Design Energy-Plus-House for the Climatic Conditions of Macedonia

Design Energy-Plus-House for the Climatic Conditions of Macedonia

Available online at www.sciencedirect.com ScienceDirect Procedia Engineering 117 (2015) 766 – 774 International Scientific Conference Urban Civil En...

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Available online at www.sciencedirect.com

ScienceDirect Procedia Engineering 117 (2015) 766 – 774

International Scientific Conference Urban Civil Engineering and Municipal Facilities, SPbUCEMF-2015

Design Energy-Plus-House for the Climatic Conditions of Macedonia Ekaterina Aronovaa, Nikolai Vatinb, Vera Murgulb,* a

Ioffe Physical-Technical Institute of the Russian Academy of Sciences, 194021, Saint-Petersburg, Russia St. Petersburg State Polytechnical University, Politekhnicheskaya, 29, Saint-Petersburg, 195251, Russia

b

Abstract Climatic conditions allow Macedonia to design buildings, known as «Energy-plus house». This work complements the earlier studies carried out under the project «Passive house» for single-family house of Franz Freundorfer, and skips to the next level creating a «Energy-plus house». The project supplemented by the possibility of electricity based on solar energy. Evaluations insolation and receipt of solar radiation on differently oriented surfaces have shown the promise of using photovoltaic modules for electricity generation in Macedonia weather conditions. ©2015 2015The The Authors. Published by Elsevier Ltd. © Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license (http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of the organizing committee of SPbUCEMF-2015. Peer-review under responsibility of the organizing committee of SPbUCEMF-2015

Keywords: Passive house, Energy-plus house, solar power, photovoltaic systems, energy efficiency, Macedonia.

1. Introduction Possibility of building a completely non-volatile buildings is relevant to Macedonia, where low population density is far away from the centralized energy networks areas. The concept is based on the statement to reduce heating costs to zero and achieve constant comfortable temperatures owing to efficient thermal insulation and impermeability of a building’s envelope, any home heat recovery and passive solar heating. [2, 3, 4] (Fig. 1).

* Corresponding author. Tel.: +7 950 010 1931; fax: +7 812 535 7992 E-mail address: [email protected]

1877-7058 © 2015 The Authors. Published by Elsevier Ltd. This is an open access article under the CC BY-NC-ND license

(http://creativecommons.org/licenses/by-nc-nd/4.0/). Peer-review under responsibility of the organizing committee of SPbUCEMF-2015

doi:10.1016/j.proeng.2015.08.231

Ekaterina Aronova et al. / Procedia Engineering 117 (2015) 766 – 774

Fig. 1. Basic components of the «Passive house»concept.

The report for the project in this article Energy-plus house has taken the concept of "passive house", supplemented by the possibility of electricity based on solarenergy. The basic assessment criteria whether the building meets the standard “passive house” are as follows: VSHFLILF HQHUJ\ GHPDQGV IRU KHDWLQJFRROLQJ 46+46&  >” N:K PD @ RU alternative: heating/cooling load (HL)/(CL) >” 10W/m2]; air impermeability >Ș ” 0.6 h-1]; specific SULPDU\ HQHUJ\ GHPDQG 463  >”  kWh/(m2a)] and the emission of CO2. [1] The rate of 15 kW / (m² per year) is the typical one in matter of energy consumption needed to heat a «passive house» under weather conditions of Central Europe. In Stockholm it can reach 20 kW / (m² per year), and in Rome it can’t be over 10 kW / (m² per year). 2. Object of research The macro location of the building falls in the eastern part of Macedonia, at an altitude of 600m and is located on a plateau. The architecture of the house has been taken from the famous house of Franz Freundorfer (Fig. 2).

Fig. 2. Facade of the analyzed building

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3. Parametric analysis of the passive house The calculation of the passive house was made with the software package PHPP 2007. Dimensions of the insulation, windows and all other elements were defined to meet the criteria for a passive house and in same time to be as close as possible to the limit values for the Passive House (PH) standard. Comparison of the final calculation results with the maximum values defined by the Passive House standard is presented in Tab. 1 [1, 5]. Table 1. Comparison of calculation results from PHPP 2007 and standard values [1] Max. value (standard)

Criteria

Symbol

Unites

Design

Specific energy heating demand

QSH

2 kWh/(m a)

14

15

Specific primary energy demand

QSP

2 kWh/(m a)

78

120

Heating load

HL

10

10

Cooling load

CL

2 W/m 2 W/m

7

10

Frequency of overheating

h

%

4

10

value

An extremely low energy demand for heating enables the heat to be delivered through the ventilation system (the air is heated with electric heaters after therecuperator). The calculation results clearly show that there is a need additional heating device which will produce an additional 171 W. In the case of conventional energy sources, emissions of carbon dioxide from the heating system is 9 kg/(m2a) while the total emission is 19 kg/(ma). Building, that are using only the solar energy, will be a CO2-neutral. Previously developed project standards of "passive house" is proposed to add energy-based photovoltaic modules. 4. Influence of the building orientation The orientation of the building has direct impact on the energy balance of the passive building. The initial orientation (south of the house was rotated by steps of 30° clockwise and the results of PHPP 2007 for each of the defined positions of the house are presented in the Tab. 2. Table 2. Influence of building orientation [1] Specific energy demands

Freq. of overh. CO2 emision

Load

Description

heating

cooling

primary energy

heating

Cooling

Symbol

QSH

QCS

QSP

HL

CL

Unites

2 [ kWh/(m a)]

Prescribedvalues Design values Rotation 30 Rotation 60 Rotation 90

o o o

2 [W/m ]

without equipem. Total h

CO2Qsp

[%]

CO2Qsh 2 [kg/(m a)]

15

120

10

10

10

/

/

13.93

9.36

77.74

10.06

6.76

3.62

8.88

19.35

14.57

11.22

78.33

10.22

7.87

6.11

9.01

19.49

16.34

14.93

79.96

10.46

8.56

12.97

9.39

19.86

18.26

17.20

81.78

10.65

10.03

11.90

9.80

20.28

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Rotation 120 Rotation 150 Rotation 180

o o o

20.02

16.68

83.47

10.75

8.96

9.89

10.19

20.66

21.41

14.99

84.84

10.78

7.55

4.10

10.51

20.97

22.92

13.85

86.36

10.94

6.61

1.83

10.85

21.32

5. Calculation of the incoming solar energy The territory of Macedonia is rich of the solar resources, which confirms the insolation map of the country, shown in Fig. 3 Meteorological observations conducted from April 2004 to March 2010, showed that almost all of the country's annual influx of solar energy is more than 1400 kWh/m², and for some areas is 1600 kWh/m². Therefore, the use of solar photovoltaic modules and systems based on them is relevant and energyefficient way to produce additional electricity for Passive house. Solution of the task of placement of photovoltaic modules on the ground is based on the correct definition of the angle of inclination to the horizontal surface of the modules, for optimal security features of electricity (at a given orientation modules to the south, in accordance with the location of the house). Tab. 3 below presents data on the amount of solar radiation on surfaces inclined at different angles to the weather conditions, the Skopje with coordinates 41°59'N, 21°26'E [8].

Fig. 3. Global horizontal irradiation.

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Table 3. Receipt of the total solar radiation on differently oriented surfaces of photovoltaicmodules, [kWh/m²] Month

Angle of inclination of the modules to the horizon, [deg] 0

27

42

57

90

January

52.08

79.67

89.28

93.93

85.87

February

68.04

91.56

98.28

99.68

84

March

106.33

126.17

128.65

124.62

94.55

April

126

133.2

128.4

117.9

79.2

May

158.41

157.17

146.32

128.65

78.43

June

183.6

174.3

159

136.5

78.3

July

192.82

188.48

172.98

149.42

85.25

August

170.5

177.32

168.64

151.59

94.55

September

122.1

140.4

140.7

133.8

96.6

October

85.25

110.05

115.94

115.94

95.17

November

50.4

72

78.9

81.6

72.3

December

41.54

63.86

71.92

76.26

70.37

Year

1357.07

1514.18

1499.01

1409.89

1014.59

As can be seen from Table 3 the maximum annual amount of solar radiation is observed in the surface inclined at an angle of 27 ° to the horizon. However, when selecting the optimum angle modules should also take into account peculiarities of power consumption. In this project, “Passive house” the house lacks heating (171 W), which is proposed to be added by using the electric heater in the cold season. Therefore, in Fig. 4 shows the flow of radiation from season to season, and Fig. 5 discrepancy in the parish in relation to the horizontal plane.

Ekaterina Aronova et al. / Procedia Engineering 117 (2015) 766 – 774

Fig. 4. Assessment of the amount of solar radiation on differently oriented surfaces byseasons.

Analysis of the data presented in Fig. 4 and 5, led to the following conclusions: • The arrival of the solar radiation in the summer is maximum on a horizontal surface; • The arrival of the solar radiation in the winter is maximum on the surface with angle of 57 °; • The arrival of the solar radiation in the spring and autumn periods is highest on the surface at angles 27 ° and 42 °, respectively; • The amount of solar radiation on a vertical surface is practically unchanged from season to season, but it is minimal with respect to the horizontal surface of the spring and summer; • The difference in the flow of energy on the surface at angles of 42 ° and 57 ° are minimal.

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Fig. 5. Shots incoming solar energy on differently oriented surface and a horizontal surface

Thus, the priority use of the energy generated by photovoltaic modules in the cold season, possibly with tilt angles of modules in 57° and 42 °. However, since the total annual flow in the second case, a 6% increase in the subsequent calculations will be used in a 42° angle to the horizon. In the second stage assess the effectiveness of solar panels to generate electricity in Macedonia weather conditions dealing with the following inputs: x Estimated area south oriented front roof pitch - 50 m²; x The efficiency of PV modules - 15%; x The angle of the modules to the horizon - 42°. Figure 6 provides an assessment of electricity generation by the solar modules of 50 m² in every month of the year. Annual electricity production will be 11242 kWh. Daily average values for each month of the year are shown in Fig. 7. The graph shows the minimum value for December is 17 kWh, which is enough to provide electricity for the heating device.

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1297 (11,54%)

1265 (11,25%) 1055 (9,38%) 870 (7,74%)

1193 (10,61%)

592 (5,27%) 1097 (9,76%)

539 (4,79%) 670 (5,96%) 963 (8,57%) 737 (6,56%) 965 (8,58%)

Jan Jul

Feb Aug

Mar Sep

Apr Oct

May Nov

Jun Dec 2

Fig. 6. Evaluation of power generation by the solar modules (from the surface of the roof 50m )

Fig. 7. Evaluation of the average daily power generation solar modules by month (50m2)

6. Conclusions Climatic conditions allow Macedonia to design buildings, known as «Energy-plus house». In addition, emission of carbon dioxide (CO2) is proportional to the increase in energy consumption for heating / cooling and total primary energy. «Energy-plus house» provide an environmentally safe operation of buildings. Evaluations insolation and receipt of solar radiation on differently oriented surfaces have shown the promise of

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using photovoltaic modules for electricity generation in Macedonia weather conditions. Optimum tilt angle of the module is 42°, which provides operational efficiencies of modules in the cold season and almost maximum energy production throughout the year. Evaluation of power generation modules with the surface of the building showed that the worst in terms of resource flows of solar radiation of the month - December solar modules will generate no less than 17 kWh electricity consumption per day. Thus, this work complements the earlier studies carried out under the project «Passive house», and skips to the next level creating a «Energy-plus house». References [1] Cvetkovska, M., Trpevski, S., Andreev, A., Knezevic, M. Parametric analysis of the energy demand in buildings with Passive House standard (2013) Portugal SB13 - Contribution of Sustainable Building to Meet EU 20-20-20 Targets, pp. 303-310. [2] Feist, W., Schnieders, J., Dorer, V., Haas, A. Re-inventing air heating: Convenient and comfortable within the frame of the Passive House concept (2005) Energy and Buildings, Vol. 37(11), pp. 1186–1203. [3] Gabriyel, I., Ladener, Kh. Rekonstruktsiya zdaniy po standartam energoeffektivnogo doma (2011) SPb.: BKhV-Peterburg, 470 p. >@ 2VWURZVND $ 6REF]\N : 0DáJRU]DWD 3DZXO 2FHQD HIHNWyZ HNRQRPLF]Q\FK L ekologicznych wykorzystania energii VáRQHF]QHM na SU]\NáDG]LH domu jednorodzinnego (2013) Rocznik 2FKURQDĝURGRZLVND $QQXDO6HW7KH(QYLURQPHQW3URWHFWLRQ SS 2697–2710. [5] Andreev A., Parametric analysis of the energy demand in buildings with Passive House standard (2013) Master thesis, University Ss. Cyril and Methodius, Skopje, 182p. [6] Standards: MKC EN 410:200; MKC EN 673/A1/A2:2006; MKC ISO 6946:2009; MKC EN ISO 9288:2008; MKC EN ISO 13788:2006; MKC EN ISO 13947:2009; DIN 277; DIN V 4108-4; DIN EN 1283; DIN EN 13363 ; DIN EN 13829; DIN EN ISO 13790:2004; DIN ISO 13370 ; DIN V 18599-2; DIN V 4180-6; DIN EN ISO 10211-1:1995; DIN V 4701-10; DIN EN ISO 6946:1996 >@ .RYDþLþ % .DPQLN 5 3UHPURY 0 *XEHOMDN 1 3UHGDQ - 7LãPD = 0RGHUQ deformation measurement techniques and their comparison (2008) Strojniski Vestnik/Journal of Mechanical Engineering, 54 (5), pp. 364-371. [8] Information on: http://solargis.info