor3Sewing Machine Operator5 5ManMachineExcessive pressure on the pressure footCarelessnessDull or bent sewing machine needle and knifeInadequate training andThe machine is threaded incorrectly oroperator inefficiencyexcessive thread tensionAll DefectsThe stitch is too long for the type of fabric inworkPoor quality needleWrong needle size and thread sizePoor quality threadIncorrectly inserted needleMaterialMethodAreasCausesSuggested SolutionsInadequate training and operator inefficiencyTrained and motivated operators sufficientlyManNegligenceImproved supervision.Machine The machine is threaded incorrectly or excessiveRethread machine and maintain proper thread tensions.thread tensionExcessive pressure on the presser foot.Minimize the pressure on the presser foot.Bent sewing machine needle and knife.Replace the needle and knife with a new one. 7Incorrectly inserted needleCheck that the bobbin wounds correctly and no loose threads or loops sticking out.MaterialPoor quality threadUsing core spun yarn .Poor quality needleThe needle should have high heat resistance capacity.Corrective ActionsAmountReplacement of dull or bent sewing machine needles16 needlesReplacement of dull knives9 knivesNumber of machines rethreaded17 machinesCorrection of needle insertions15 machinesReplacement of faulty bobbins3 machinesTraining providedmachines 2 hours each dayV. * Export Performance of RMG of Bangladesh for 2011-12 and 2012-13, Annual Report of Bangladesh Knitwear Manufacturers and Export Association BKMEA * Minimization of Reworks in Quality and Productivity Improvement in the Apparel Industry MMIslam AMKhan Int. J. of Engg. and Applied Sciences 1 4 2013 * GeoffTennant SixSigma SPC and TQM in Manufacturing and Services Gower Publishing Ltd 2001 25 * DSikorski JWDean DEBowen Management Theory and Total Quality: Improving Research and Practice and Theory Development 1994 19 * Six sigma in small and medium-sized UK manufacturing enterprises: Some empirical observations AntonyJKumar MMadu CN International Journal of Quality and Reliability Management 22 8 2005 * Toyota Production System TOhno 1988 Productivity Press New York * Dynamics of manufacturing Productivity MIShahidul STSyed Shazali Journal of Manufacturing Technology Management 22 5 2011 * Implementation of Six Sigma to Minimize Defects in Sewing Section of Apparel Industry in Bangladesh 10