International Journal of Engineering Materials and Manufacture (2021) 6(2) 95-101 

https://doi.org/10.26776/ijemm.06.02.2021.02 

 

N. Abidah
1
, M. Hazza

2
   

1
Department of Manufacturing and Materials Engineering  

International Islamic University Malaysia 

PO Box 10, 50728 Kuala Lumpur, Malaysia 

2
Mechanical and Industrial Engineering Department 

School of Engineering, American University of Ras Al Khaimah 

United Arab Emirates 

E-mail: muataz.alhazza@aurak.ac.ae 

 

Reference: N. Abidah and M. Hazza (2021). Influence of Buffer Size Change in Critical Chain Scheduling: Case Study. International 

Journal of Engineering Materials and Manufacture, 6(2), 95-101. 

 

 

Influence of Buffer Size Change in Critical Chain Scheduling: Case Study 

 

 

N. Abidah and M.H. Al Hazza 

 

 

Received: 17 Martch 2021 

Accepted: 04 April 2021 

Published: 15 April 2021 

Publisher: Deer Hill Publications 

© 2021 The Author(s) 

Creative Commons: CC BY 4.0 

 

 

ABSTRACT 

Performing the Critical Chain Scheduling (CCS) and Buffer Management (BM) in project management has recently 

risen as one of the most popular project management approaches. The critical Chain Scheduling (CCS) approach is 

replacing the traditional scheduling method to reduce the uncertainty associated with time schedules. The research 

highlights the importance of critical chain scheduling in project execution by investigating using buffers in the critical 

paths and the feeding baths in project management using a real case study. The case study was studied by analyzing 

the schedule provided and then implementing CCS and BM using four different methods. The methods are cut and 

paste (C&PM), the root square method (RSEM), the Adaptive procedure with resource tightness, and the Adaptive 

procedure with network density (APND). The buffer size obtained for each method was determined. From the result 

got, for project buffer in adaptive approach with network density method yields a larger buffer size compared to the 

adaptive procedure with resource tightness method. While for feeding buffer also show that APND resulted in a 

larger buffer size than APRT. Finally, the proposed buffer size was investigated and simulated using the What if 

approach. 

Keywords: Project management, Critical chain, Buffer, Buffer sizing. 

 

1 INTRODUCTION 

The project manager's leading role is to achieve the project objectives on time within the budget. One of the 

challenges of this role is the critical activities with zero or low time tolerances. The project activities in the critical 

chain are the activities that have zero lead time. These dependent activities and activities close to the critical chain 

with low lead time need to be managed effectively and beneficially because any delay in those activities will delay 

the project completion time. From 1956 until 1997, project managers used two main scheduling tools: The critical 

Path Method (CPM) and the project management review technique (PERT). CPM was developed from 1956 to 1958 

by DuPont de Nemours and Company in conjunction with the Univac Applications Research Center of Remington 

Rand [1]. In 1957, PERT was developed by the U.S. Navy Special Projects Office on the Polaris missile system to 

support the nuclear submarine projects [2]. CPM is based on focusing on the float or the time each activity can delay 

without affecting the project's total completion time. However, PERT is considering the probability of finishing the 

project on time scheduled. Finally, PERT and CPM integrated to take both methods' advantages to be valuable tools 

and techniques in project scheduling named CPM/PERT. In 1997, a new improvement was introduced by Goldratt 

1997 [3], known as critical chain project management (CCPM). The fundamental principle of CCPM is by using the 

critical chain instead of the critical path [4]. Leach [5] said that CCPM is improving by aggregating the uncertainties 

at the end of paths that protect the overall project completion on the critical chain path and protect the feeding 

buffers by protecting the critical chain from path merging. However, the critical chain technique for overcoming 

uncertainty in a project offers that buffers are added at the end of the critical chain and feed chains [6]. 

Zhao et al. [4] proposed improving a two-stage approach focusing on the feeding buffer. They suggest solving 

the conflict that may happen. The precedence conflict or source conflict can be solved by rescheduling that will lead 

to a noncritical chain that may start earlier than a critical chain in critical chain activities. Bhattacharjee [7] lists the 

benefit of applying critical chain scheduling (CCS) instead of the Critical Path Method (CPM) or PERT. Firstly, avoid 



Influence of Buffer Size Change in Critical Chain Scheduling: Case Study 

96 

uncertainties that may occur within the project duration. The due dateline for each activity is not fixed and emphasizes 

the project's completion date. Secondly, more assured activity duration estimation– two measures, which are realistic 

90% confidence and aggressive estimation 50 % confidence. Aggressive activity estimation is used in CCS to avoid 

excessive activity's working time. Thirdly, if the schedule completion date of 50% estimation is not met, it will protect 

the project. Reduce the bottleneck's impact in the schedule-feeding buffer to protect the critical chain from variation 

in the noncritical chain. 

In another paper, Chuan & Gershwing [8] share the buffering concept in manufacturing to ensure the production 

line runs smoothly by maintaining enough supplies even if there are variations or fluctuations in the production 

process or demand chain, production capacities, and lead time. Buffer often supplies the raw material and inventories 

of the finished products waiting for the shipment. For instance, if there is a delay in suppliers' lead time, the raw 

material buffer can compensate the shortage for the following production process. Thus, this can contribute to the 

minimization of loss and can maximize the efficiency of the process. According to Büchmann [9], the buffers can be 

material buffers, resource buffers, equipment buffers, or some entity to protect the production flow. However, this 

is limited to study about time buffer in the project schedule. In his paper, Büchmann stated there two types of time 

buffer for scheduling: 

a) Activity buffers: applied to each activity in the schedule to protect the variability in production, such as 

incidents and fluctuation in demand. 

b) Stage buffer – to protect unexpected occasions that might happen between activities. 

 

Thus, to prevent delays happen, the buffers are allocated to a specific position with different functions. Categories of 

the buffers are divided into three types that according to their positions. Project buffer is the time buffer added to 

the end of the chain to protect project delivery time. Feeding buffers is the time buffer allocated at every noncritical 

path and feed the critical chain to prevent the slack on a critical task. Lastly, Resource buffers are the alert used to 

indicate that the resource is needed to perform an activity. Project buffer plays the most crucial role in production 

scheduling. As it is located at the end of critical path, the project buffer size affects most the whole project's duration, 

so the project buffer must be determined reasonably. As a result, determining the buffer size is a crucial for project 

success. Tukel et al., [10] addressed five different simulation methods for determining feeding buffer sizes in CCS: cut 

and paste method, root square error method, adaptive procedure with resource tightness, adaptive procedure with 

density, and adaptive procedure with resource tightness.  

 

2 CASE STUDY 

The case study is named 'Schedule the Chocolate production for XYZ brand. The project network diagram is presented 

in figure 1, representing the project activities according to their precedence, duration, and resources. The activity 

durations are shown in days while the respective resources are presented in the alphabet. The renewable resource 

required to perform the activity is identified as A, B, C, D, E, and F at the respective nodes. The availability of each 

resource is different is A, B, C, D E, F, and G availability is one 

In applying a critical chain, each task's duration must be estimated almost to half of the expected duration. The 

schedule duration shortened after the activity duration is estimated aggressively. From 196 days of project duration, 

the time was reduced to 99 days only. The critical chain also can be identified as the longest chain. In Figure 2, the 

red box indicates the chain of critical activities. 

 

 

 

 

Figure 1: Project network   



Abidah  and Muataz (2021): International Journal of Engineering Materials and Manufacture, 6(2), 95-101 

97 

Project critical chain consists of the sequences of task 1-2-3-8-9-11-14-16-19-21-22-23-24-25, and the essential length 

of the chain is equal to 99 days. Project buffer is placed at the end of the critical chain. While feeding buffer is placed 

at the end of the noncritical chain that feeds to the critical chain. Figure 3 shows the buffer in a blue box. There are 

3 feeding buffers, and 1 project buffer are placed. Using the data in Table 1, the calculation is being done using two 

method of calculation. 

 

 

 

 

 

Figure 2: Critical chain 

 

 

 

 

 

Figure 3: Buffer location 

  



Influence of Buffer Size Change in Critical Chain Scheduling: Case Study 

98 

Table 1: Project data 

 

Activity Normal duration Aggressive duration Differences 50% of differences 

1 14 7 7 3.5 

2 14 7 7 3.5 

3 28 14 14 7 

4 21 11 10 5 

5 7 4 3 1.5 

6 21 11 10 5 

7 7 4 3 1.5 

8 14 7 7 3.5 

9 14 7 7 3.5 

10 7 4 3 1.5 

11 14 7 7 3.5 

12 14 7 7 3.5 

13 14 7 7 3.5 

14 14 7 7 3.5 

15 7 4 3 1.5 

16 7 4 3 1.5 

17 7 4 3 1.5 

18 7 4 3 1.5 

19 14 7 7 3.5 

20 14 7 7 3.5 

21 14 7 7 3.5 

22 14 7 7 3.5 

23 7 4 3 1.5 

24 14 7 7 3.5 

25 14 7 7 3.5 

 

 

3 RESULTS AND DISCUSSIONS 

The calculation for each buffer size method is started by calculating the standard deviation. The standard deviation 

for each activity is computed by 50% of the difference between normal duration and aggressive estimation (D). 

Then, the buffer size can be calculated using equation 1. Where K(scale parameter) is different based on Adaptive 

procedure with network density method  or Adaptive approach with resource tightness. 

 

        (1) 

       (2) 

      (3) 

 

 

After calculation, the buffer sizes of each method are listed below 

 

1. Adaptive procedure with network density 

Project buffer 1-2-3-8-9-13-14-16-19-21-22-23-24-25 = (1.9) (13.72) = 26 days 

Feeding buffer 6-10-17-18 = (1.75) (5.63) = 9 days 

Feeding buffer 7-17-18 = (1.6) (2.59) = 4 days 

Feeding buffer 5-11-12-15 = (1.75) (6.24) = 10. ays 

Feeding buffer 5-11-20 = 8 days 

 

2. Adaptive procedure with resource tightness 

Project buffer 1-2-3-8-9-13-14-16-19-21-22-23-24-25 = (1.9) (13.72) = 20 days 

Feeding buffer 6-10-17-18 = (1.75) (5.63) = 9 days 

Feeding buffer 7-17-18 = (1.6) (2.59) = 4 days 

Feeding buffer 5-11-12-15 = (1.75) (6.24) = 8 days 

Feeding buffer 5-11-20 = 7 days 

  



Abidah  and Muataz (2021): International Journal of Engineering Materials and Manufacture, 6(2), 95-101 

99 

The buffer size obtained for each method is summarized in the table below. From the result got, For project buffer, 

the Adaptive procedure with network density method yields a larger buffer size than the adaptive approach with the 

resource tightness method. While for feeding buffer also show that APND resulted in a larger buffer size than APRT. 

The project buffer is placed at the end of the critical chain and resulted in additional 26 days. The 26 days is the time 

buffer to cope with any delays that might happen in the schedule. The yellow box indicated the buffer. The project 

buffer is placed at the end of the critical chain and resulted to additional 20 days. The 20 days is the time buffer to 

cope with any delays might happen in schedule. 

 

 

Table 2: Buffer size result 

 

Method P.B. F.B. 7-17-18 F.B. 5-11-20 FB 5-11-12-15 FB 6-10-17-18 

Adaptive procedure 

network density 
26 4 8 10 9 

Adaptive procedure 

resource tightness 
20 4 7 8 9 

 

 

 

Figure 4: Buffer (APND 

 

 

 

Figure 5: Buffer (APRT) 

  



Influence of Buffer Size Change in Critical Chain Scheduling: Case Study 

100 

Table 3: Result of simulation 

 

Remaining duration Project completion (%) Buffer penetration 

0 100% -380.77% 

12 87.88% -334.62% 

30 69.70% -265.38% 

60 39.39% -150% 

120 -21.21% 80.77% 

 

 

From the figure above, the differences between overall duration can be seen. The duration of the project using 

adaptive procedure with network density method is longer than adaptive procedure with resource tightness. A 

simulation that considers the possible scenario might happen in the project can evaluate the critical chain schedule. A 

project manager can determine the health of buffer or buffer consumption in the project schedule by using the What-

if simulation. The simulation to calculate buffer penetration is being done. The project manager reviewed the project 

progress on the fifth day of project execution. First, the project manager predicts that based on the planned project 

schedule. If the remaining duration to complete the project is 12 days left, the project is completed by 87.88 % and 

penetrates the time buffer at -334.62. The negative sign indicates that the buffer is not consumed yet. So the project 

is at no risk of being delayed and contrasted with estimating the remaining 120 days. In reviewing some uncertainty 

and problem might happen, the project manager estimate that the remaining days or possibility to complete the 

project is 120 days. So the project acts to be delayed and consume 80.77% of a time buffer. A negative sign of 

percentage of project completion shows that the project is delayed for 21 days. So the project finishes 21 days of 26 

allocated project time buffer. Table 4 shows the result of the simulation generated from Microsoft excel. 

 

After implementing and applying all necessary steps for the critical chain and buffer approach method, it is now 

possible to conclude which buffer location and sizing method should be proposed in the project. In selecting the 

buffer, the size method is depending on how risk-averse the project manager is. If the project manager is a risk-seeker 

who prefers a more extended deadline, an Adaptive procedure with a network density method is suggested to 

determine the buffer size as the APND yields a larger time buffer than Adaptive procedure with the resource tightness 

method. The buffer size generated from the adaptive procedure with resource tightness is preferable to high risk 

seeker. High risk seeker is the project manager who is planning to be competitive to finish the project earlier. 

 

4 CONCLUSIONS 

The actual life case study acquired from a local company is the project for production schedule being studied to apply 

the critical chain approach. Starting from review the provided schedule, the critical chain approach is implemented 

to the schedule and buffer management. There are six steps to be followed to achieve the aim of implementation.  

The results of each buffer sizing method are compared to select the suitable buffer size in the schedule. Due to lack 

of professional software to simulate and validate the efficiency of buffer size. Using Microsoft Project, one of the 

tools in project management, we can monitor the project. The Microsoft project feature such as Tracking Gantt, 

Report in progress, and resource overview assists the project manager. To simulate how buffer effect the schedule, 

the What-If concept simulation is designed using Microsoft excel. This simulation can help the project manager 

identify the project completion percentage and buffer penetration in the project schedule. A fever chart is also a tool 

used to check the time buffer's health in the schedule. 

 

ACKNOWLEDGEMENT 

The authors would like to acknowledge that the work have been conducted in the Department of Manufacturing 

and Materials Engineering, International Islamic University Malaysia. The authors are grateful to those who 

contributed directly and indirectly in producing this paper. 

 

 

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of Operations Research, 285(1), 67-95. 

5. Leach, L. P. (1999). Critical chain project management improves project performance. Project Management 

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