Operational Research in Engineering Sciences: Theory and Applications 
Vol. 4, Issue 2, 2021, pp. 36-54 
ISSN: 2620-1607 
eISSN: 2620-1747 

 DOI: https://doi.org/10.31181/oresta20402036f 

* Corresponding author. 
Dimas.mhfathurohman (Fathurohman), humiras.hardi@mercubuana.ac.id (H. H. Purba), 
aristrimarjoko@gmail.com (A. Trimarjoko)  

VALUE STREAM MAPPING AND SIX SIGMA METHODS TO 
IMPROVE SERVICE QUALITY AT AUTOMOTIVE SERVICES 

IN INDONESIA  

Dimas Mukhlis Hidayat Fathurohman 1, Humiras Hardi Purba 1, Aris 
Trimarjoko 2* 

1 Department of Industrial Engineering, Mercu Buana University, Jakarta, Indonesia  
2 Department of Industrial Engineering, Sekolah Tinggi Teknologi Yuppentek, 

Tangerang, Banten, Indonesia 
 

Received: 16 February 2021  
Accepted: 26 April 2021  
First online: 24 June 2021 

 
Research paper 

Abstract: Automotive service industry currently holds an important role in helping to 
increase customer satisfaction. Various strategies are carried out to win the 
competition for increasing customer satisfaction. Quality service combined with the 
right instruments can be used to increase customer satisfaction and loyalty. Customer 
satisfaction is the key to success in the manufacturing and service industries. Service 
quality is an important attribute and it is a key factor in service industries. Improving 
lead time service in automotive Toyota dealer service industries is the focus of this 
research. Value Stream Mapping succeeded in identifying problems that were 
happening as an impact of waiting for services, washing processes, and length of service 
processes. The DMAIC (Define, Measure, Analyze, Improve and Control) method assisted 
by tools of quality successfully analyzed and gave recommended corrective actions to 
reduce the lead time of Express Maintenance Service from 120.06 minutes to 64.00 
minutes or improved 53% per service cycle, and succeeded in increasing the capability 
of the service process from 1.96 sigma to 3.80 sigma. Quality of service can be improved 
to get customer satisfaction, increase company profitability, and increase the 
competitiveness of companies in maintaining the sustainability of the industry in the 
future. 

Keywords: Service Quality, Lead Time, Value Stream Mapping, DMAIC 

1. Introduction 

Global competition in the increasingly stringent industry requires business people 
to get effective strategies to meet customer satisfaction. Customer satisfaction is a 



Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive 
Services in indonesia 

 

37 
 

feeling of consumers for the product or service that has been used (Kuhlang et al. 
2011). Customer satisfaction can be formed if the organization might be able to 
provide product characteristics or attributes following customer expectations 
(Pyzdek, 2003). Thus, it can be interpreted that customer satisfaction is one of the 
important attributes in the industrial world, especially the service industry. Based on 
this fact, the service industry must be able to identify important elements and be able 
to make improvements to receive intended customer satisfaction. The automobile 
services industry in Indonesia is a type of automotive industry or commonly referred 
to as a dealer that provides sales, repair, and sales for four-wheeled vehicle parts. The 
results of a survey conducted by JD Power 2018, Jandhagi et al. (2011) in Indonesia 
found an important finding namely low customer satisfaction caused by scheduling 
appointments via digital channels that are very low, with a percentage value of 7% of 
customers who schedule their service appointments via its website or through 
smartphone applications. An automobile service company is a service industry that 
serves sales, maintenance, repair, and supply of vehicle part services. The service 
operation branch also provides spare parts and workshops that provide special 
maintenance and repair services for vehicles. It consists of three main divisions, 
which are Sales Department, Service Department, and Spare Parts Department. The 
key element in determining the level of service quality is after-sales customer 
satisfaction. The quality of after-sales services provided by car dealers has a great 
influence on customer satisfaction to maintain long-term relationships with their 
customers and many businesses. Have changed their strategic focus to emphasize 
customer retention (Rego et al. 2013).  

The high after-sales service lead time in automobile services in Toyota dealers in 
Indonesia is 120.06 minutes in one service cycle, higher than the lead time charged at 
60 minutes. It is a problem that must be resolved so that customer satisfaction, which 
is an important attribute in the service industry can be met. By mapping the after-
sales service process in automotive services Toyota dealer using Value Stream 
Mapping, it is expected that the actual conditions of current service processes can be 
identified and found, which processes are causing the high after-sales service lead 
time that occurs. By assisting various tools of quality in the Six Sigma method, it is 
also expected to be able to provide analysis and recommendations for corrective 
actions so that the quality of service is in line with expectations and can be improved. 
It is believed that good service quality will result in customer satisfaction and will 
have an impact on the reuse of products and services that have been used and help 
improve company's image through product information and services to other 
customers (Gijo et al. 2012, Thompson, 2005, Lam et al. 2004, Venkamteswaran and 
Padmanaban, 2018).  

Six sigma is a systemic and structured method with DMAIC stages (Define, 
Measure, Analyze, Improve, and Control) that has been proven effective in identifying, 
measuring, analyzing, and providing recommendations for improvement of problems 
that occurred (Causevic & Golub, 2019). Researched at Portugal Automotive industry 
using DMAIC (Define, Measure, Analyze, Improve and Control) cycle for process 
improvement could decrease 0.98% on the indicator of work-off generated by the 
production system, the financial impact could save over 165,000 € per annum (Costa 
et al. 2017). Omar & Mustafa (2014) stated that the adoption of Six Sigma does not 
only mean a process improvement but it is a business strategy that uses a systematic 
approach to increase productivity, corporate financial benefits, and customer 



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38 
 

satisfaction (Pucheta et al. 2019). Other research in automotive that selected as 
observed machine DMAIC could reduce the machine breakdown time from 111 
became 85 minutes/month and breakdown quantity from 4.7 became 3.5 
times/month and increase the availability value from 90.8% became 96.0% and the 
impact was increasing OEE (Overall Equipment Effectiveness) value from 87% 
became 92% (Rozak et al. 2020).  

In the United Kingdom 2012, the Six Sigma method had succeeded in reducing the 
waiting time from 24 minutes to 11 minutes or more than 50% of Pathology 
Department service processes in the healthcare industry (Hussain et al. 2014). Other 
studies had also successfully revealed that the implementation of Six Sigma can 
improve the attitude of health workers better (53%), compared to government 
employees (18%) (Sethi et al. 2018). Based on the facts from previous studies, it is 
proven that the implementation of Value Stream Mapping and Six Sigma combined 
with other tools of quality successfully resolve various problems and succeeded in 
enhancing customer satisfaction and company profits.  

2. Literature Review 

Customer satisfaction is the lifeblood of every company, so customer satisfaction 
is one important element in improving the performance of a company or organization 
(Nagi & Altarazi, 2017). Customer satisfaction can be formed if the customers get 
what is expected from a product or service they use (Croft & Kovach, 2012, Pyzdek, 
2003). Customer satisfaction is a comparison between the actual performance in 
products and the expected performance (Caesaron & Simatupang, 2015). Customer 
satisfaction is a response from the comparison of product performance with several 
standards before, during, and after consumption (Minh & Huu, 2016, Srivasnavar & 
Bhatnagar, 2013, Barrios & Jimenez, 2016). Especially in the service industry, 
customer satisfaction is closely related to the level of service quality in which there is 
a direct interaction between the system, the operator, and the customer, where 
process the customer can feel directly the quality of services which at the same time 
can provide an assessment of the quality of the service without passing through other 
stages of the process. 

Service quality is the main process in the service organization/industry that 
prioritizes the achievement of service quality that meets or even exceeds customer 
expectations (Barrios & Jimenez, 2016). Other research stated that the success of 
industry without exception a service industry is very dependent on human resources 
and processes owned so that in the service industry the improvement of human 
resource competencies and continuous process improvement are important factors 
as well as determinants of the industry to gain its success (Vijay, 2014). Identification 
of ongoing process conditions including in the service industry which aims to find 
opportunities for continuous process improvement is an important activity so that 
quality of service that can meet customer expectations can be realized. Some various 
methods and tools can help identify the ongoing process to get the opportunity for 
improvement as intended. This research seeks to combine Value Stream Mapping and 
Six Sigma methods with the help of other tools of quality in identifying, measuring, 
and analyzing the processes that occur in automotive after-sales services in 
Indonesia, it is hoped that the processes currently running can be identified and 



Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive 
Services in indonesia 

 

39 
 

opportunities for improvement can be found in efforts to improve quality services 
that can meet or exceed expectations and certainly increase customer satisfaction. 

The identification of ongoing process conditions is very important in the strategy 
of quality improvement in the industrial world both in the manufacturing and service 
industries. Especially in the service industry, the quality of service that can be felt 
simultaneously in the process becomes very important to always be identified and 
evaluated quickly and effectively so that the quality of service and the image of the 
organization in customer perspectives can be maintained. Value Stream Mapping is a 
device that has been widely used by various industries including the service industry 
in identifying and analyzing the conditions of ongoing processes to find opportunities 
for further improvement. Value Stream Mapping can optimize the power sources by 
eliminating non-value of added activities to improve productivity and sense of 
competitiveness (George, 2003).  

Value Stream Mapping is a successful method that is used internationally, usually 
applied in a single project that has a high innovative impact and is developed towards 
continuous improvement with a systematic process management approach (Kuhlang 
et al. 2011). The Value Stream Mapping method has successfully identified the 
operational conditions through the study of takt time and succeeded in reducing the 
process lead time from 7.6 to 3.2 days or a 73% reduction in the automotive industry 
cycle time in India (Chang & Wang, 2007). Value Stream Mapping has also succeeded 
in identifying bottleneck processes and reducing waiting time by up to 27% (Otim & 
Grover, 2006). Referring to the various studies, it can be understood that the Value 
Stream Mapping method is very effective in identifying ongoing processes to obtain 
opportunities for improvement and can improve the productivity and quality of 
processes and products in both manufacturing and service industries. 

Six Sigma is a comprehensive, flexible and measurable system for achieving, 
maintaining, and maximizing increasingly competitive business success. Six Sigma is 
a quality improvement approach that is systematically effective for improving 
organizational performance based on the use of various statistical analysis 
techniques (Pande & Holpp, 2002). In general, Six Sigma has two meanings, namely 
Six Sigma as a philosophy for continuous improvement in reducing defective 
products and Six Sigma as a technical tool in measuring the number of defects per 1 
million products produced. Six Sigma in technical methods has a statistical. Approach 
orientation to the calculation of product defects. The goal is to reduce the variance 
process by eliminating the entire defects interfering with customer satisfaction (Peng 
& Wang, 2006). For the service industry, Six Sigma is a business improvement 
methodology that maximizes shareholder value by achieving the fastest rate of 
increase in customer satisfaction, cost, quality, processing speed, and investment 
capital (Haviana & Hernadewita, 2019).  

Six Sigma is a version, philosophy, strategy, and a set of tools to improve process 
and service quality, for services-based industries, where customer needs are the main 
focus, and their needs often seem unpredictable (Ebrahimi & Keykavossi, 2018). Six 
Sigma is a systemic and structured method with DMAIC (Define, Measure, Analyze, 
Improve, and Control) steps. It has been proven effective in identifying, measuring, 
analyzing, and providing recommendations for improvement that have a focus on 
reducing the variety of processes and products that can increase customer 
satisfaction, profitability, and competitiveness of the company (Elbireer et al. 2011, 



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54  

 

40 
 

Jona than, 2013, Trimarjoko et al. 2019). The researches showed that most service 
organizations in the UK have been implementing Six Sigma for more than three years. 
The company's average sigma quality level is around 2.8 around 98,000 Defects Per 
Million Opportunities (DPMO). Management commitment and involvement, customer 
focus and Six Sigma integration with business strategy are important factors in 
implementing Six Sigma (Syafwiratama et. al. 2016). The implementation of the Six 
Sigma method can reduce shipping delays and lead time in the small and medium 
scale industries in the United Kingdom and increase the sigma level from 1.44 to 2.09 
Sigma (Otim & Grover, 2006). The application of the Six Sigma method proves that 
the average waiting time for maternal and child hospital services decline from 6.89 
days to 4.08 days and the standard deviation dropped from 1.57 days to 1.24 days. In 
this way, the hospital will serve pregnant women faster, reducing the risk of perinatal 
and maternal death (Omar & Mustofa, 2014).  

The combination of Value Stream Mapping and Six Sigma methods can reduce the 
lead time of a delivery process at the automotive dealers in Mexico from 50,499.5 
minutes (35.06 days) to close to 30,240 minutes or even 20,160 minutes or down 
60.17% (Parasuraman & Grewal, 2000). Other research in India using Value stream 
mapping and Six Sigma methods showed that lead time has been reduced by 14.88%, 
processing time 14.71%, and waste of material movement 37.97%. As proposed in 
the model, WIP (Work In Process) inventories have decreased by 17.76% and labor 
17.64%. Furthermore, it will generate 161,800 Rupees profit per year. And get a net 
savings of 145,560 Rupees per year (Shahin, 2006). Referring to these studies, it 
shows that Six Sigma methods in the service industry combined with other methods 
are very effective in identifying, analyzing, and improving processes and products to 
get better service quality and also able to increase the profit and competitiveness of 
the industry by 37.97%. Referring to these studies, the Six Sigma method in the 
service industry combined with other methods is very effective in identifying, analyze 
and improve processes and products to get better service quality and can increase the 
profitability and competitiveness of the industry.  

3. Case Study 

Automotive Toyota dealers service in Indonesia have a problem with high after-
sales service lead time is 120.06 minutes in one service cycle, which is higher than the 
lead time charged by 60 minutes for a type of Expres Maintenance service. By 
combining Value Stream Mapping and Six Sigma based on other tools of quality, it is 
expected that the problem of high after-sales lead time in the automotive Toyota 
dealer services industry can be identified and get improvement recommendations so 
that the problem can be solved effectively and efficiently. The proposed 
implementation framework is an integrated approach of Lean and Six Sigma and is 
shown in Figure 1. It is based on the traditional five phases of the DMAIC Six Sigma 
improvement model: (Define, Measure, Analyze, Improve, and Control). Each phase of 
the DMAIC: Define, Measure, Analyze, Improve and Control methodology utilizes 
several Six Sigma tools to improve the mobile order fulfillment process. In this study, 
both qualitative and quantitative data were collected from multiple sources. 
Qualitative data were obtained from direct observations in the field and unstructured 
interviews with team leaders, experienced team members, and systems experts, while 
quantitative data were obtained from the company’s historical records. Several tools 



Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive 
Services in indonesia 

 

41 
 

and techniques, such as a Pareto chart, Value Stream Mapping (VSM), cause-and-
effect analysis, process capability analysis, a control chart, and 5W + 1H analysis, 
were used through the DMAIC (Define, Measure, Analyze, Improve and Control) 
methodology. All statistical analysis of data (at a 5% level of significance) and 
graphical presentations were performed using Minitab statistical software. 

Identification

- Scope and Objectives

- Input from Case Organization 
Literatures Review

Define (Describe the problem) :

1. Identify Critical To Quality Characteristics

2. Finalize problem description activity through Pareto Analyze

. 

Measure (Establish baseline performance) :

1. Data Collection

2. Test Normality & Exixtence of Special Cause of Variation & 

    Process Capability Analysis 

3. Four Block Diagram Current Condition

Analyze (Identify the root cause) :

Cause and Effect Analysis

Improve (Select the best solution) :

1. Further Analysis of Root Cause by 5W + 1 H

2. Establish Improvement Planning Martrix

Control (Sustain the gain) :

1. Test Normality & Exixtence of Special Cause of Variation & 

    Process Capability Analysis 

2. Four Block After Improvement

3. Evaluation Value Stream Mapping After Improvement 

3. Documentation and standardization of All Methods

4. Process Monitoring and Controling 

  Analysis Value Stream Mapping Current Condition 

Figure 1. Implementation Framework   

Value Stream Mapping has been widely used in various companies both 
manufacturing and services that are useful for knowing the condition of the ongoing 
process and very effective in knowing which of all sub-processes (workstations) are 
bottlenecks and have an impact on current problems. These conditions are termed as 
current stage conditions, while Value Stream Mapping can also be reused in mapping 
a series of processes after repairs called Future Stage conditions so that with the 
improved results Value Stream Mapping can also be identified. 



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42 
 

Receiving Binning Issuing

Reception Production Final Inspection Washing Call Customer

Sub Depot 

Regional

C/T = 542 second

Ope rat or = 8 

Distance = 0

C/T = 2067 second 

Ope rat or = 6

Distance = 30 m

C/T = 115 second 

Ope rat or = 1

Distance = 10 m

C/T = 606 second 

Ope rat or = 2

Distance = 25 m

C/T = 383 second

Ope rat or = 1 

Distance = 0 m

Total L/T

LT = 120,06 Minutes

Sparepare 

Demand/PO 

Appointment
Maintain 

Reminder 

Activity

Customer

LT=90 Minutes
L/T = 60 

Minutes

Total L/T

LT = 154 Minutes
L/T = 4 Minutes

PKB PKB PKB PKB PKB

 Service 

Process

Service 

Preparation

SPS 

C

2 Days
30 Minutes

10 Minutes

Appointment Preparation

3 Days

Waiting Time 127 second Waiting Time 2704 second Waiting Time 382 second

Waiting Time 10 

Minutes

Waiting Time 30 

Minutes

Waiting Time 5 

Minutes

Waiting Time 10 

Minutes

Waiting Time 5 

Minutes

1 Day

Waiting Time Issuing 

10 Minutes

15 Minutes

T T T T

I

LT = 2.12 Minutes 

LT = 9.04 Minutes

LT = 45.08 Minutes

LT = 34.45 Minutes

LT= 4.59 Minutes

LT = 1.92 Minutes

LT = 6.37 Minutes

LT = 10.10 Minutes LT = 6.39 Minutes

Waiting Time 275 second

Figure 2. Value Stream Mapping Current Condition 



Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive 
Services in indonesia 

 

43 
 

Figure 2 explains Value Stream Mapping (VSM) that illustrates the current 
condition of the process that is ongoing (before improvement). The condition was 
analyzed to find out which workstations were causing the high lead time. Based on 
Value Stream Mapping current condition as obtained in Figure 2, the average lead 
time process in the automotive Totota dealer services industry was a minimum of 46 
~ 65 minutes, a maximum of 263 ~ 389 minutes with an average of 120.06 minutes 
for a type of Express Maintenance service. Its condition exceeded the company's 
target of 60 minutes, using Value Stream Mapping The Value Stream Mapping for 
general description can be explained in Table 1. 

Table 1. Evaluation of the actual time of overall workstations current condition 

Order Type 
Service 

Count 
(Valid) 

Work Process (minute) Total 
Lead 
Time 

EM (Express 
Maintenance) 

 

W
a

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in

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R
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ce
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ti
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is

t 

P
ro

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ss

 
R

e
ce

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is
t 

W
a

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  S

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e

 

P
ro

ce
ss

 S
e

rv
ic

e
 

A
n

o
th

e
r 

Jo
b

 O
rd

e
r 

W
a

it
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g
 F

in
a

l 
In

sp
e

ct
io

n
 

P
ro

ce
ss

 F
in

a
l 

In
sp

e
ct

io
n

 

W
a

it
in

g
 W

a
sh

in
g

 

W
a

sh
in

g
 P

ro
ce

ss
 

C
a

ll
 C

u
st

o
m

e
r 

 

TimeActual 
Target 

Evaluation 

2.12 9.04 45.08 34.45 0.00 4.59 1.92 6.37 10.10 6.39 120.06 
0.00 10.00 0.00 30.00 0.00 0.00 5.00 0.00 10.00 5.00 60.00 

X V X X V X V X X X X 

Note : X: unable to meet the target. 

           V: able to meet the target. 

Referring to the evaluation of each workstation contained in the Express 
Maintenance (EM) process, in this case, the process of handling after-sales customer 
complaints in the automotive Toyota dealer services, the results showed that up to 
80% were not able to meet the target of the company so that the overall total lead 
time was not be fulfilled. Therefore, further analysis is needed to get the total lead 
time following the company's target. The application of the Six Sigma method is based 
on theoretical studies that had been found and had been proven effective in solving 
problems in various industries both manufacturing and service industries. Six Sigma 
with its structured stages will be used in solving the problem of high after-
sales/express maintenance lead time in the automotive. Services industry in this 
study. The Six Sigma analysis used in this study was:  

3.1. Define phase  

The define stage was the first stage. In this stage, the problem description activity 
was carried out, determining Critical to Quality (CTQ) and the target to be achieved. 
From the data collection and mapping process with Value Stream Mapping, it is 
known that the problem that occurred was the high after-sales lead time on average 
of 120.06 minutes of the specified target was 60.0 minutes. As for the data obtained, 
we floated in the Pareto diagram to find out the Critical to Quality that occurred, 
while the Pareto diagram is shown in Figure 3. Based on the Pareto diagram in Figure 
3 it explained that 80% of the longest Express Maintenance lead time was on the 
waiting service 49.15 minutes or 56%, washing process 12.27 minutes difference to 
the target or 14% and process (service) 10.45 minutes, so based on the Pareto 
diagram Critical To Quality of this research was as many as 3 types, i.e. waiting for 



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54  

 

44 
 

service, service process, and washing process. The target to be achieved in this 
research was lead maintenance Express Maintenance service time of 60.0 minutes. 

Lead Time 49,15 40,45 22,27 10,27 6,47 5,88 5,63 3,35

Percent 34,3 28,2 15,5 7,2 4,5 4,1 3,9 2,3

Cum % 34,3 62,5 78,0 85,1 89,6 93,7 97,7 100,0

Process

O
th

er

Ca
ll 
C
us

to
m

er

W
ai
tin

g 
W

as
hi
ng

Pr
oc

es
s 
Fi
na

l I
ns

pe
ct
io
n

Pr
oc

es
s 
re

ce
pt

io
ni
st

Pr
oc

es
s 
W

as
hi
ng

Pr
oc

es
s 
Se

rv
ic
e

W
ai

tin
g 

Se
rv

ic
e

160

140

120

100

80

60

40

20

0

100

80

60

40

20

0

L
e

a
d

 T
im

e

P
e

r
c
e

n
t

 

Figure 3. Pareto Diagram analysis of the Express Maintenance process 

3.2. Measure phase 

Measure phase was the second stage. In this step, the capability of the express 
maintenance process was calculated, aimed to find out the current condition of the 
process under this study. From data collection which had  been obtained, to be then 
calculated the capability of the process as follows:  

360300240180120600

LSL USL

LS L 71

Target *

U S L 210

S ample M ean 141.015

S ample N 400

S tD ev (Within) 67

S tD ev (O v erall) 67.73

P rocess D ata

Z.Bench 0,53

Z.LS L 1,04

Z.U S L 1,03

C pk 0,34

Z.Bench 0,51

Z.LS L 1,03

Z.U S L 1,02

P pk 0,34

C pm *

O v erall C apability

P otential (Within) C apability

P P M  < LS L 65000,00

P P M  > U S L 135000,00

P P M  Total 200000,00

O bserv ed P erformance

P P M  < LS L 148011,48

P P M  > U S L 151592,60

P P M  Total 299604,08

E xp. Within P erformance

P P M  < LS L 150629,60

P P M  > U S L 154213,21

P P M  Total 304842,81

E xp. O v erall P erformance

W ithin

Ov erall

 

Figure 4. The Capability Process of Z bench St Express Maintenance 



Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive 
Services in indonesia 

 

45 
 

360300240180120600

LSL USL

LS L 71

Target *

U S L 210

S ample M ean 141.015

S ample N 400

S tD ev (Within) 67.8915

S tD ev (O v erall) 67.73

P rocess D ata

Z.Bench 0,51

Z.LS L 1,03

Z.U S L 1,02

C pk 0,34

Z.Bench 0,51

Z.LS L 1,03

Z.U S L 1,02

P pk 0,34

C pm *

O v erall C apability

P otential (Within) C apability

P P M  < LS L 65000,00

P P M  > U S L 135000,00

P P M  Total 200000,00

O bserv ed P erformance

P P M  < LS L 151205,38

P P M  > U S L 154789,43

P P M  Total 305994,81

E xp. Within P erformance

P P M  < LS L 150629,60

P P M  > U S L 154213,21

P P M  Total 304842,81

E xp. O v erall P erformance

W ithin

Ov erall

 

Figure 5. The Capability Process of Z bench Lt Express Maintenance 

From the calculation of Z bench St (sigma level) and the value of Z bench Lt, it can 
be plotted into four block diagrams as an illustration of improvement direction from 
the control and technology side, by calculating Z shift with the following result from 
calculating and converting Defect Per Million Opportunity (DPMO) to sigma level 1.96 
Sigma. So that the capabilities of the running process can be plotted in the four-block 
diagrams in Figure 6, as follows. 

A

C

B

D

Control

Technology

1,5

4,5

Poor Good

Z shift

Z St

(0,34, 1.96)

5,02

 

Figure 6. Four block diagram current condition 



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46 
 

Figure 6 explains that the condition of the sigma level of the ongoing process in 
terms of control is good but in terms of technology is still very bad. So that effective 
improvement is needed to get a better sigma level. 

3.3. Analyze phase 

Referring to Value Stram Mapping Define and Measure phases It is known that the 
high lead time Express maintenance (EM) was caused by 3 processes, namely: 
waiting for service, service process, and washing service. By using the Cause-effect 
diagram, the problems of processes were analyzed to get what was the dominant 
cause of the 3 processes. The Cause-effect diagram of the problem is shown in Figure 
7 below: 

The maintenance process was caused by: 

1. Equipment Factor 

The condition of the equipment used by Express Maintenance mechanics was only 
40% in good condition and suitable for use, 24% was damaged, 7% was lacking and 
29% was missing or not yet used. Utilizing the tools which were broken and lacking 
was temporarily displaced by stalls Express Maintenance 1 and 2 tools whereas, for 
devices that did not exist, EM had not used them. They still used standard tools that 
were periodically serviced. 

2. Material Factors 

The rapidity of providing spare parts for regular service. For the procurement 
stock of spare parts, consumers still often waited due to the availability of spare 
following periodic service manuals. 

3. Management Factors 

The length of time Express Maintenance service takes place was because 
mechanical mechanics received work orders that had complaints either Express 
Maintenance booking or Express Maintenance Walk-in (direct coming). Express 
Maintenance work should have as few complaints as possible due to the distribution 
of improper mechanical task dividers for cars coming in for service and the lack of 
digging information from the booking service staff. 

4. Environmental Factors 

EM mechanics should look for cars that needed to be serviced in the service 
parking area because cars were mixed with other cars which were not included as the 
Express Maintenance (EM) service customers. Moreover, when the car park was full, 
it was placed in another parking area, making it more difficult for mechanics to find 
the cars. The fact that an indicator to search the cars was only a periodic service 
indicator without a sign or special identity of Express Maintenance also made it hard 
to identify the cars. 

 



Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive Services in indonesia 
 

47 
 

Lead Time 

Service

Used the sam e tools

Bad of procurement tools

Less of tools
Still conventional tools

Decrease of efficiency tools

Waiting for take additional parts

Standard Operation Procedur isn t done

Waiting supporting part

Mechanic missunderstanding service will need

Type of booking service and walking 

service come at the same tim e 

Search of vehicle will be service  

Parking area not organized

 

Figure 7. Cause and Effect Diagram Analysis 



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54  

 

48 
 

3.4. Improve phase 

Activities in this stage were to determine the proposed improvement of the root of 
the causes that have been carried out at the Analyze stage by conducting a 
brainstorming using 5W + 1H and the Improvement Matrix Plan of the service 
process and washing process that becomes the problem in this study. A large amount 
of lead time in services at the dealer had been found. It might likely occur due to the 
long duration of handling throughout the service process, and many 
miscommunication errors. Thus, it will be one of the main points for improvement in 
the next step of the DMAIC improvement cycle. With the following improvements: 
The improvement in the production area or service process aimed to reduce the 
service process time from the actual time before repairing 34.45 minutes while the 
expected target is 30 minutes. The improvement steps taken by the Small Group 
Activity Express Maintenance team (SGA EM) were as follows: Failure1: Provide 
Special Parking Wait Express Maintenance Service. Failure 2: Provide Parts with 
Standard Operation Procedure (SOP) Pre-Picking Rack. Failure 3: Provide Material 
with Standard Operation Procedure Pre-Picking. Failure 4: Loss of manpower with 
the addition of Man Power. By carrying out the corrective footsteps as mentioned 
above, it is expected that the high maintenance lead time of 120.06 minutes can be 
reduced to the target of 60.00 minutes per service cycle. 

3.5. Control phase 

The control stage was the last in the Six Sigma method, where this stage the 
process capability (sigma level) calculation was conducted again after the 
improvement. Observation activities as in the measuring stage were still applied. 
Sigma level could be calculated by using Minitab software that could also by 
calculating Z shift with the following result from calculating and converting Defect 
Per Million Opportunity (DPMO) to sigma level 3.80 Sigma. 

A

C

B

D

Technology

1,5

4,5

Poor

5,02

(0,36, 3.80)

Good

Control

 

Figure 8. Four block diagram after improvement 

Figure 8 shows the results of improvement in this study. It has better results than 
the conditions before the improvement. Then, to get the stability of the Express 
Maintenance process, the documentation of improvement was made into a work 



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54 
 

49 
 

standard in the form of 1. Making a Work Squance Sheet (WSS), was a written work 
procedure that was a detailed job in detail. 2. Stick Work Squance Sheet (WSS) in 
areas related to WSS attached to areas that had been improvised, placing Work 
Squance Sheet (WSS) in a location that was visible and readable by officers in their 
respective areas. 3. Socializing Work Squance Sheet (WSS) socialization and 
improvement programs were conducted when the regular All Small Group Activity 
(SGA) meetings are held every month. Also, it was socialized at the machine shop roll 
call, which was routinely held on Tuesday and Thursday. Every morning roll call, 
each Smal Group Activity can report the progress of the repairs that have been made. 
Furthermore, to find out the lead time analysis of the Express Maintenance process 
after improvement, this mapping was carried out again after the improvement using 
Value Stream Mapping in Figure 9. 

Figure 9 explains Value Stream Mapping (VSM) that illustrates condition after 
improvement process. Figures 2 and 9 Value Stream Mapping are the same, both the 
flow process and the location map, only the difference is that the results of the lead 
time have been made improvements to the work process. Value Stream Mapping 
(VSM) shows the condition of the process that is being Express Maintenance after a 
repair, as for the general description can be explained in Table 3: 

Table 3. Evaluation of the overall actual time of work stations at After Improvement 
Order Type 

Service 
Count 

(Valid) 
Work Process (minute) Total 

Lead 
Time 

EM (Express 
Maintenance) 

 

W
a

it
in

g
 R

e
ce

p
ti

o
n

is
t 

P
ro

ce
ss

 R
e

ce
p

ti
o

n
is

t 

W
a

it
in

g
  S

e
rv

ic
e

 

P
ro

ce
ss

 S
e

rv
ic

e
 

A
n

o
th

e
r 

Jo
b

 O
rd

e
r 

W
a

it
in

g
 F

in
a

l 
In

sp
e

ct
io

n
 

P
ro

ce
ss

 F
in

a
l 

In
sp

e
ct

io
n

 

W
a

it
in

g
 W

a
sh

in
g

 

W
a

sh
in

g
 P

ro
ce

ss
 

C
a

ll
 C

u
st

o
m

e
r 

 

TimeActual 
Target 
Evaluation 

1.57 7.53 13.00 23.70 0.00 3.63 1.25 5.46 3.45 4.45 64.00 
0.0 10.00 0.00 30.00 0.00 0.00 5.00 0.00 10.00 5.00 60.00 
X V X V X X V X V V  

Note : X: unable to meet the target. 

  V: able to meet the target. 

 



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54  

 

50 
 

Receiving Binning Issuing

Reception Production Final Inspection Washing Call Customer

Sub Depot 

Regional

C/T = 454 second

Ope rat or = 2 

C/T = 1422 second 

Ope rat or = 5

C/T = 75 second 

Ope rat or = 1

C/T = 207 second 

Ope rat or = 4

C/T = 267 second

Ope rat or = 1 

Total L/T

LT = 64 Minutes

Sparepare 

Demand/PO 

Appointment
Maintain 

Reminder 

Activity

Customer

LT=90 Minutes
L/T = 60 

Minutes

Total L/T

LT = 154 Minutes
L/T = 4 Minutes

PKB PKB PKB PKB PKB

 Service 

Process

Service 

Preparation

SPS 

C

2 Days
30 Minutes

10 Minutes

Appointment Preparation

3 Days

Waiting Time 10 

Minutes

Waiting Time 30 

Minutes

Waiting Time 5 

Minutes

Waiting Time 10 

Minutes

Waiting Time 5 

Minutes

1 Day

15 Minutes

T T T T

I

LT = 1.57 Minutes 

LT = 7.53 Minutes LT = 1.25 Minutes

LT= 3.63 Minutes

LT = 23.70 Minutes

LT = 13.00 Minutes LT = 5.46 Minutes

LT = 3.45 Minutes LT = 4.45 Minutes

 

Figure 9. Value Stream Mapping After Improvement



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54 
 

51 
 

Table 3. Evaluation of the overall actual time of work stations at future conditions. 
Based on the results of the Current Stream Mapping mapping, three dominant factors 
are causing the Express Maintenance service duration of the vehicle flow, namely: 
waiting service 13.00 minutes, washing process 3.45 minutes, and service process 
23.70 minutes with an average completion process reaching 64 minutes. The state 
map after improvement was created to show the condition after repair. 
Improvements in processing time and waiting time resulted from the dominant 
length of work for the Express Maintenance service, namely the washing process, 
service process, and cycle time service. The improvement state map that has been 
created will be a reference for the current state map which requires corrective action 
to achieve the next future. All of this is done continuously to achieve the ideal 
conditions of Express Maintenance services.  

4. Result 

The combination of Value Stream Mapping and Six Sigma used in this study 
proved effective and succeeded in reducing the lead time of Express Entertainment 
services in the automotive services in Toyota dealer. That would be seen by 
reviewing the results of the comparison of the Four Block Diagrams, before and after 
improvements to the car service that can experience an increase in terms of 
technology. Thus, it means resolving the problem using the Define, Measure, Analyze, 
Improve and Control (DMAIC) method in the automobile Totota dealer service 
succeeded in increasing the process capability from 1.96 to 3.80 sigma, mapping 
process using Value Stream Mapping analysis was seen to be able to reduce the 
length of service time and waiting time of each process in the car service with a total 
lead time to 64.0 minutes from 120.06 minutes or can reduce the Express 
Maintenance service lead time by 53%. 

5. Conclusion 

This study aims to improve car dealer services by reducing the Express 
Maintenance lead time in the automobile Toyta dealer services. For this reason, it is 
necessary to know the stages of the process that results in dealer service issues 
ranging from acceptance to submission back to the customer and can be analyzed and 
prevented from occurring problems. Value Stream Mapping helps to define key 
process stages to make improvements to the problems that occur in each stage of the 
process. This research uses an integrated Value Stream Mapping (VSM) and Six Sigma 
mechanism that tries to unravel the problem that is happening the Express 
Maintenance service in the automotive Toyota dealer services industry in Indonesia, 
namely a high lead time of 120.06 minutes from the management target of 60.00 
minutes. By assisting the Value Stream Mapping method, it was able to identify which 
part of the series of processes caused the problem and managed to find out the total 
lead time that was running at 120.06 minutes and after repairing the value stream it 
was also found that the total lead time Express Maintenance decreased to 64.00. Six 
Sigma method with DMAIC (Define, Measure, Analyze, Improve and Control) steps 
were also carried out in this study with the help of other tools of quality such as 
Pareto diagrams, process capability with four block diagrams, Cause-Effect diagram 
analysis of 5W + 1H also and succeeded in measuring, analyzing, repairing and 



Fathurohman et al./Oper. Res. Eng. Sci. Theor. Appl. 4 (2) (2021) 36-54  

 

52 
 

controlling the process of Express Maintenance so that total lead time of the process 
can be derived as above and can raise the sigma level of the Express Maintenance 
process from 1.96 sigma to 3.80 sigma. In general, Value Stream Mapping and Six 
Sigma methods in this study reinforce previous studies, namely increasing sigma 
level, which is marked by decreasing total lead time Express Maintenance so that the 
quality of service can be improved to get customer satisfaction, increase company 
profitability, increase the competitiveness of companies in maintaining the 
sustainability of the industry in the future. 

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	Value Stream Mapping and Six Sigma Methods to Improve Service Quality at Automotive Services in indonesia
	Dimas Mukhlis Hidayat Fathurohman 1, Humiras Hardi Purba 1, Aris Trimarjoko 2*
	1. Introduction
	2. Literature Review
	3. Case Study
	Note : X: unable to meet the target.
	V: able to meet the target.
	3.1. Define phase
	3.2. Measure phase
	3.3. Analyze phase
	3.4. Improve phase
	3.5. Control phase
	Note : X: unable to meet the target.
	V: able to meet the target.

	4. Result
	5. Conclusion
	References