In recent time, becoming green is not only a matter of compliance with regulations, however it is a matter of responding to the expectations and demands of our world, country, community, stockholders, customers, employees and competitors. These matters create tremendous pressure for companies to carry out their activities in a more environmental friendly.

Being green requires the best engineering minds and commitment from the entire organization. Engineering is all  about  practicality  finding  solutions  to  improve  the

conditions. Excellent understanding of the fundamental engineering  is  a  key  to  helping  industrial  activities  to

become greener and the engineers are in an ideal position to contribute in these activities, in term of development and

implementation of technologically sound, as well as cost- effective solutions.

Green initiatives create big business opportunities in the order of trillions of dollars for innovative companies and engineers,  in  this  decade.  These  business  activities  are

started from research and development, plant design, plant construction and plant operation stage. This paper presents some ideas on how to implement the green concept in engineering  activities.  The  case  studies  application  of

Nair, Sukumaran, “What are the strategies for sustainable chemical production”, Hydrocarbon Proc., Jan. 2011, pp. 69–

Ottewell, Sean, “Sustainability Sustains its Appeal”, Chem.

Proc., Nov. 2009, pp. 21–24.

Ottewell, Sean, “A Different Plant Appears on the Horizon”, Chem. Proc., Aug. 2009, pp.14–18.

Hall, Nina et al, “The New Chemistry,” Cambridge University

Press, 2000.

Bravo, Fabio, others, “Wisely Use Emergency Scrubbers with

Vent Systems”, Chem. Eng. Prog., Aug. 1997, pp. 62–68.

“Separation Technologies for the Industries of the Future” Publication NMAB-487-3, National Academy Press, Washington, D.C., 1998.

Tracking Industrial Energy Efficiency and CO2 Emissions.

Paris, France: International Energy Agency, 2007.

Energy Information Administration, "Annual Energy Outlook

," U.S. Department of Energy 2012.

R. Smith, Chemical process design and integration: Wiley

New York, 2005.

A. L. Querzoli, A. F. A. Hoadley, and T. E. S. Dyson, "Identification of heat integration retrofit opportunities for crude distillation and residue cracking units," Korean Journal of Chemical Engineering, vol. 20, pp. 635-641, 2003.

J. Rehman Khan and S. M. Zubair, "A risk based performance

evaluation of plate-and-frame heat exchangers," Heat and

Mass Transfer, vol. 39, pp. 327-336, 2003.

T. R. Bott, Fouling of Heat Exchangers. Amsterdam: Elsevier

Science & Technology Books, 1995.

F. Smaïli, V. S. Vassiliadis, and D. I. Wilson, "Mitigation of fouling in refinery heat exchanger networks by optimal management of cleaning," Energy & Fuels, vol. 15, pp. 1038-

, 2001.

K. Brodowicz and M. Markowski, "Calculation of heat exchanger networks for limiting fouling effects in the petrochemical industry," Applied Thermal Engineering, vol.

, pp. 2241-2253, 2003.

C. Riverol and V. Napolitano, "Estimation of fouling in a plate heat exchanger through the application on neural networks," Journal of Chemical Technology and Biotechnology, vol. 80, pp. 594-600, 2005.

L. M. Romeo and R. Gareta, "Hybrid System for fouling control in biomass boilers," Engineering Applications of Artificial Intelligence, vol. 19, pp. 915-925, 2006.

F. Smaïli, D. K. Angadi, C. M. Hatch, and O. Herbert,

"Optimization of scheduling of cleaning in heat exchanger networks subject to fouling: sugar industry case study," Food and Bioproducts Processing, vol. 77, pp. 159-164, 1999.

S. Macchietto, G. F. Hewitt, F. Coletti, B. D. Crittenden, D. R.

Dugwell, A. Galindo, G. Jackson, R. Kandiyoti, S. G. Kazarian, and P. F. Luckham, "Fouling in crude oil preheat trains: a systematic solution to an old problem," in Heat Transfer Engineering, 2009, pp. 197-215.

ESDU, "Heat exchanger fouling in the preheat train of a crude oil distillation unit," ESDU, London 2000.

B. L. Yeap, "Design of heat exchanger networks with fouling

mitigation," in CGPS dissertation: University of Cambridge, UK, 2001.

B. L. Yeap, D. I. Wilson, G. T. Polley, and S. J. Pugh,

"Mitigation of crude oil refinery heat exchanger fouling through retrofits based on thermo-hydraulic fouling models," Chemical Engineering Research and Design, vol. 82, pp. 53-

, 2004.

B. L. Yeap, D. I. Wilson, G. T. Polley, and S. J. Pugh, "Retrofitting crude oil refinery heat exchanger networks to minimize fouling while maximizing heat recovery," Heat Transfer Engineering, vol. 26, pp. 23-34, 2005.

W. Ebert and C. B. Panchal, "Analysis of Exxon crude-oil-slip

stream coking data," Fouling mitigation of industrial heat exchangers, San Luis Ebispo, CA (United States), 18-23 Jun

, 1995.

W. L. Van Nostrand, S. H. Leach, and J. L. Haluska, "Economic penalties associated with the fouling of refinery heat transfer equipment," Fouling of heat transfer equipment, pp. 619-643, 1981.

S. H. Leach and S. A. Factor, "Monitoring fouling in refinery and petrochemical plant heat exchange equipment," in 20th National Heat Transfer Conference. ASME, 1981, p. 39.

D. Lawler, "Fouling of Crude Oil in Refinery Heat Exchangers," in Proceeding of the Conference on Fouling, Science or Art, The Institute of Chemical Engineers UK, 1979.

B. Garrett-Price, "Fouling of Heat Exchangers: Characteristics, Costs, Prevention, Control and Removal," Noyes Publications,

, p. 417, 1985.

S. Sanaye and B. Niroomand, "Simulation of heat exchanger network (HEN) and planning the optimum cleaning schedule," Energy Conversion and Management, vol. 48, pp. 1450-1461,

J. Chenoweth, "Final report of the HTRI/TEMA joint committee to review the fouling section of the TEMA standards," Heat Transfer Engineering, vol. 11, pp. 73-107,

M. C. Georgiadis, L. G. Papageorgiou, and S. Macchietto, "Optimal cyclic cleaning scheduling in heat exchanger networks under fouling," Computers & Chemical Engineering, vol. 23, pp. S203-S206, 1999.

Totok R.Biyanto, ‘Algoritma Genetika untuk Mengoptimasi Penjadualan Pembersihan Jaringan Penukar Panas’, Jurnal Teknik Industri, Vol. 17, No. 1, Juni 2015

Van Oss HG, Padovani AC. Cement Manufacture and The

Environment, Part I: Chemistry & Technology, Journal of Industrial Ecology 2000; 6: 89-105.

Van Oss HG, Padovani AC. Cement Manufacture and The

Environment, Part II: Environmental Challenges and

Opportunities, Journal of Industrial Ecology 2003;7: 93-126.

GERIAP, Company Toolkit for Energy Efficiency, Industry

Sectors – Cement, 2005. http://www.energyefficiencyasia.org/docs/IndustrySectorsCem

ent_draftMay05.pdf, Accessed on May 10, 2012.

ITS Kemitraan, Study Evaluasi Waste Heat Power Generator

Dari Exit Gas Raw Mill Dan Cooler, Project Report, 2013.