Energy and Power Engineering
Vol.08 No.11(2016), Article ID:72186,22 pages
10.4236/epe.2016.811030

The Impact of Optimum Insulation Thickness of External Walls to Energy Saving and Emissions of CO2 and SO2 for Turkey Different Climate Regions

Ö. Altan Dombayci1*, Harun Kemal Ozturk2, Öner Atalay3, Şengül Güven Acar3, Eylem Yilmaz Ulu3

1Faculty of Technology, Pamukkale University, Denizli, Turkey

2Department of Mechanical Engineering, Faculty of Engineering, Pamukkale University, Denizli, Turkey

3Sarayköy Vocational High School, Pamukkale University, Denizli, Turkey

Copyright © 2016 by authors and Scientific Research Publishing Inc.

This work is licensed under the Creative Commons Attribution International License (CC BY 4.0).

http://creativecommons.org/licenses/by/4.0/

Received: October 23, 2016; Accepted: November 20, 2016; Published: November 23, 2016

ABSTRACT

In this study, the optimum insulation thickness of the external walls of the housing and it’s energy saving and environmental impact in the provinces―Ardahan, Aydın, Eskişehir and Samsun―located in four different climate regions of Turkey was calculated for the expanded polystyrene and polyurethane insulation materials. Natural gas and coal were selected as fuels. Ardahan in the coldest climate region and Aydın in the hottest climate region, for the coal and optimum thickness of expanded polystyrene and polyurethane insulation materials, the reduction of CO2 and SO2 emissions. In the study, the relations between annual energy cost saving and insulation thickness are given. The value of energy cost saving increases up to optimum insulation thickness and beyond this level, the energy cost saving is decreased. For coal and optimum thickness of expanded polystyrene and polyurethane insulation materials, the energy cost savings was higher for the cold climate regions when it was compared with the hot climate regions.

Keywords:

Optimum Insulation Thickness, Energy Saving, Environmental Impact

1. Introduction

Energy, because of the world’s population and standard of living with constant increase, has become an important resource and power. Continuously and cheap supply of energy is insurance for the economic and social development [1] . The increment of the population, globalization of the world, improvement in technology and the increment of the welfare level causes to increase of energy use of goods and services. One of the easiest ways to employ the growing demand was to utilize fossil fuel sources. However, due to the limited amount of fossil fuels, increase of the energy price, environmental problems and global warming, it is important to use energy efficiently [2] [3] [4] .

The area of Turkey is 783,502 km2. Turkey is located at the meeting point of three continents―Asia, Europe and Africa. Turkey can be considered a natural bridge between West and East or Europe and Asia [5] According to the data of Ministry of Energy and Natural Resources (MENR), total energy consumption in Turkey in 2013 was 120.3 Million Tons of Oil Equivalent (MTOE). The total energy demand in Turkey increased 127% from in 1990 to 2013. In 2013, imported primary energy supply was 75.5%. Currently, primary energy demand in Turkey is met by natural gas (31.3%), oil (28.2%), hard coal (14.7%) and lignite (11%). Turkey imports nearly 98% of the natural gas and 93% of the oil it consumes and coal import of Turkey increases steadily [6] .

Generally, major energy end-use sectors are commercial, industrial transportation and residential. In many countries, the highest energy was consumed in residential sectors. Energy consumption for the space heating is about two times higher than domestic hot water, cooking, refrigeration, cooling etc. for residential sector. It is possible to significantly reduce the energy consumption with the insulation of the housing [7] .

Insulation is the most important part of energy efficiency all over the world. The aim of the TS825 “Thermal Insulation Requirements for Buildings” is to decrease the energy consumption of space heating for the residential sector. This may help the energy saving and reducing CO2 and SO2 emissions [8] [9] .

According to the International Energy Agency energy indicators in 2008, per capita primary energy consumption worldwide average of 1.83 of oil equivalent (toe/person) and the OECD average of 4.56 toe/person. In 2009, the energy-related greenhouse gas emission per person was 3.7 tons of carbon dioxide (CO2) equivalent. In the same period, per capita emission was 10.6 tons of CO2 equivalent/personfor the OECD, 5.1 tons of CO2 equivalent/person for non-OECD Europeand average of 4.4 tons of CO2 equivalent/person for the world. Turkey’s total greenhouse gas emissions in 1990 amounted to about 187 million tons of CO2 equivalent, while this value in 2009 amounted to about 370 million tons of CO2 equivalent. Total sectoral distribution of emissions: energy 278.33 Mton CO2 equivalent (75.3%), Waste 33.93 Mtoe of CO2 equivalent (9.2%), industrial processes 31.69 Mtoe of CO2 equivalent (8.6%) and agriculture 25.7 Mtoe of CO2 equivalents (7%) [10] .

Calculation of optimum insulation thickness of external walls of housing by using Life-Cycle Cost was discussed by Refs [11] - [33] . Çomaklı and Yüksel [34] selected Erzurum province of Turkey to analyze the optimum insulation thickness, fuel consumption and emission of CO2. This analysis showed that CO2 emissions amount decreased 50% by using optimum insulation thickness.

The purpose of this study is to determine the optimum insulation thickness of the external walls of the housing and it’s energy saving, fuel consumption and environmental impact in the provinces―Ardahan, Aydın, Eskişehir and Samsun―located in four different climate regions of Turkey by using Life Cycle Cost Analysis (LCA) method. Expanded polystyrene and polyurethane were selected as insulation materials and natural gas and coal were selected as fuels. The geographic location of these provinces has been given in Figure 1.

2. Material and Methods

The amount of heat lost from the unit external wall surfaces of houses in selected provinces and the annual fuel consumption due to the heat loss for natural gas and coal as fuel were calculated. The optimum insulation thickness by using LCA method and the emissions of CO2 and SO2 from fuel combustion equations of chemical formulas were calculated for each province.

The external wall structure which is used in the calculations has been shown in Figure 2. As seen from the figure, the external wall also called as the “sandwich wall”, consists of 2 cm inner plaster, two 8.5 cm horizontal hollow bricks and 3 cm exterior plaster and insulation material.

The Life Cycle Cost Analysis (LCA) for a project or piece of equipment is the most

Figure 1. The geographic location of selected provinces.

Figure 2. The model of external wall.

commonly method used to assess the economic benefits of energy conservation projects over their lifetime [39] [40] . The parameters of calculation are given in Table 1.

Heat loss from unit external wall surface,

(1)

where, U is coefficient of heat transfer. In the heating season, the annual heat loss from unit external wall surface and the annual energy demand which is depends on this heat loss are calculated by using heating degree day numbers (HDD) [36] ,

(2)

(3)

for the typically wall given by,

(4)

where, and the thermal resistance of interior and exterior air film respectively and, the thermal resistance of non-insulated wall layers.

The thermal resistance of insulation material given by,

(5)

Table 1. Parameters used in calculations of optimum thickness.

where and are the thickness and thermal conductivity of insulation materials respectively.

(6)

The annual energy consumption (kJ/m2∙year),

(7)

Annual fuel consumption (kg/m2∙year),

(8)

where, annual fuel consumption, HDD, heating degree day numbers, Rwt, thermal resistance of the external wall insulation material excluding and Hu, the lower calorific value of the fuel. The total cost from LCA method [8] [36] ,

(9)

where, PWF is the present worth factor, is the total cost, Cins is the unit insulation material cost ($/m3), is the unit fuel cost ($/kg) and x is insulation thickness (m).

The total cost of the derivative based on insulation thickness by equalizing to zero, the optimum insulation thickness is calculated [41] .

(10)

and,

(11)

The optimum insulation thickness is obtained from (11) equation.

Energy cost saving ($/m2∙year) [36] ,

(12)

where, and, the total energy costs for non-insulated and insulated walls respectively.

Assuming the complete combustion, the chemical reactions for annual n kmole fuel consumption and the parameters in Table 2 by using.

For coal,

Table 2. Chemical formulas and boiler efficiency of fuels used in calculations.

For natural gas,

Mol number n,

(13)

M is molecular mass of fuel. The molecular mass of coal and natural gas used in calculations 94.874 ve 17.452 kg/kmol respectively.

The annual emissions of CO2 and SO2 by combustion coal [9] [33] ,

(14)

(15)

There is no sulfur in the chemical composition of the natural gas, the emission of CO2,

(16)

and are emissions of CO2 ve SO2 (kg/m2∙year), andare molecular mass of CO2 ve SO2 (44 ve 64 kg/kmol) respectively.

3. Results and Discussion

In this study, the optimum insulation thickness and it’s energy saving and environmental impact of the external wall of the housing in the provinces―Ardahan, Aydın, Eskişehir and Samsun―located in four different climate regions of Turkey was calculated for the expanded polystyrene and polyurethane insulation materials. Naturalgas and coal were selected as fuels. Although reduced heat loss from walls in the houses with increasing thickness of the insulation material, the insulation cost is higher. As seen in Figures 3-18, total cost which is the sum of fuel cost and insulation cost decreases up to specific valufe of the insulation thickness and then the total cost is increased. The value of optimum insulation thickness that corresponding to the minimum total cost value. For coal and expanded polystyrene insulation material, optimal

Figure 3. Annual cost versus insulation thickness for expanded polystyrene insulation material for Aydın.

Figure 4. Annual cost versus insulation thickness for polyurethane insulation material for Aydın.

Figure 5. Annual cost versus insulation thickness for expanded polystyrene insulation material for Aydın.

Figure 6. Annual cost versus insulation thickness for polyurethane insulation material for Aydın.

Figure 7. Annual cost versus insulation thickness for expanded polystyrene insulation material for Ardahan.

Figure 8. Annual cost versus insulation thickness for polyurethane insulation material for Ardahan.

Figure 9. Annual cost versus insulation thickness for expanded polystyrene insulation material for Ardahan.

Figure 10. Annual cost versus insulation thickness for polyurethane insulation material for Ardahan.

Figure 11. Annual cost versus insulation thickness for expanded polystyrene insulation material for Eskişehir.

Figure 12. Annual cost versus insulation thickness for polyurethane insulation material for Eskişehir.

Figure 13. Annual cost versus insulation thickness for expanded polystyrene insulation material for Eskişehir.

Figure 14. Annual cost versus insulation thickness for polyurethane insulation material for Eskişehir.

Figure 15. Annual cost versus insulation thickness for expanded polystyrene insulation material for Samsun.

Figure 16. Annual cost versus insulation thickness for polyurethane insulation material for Samsun.

Figure 17. Annual cost versus insulation thickness for expanded polystyrene insulation material for Samsun.

Figure 18. Annual cost versus insulation thickness for polyurethane insulation material for Samsun.

insulation thickness values of Aydın, Ardahan, Eskişehir and Samsun provinces 0.0608 m, 0.137 m, 0.103 m and 0.078 m respectively, for coal and polyurethane insulation material, 0.0304 m, 0.071 m, 0.0532 m and 0.0398 m respectively. For natural gas and expanded polystyrene insulation material, optimum insulation thickness values of Aydın, Ardahan, Eskişehir and Samsun provinces 0.0514 m, 0.1193 m, 0.0895 m and 0.067 m respectively, for natural gas and polyurethane insulation material 0.0255 m, 0.0617 m, 0.0476 m and 0.0338 m respectively.

For the 4 provinces, the changes of CO2 and SO2 emissions depending on insulation thickness are shown in Figures 19-30. As seen from the figures, while the insulation thickness increases, emission values decrease logarithmically. When compared the provinces of Ardahan in the cold climate region and Aydın in the hottest climate region, for the coal and optimum thickness of expanded polystyrene and polyurethane insulation materials, the reduction of CO2 and SO2 emissions of Aydın 72.5% and 68%

Figure 19. Variation of CO2 emission with insulation thickness for coal for Aydın.

Figure 20. Variation of SO2 emission with insulation thickness for coal for Aydın.

Figure 21. Variation of CO2 emission with insulation thickness for natural gas for Aydın.

Figure 22. Variation of CO2 emission with insulation thickness for coal for Ardahan.

Figure 23. Variation of SO2 emission with insulation thickness for coal for Ardahan.

Figure 24. Variation of CO2 emission with insulation thickness for natural gas for Ardahan.

Figure 25. Variation of CO2 emission with insulation thickness for coal for Eskişehir.

Figure 26. Variation of SO2 emission with insulation thickness for coal for Eskişehir.

Figure 27. Variation of CO2 emission with insulation thickness for natural gas for Eskişehir.

Figure 28. Variation of CO2 emission with insulation thickness for coal for Samsun.

Figure 29. Variation of SO2 emission with insulation thickness for coal for Samsun.

respectively, for natural gas and optimum thickness of expanded polystyrene and polyurethane insulation materials, the reduction of CO2 emission of Aydın 69% and 64.2% respectively. For coal and optimum thickness of expanded polystyrene and polyurethane insulation materials, the reduction of CO2 and SO2 emissions of Ardahan 85.6% and 83.3% respectively, for natural gas and optimum thickness of expanded polystyrene and polyurethane insulation materials, the reduction of CO2 emission of Ardahan 69% and 64.2% respectively.

The relations between annual energy cost saving and insulation thickness are shown in Figures 31-38. The values of energy cost saving increases up to optimum insulation thickness and beyond this level, the energy cost saving is decreased. For coal and optimum thickness of expanded polystyrene and polyurethane insulation materials, the energy cost savings of Aydın 19 $/m2∙year and 16 $/m2∙year respectively, for natural gas and optimum thickness of expanded polystyrene and polyurethane insulation materials, the energy saving of Aydın 13.9 $/m2∙year and 11.8 $/m2∙year respectively. For coal and

Figure 30. Variation of CO2 emission with insulation thickness for natural gas for Samsun.

Figure 31. Variation of energy saving with insulation thickness for coal for Aydın.

Figure 32. Variation of energy saving with insulation thickness for natural gas for Aydın.

Figure 33. Variation of energy saving with insulation thickness for coal for Ardahan.

Figure 34. Variation of energy saving with insulation thickness for natural gas for Ardahan.

Figure 35. Variation of energy saving with insulation thickness for coal for Eskişehir.

Figure 36. Variation of energy saving with insulation thickness for natural gas for Eskişehir.

Figure 37. Variation of energy saving with insulation thickness for coal for Samsun.

Figure 38. Variation of energy saving with insulation thickness for natural gas for Samsun.

optimum thickness of expanded polystyrene and polyurethane insulation materials, the energy saving of Ardahan 96 $/m2∙year and 88 $/m2∙year respectively, for natural gas and optimum thickness of expanded polystyrene and polyurethane insulation materials, the energy saving of Ardahan 73.35 $/m2∙year and 69.5 $/m2∙year respectively.

4. Conclusion

It has been calculated that Ardahan is located in the coldest climate region and Aydın is located in the hottest climate region. Thickness of the insulation material reduces the CO2 and SO2 emissions. It has been indicated that the reduction of CO2 and SO2 emissions for expanded polystyrene was higher than the polyurethane for the different climate regions. It can be concluded that the energy cost savings for coal is higher than the natural gas for the different regions. Also the energy cost savings for the expanded polystyrene was higher than the polyurethane insulation materials.

Cite this paper

Dombayci, Ö.A., Ozturk, H.K., Atalay, Ö., Acar, Ş.G. and Ulu, E.Y. (2016) The Impact of Optimum Insulation Thickness of External Walls to Energy Saving and Emissions of CO2 and SO2 for Turkey Different Climate Regions. Energy and Power Engineering, 8, 327-348. http://dx.doi.org/10.4236/epe.2016.811030

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Nomenclature

C cost ($)

Cf unit cost of fuel ($/kg)

Ct total heating cost at present value ($)

Cins unit cost of insulation material

HDD heating degree-days

PWF present worth factor

k thermal conductivity coefficient (W/m∙K)

qA annual heat loss (kJ/m2)

U heat transfer coefficient (W/m2∙K)

m mass (kg)

M(m) molecular mass (kg/kmol)

n mole(kmol)

EA annual energy needs(kJ/m2-year)

EC annual energy consumption (kJ/m2-year)

Ecostsaving annual energy cost saving ($/m2∙year)

R thermal resistance (m2∙K/W)

x insulation thickness (m)

η efficiency of the heating system

Subscripts

Qloss losses due to heat transfer

F(f) fuel

Ins insulation

nins non-insulation

opt optimum

t total