building envelope - group b (ettv)
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ettevTRANSCRIPT
![Page 1: Building Envelope - Group B (ETTV)](https://reader034.vdocument.in/reader034/viewer/2022042718/55cf8ef6550346703b977839/html5/thumbnails/1.jpg)
Calculation of ETTV Group B
Alan, Jaz, Xuan Xuan, Si yu, Fang Cong
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Content ETTV equation
Computing steps of ETTV
Work example 1
Work example 2
Sensitivity analysis
Quiz
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ETTV Equation
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ETTV Equation • Where more than one type of material and/or fenestration is used:
![Page 5: Building Envelope - Group B (ETTV)](https://reader034.vdocument.in/reader034/viewer/2022042718/55cf8ef6550346703b977839/html5/thumbnails/5.jpg)
ETTV Equation • ETTV of the whole building envelope is obtained by taking the weighted
average of individual walls at different orientations.
![Page 6: Building Envelope - Group B (ETTV)](https://reader034.vdocument.in/reader034/viewer/2022042718/55cf8ef6550346703b977839/html5/thumbnails/6.jpg)
Computation of ETTV
• First step: calculation of different areas with different material
• Second step: computation of U-value for different types of building envelope
• Third step: find out the shading coefficient (SC) for different types of glass
• Forth step: find out the correction factors (CF) for solar heat gain through fenestration in different orientation
• Last step: use ETTV equation to calculate the total ETTV
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1st step: Areas • South-west elevation
Beam
Glass window
Glass window
Glass window
Brick wall
60000
1800
2400
350
3150
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1st step: Areas
• Area of beam:
– Aw1=350x60000
• Area of glass windows:
– Af1=2400x1800
• Area of brick wall:
– Aw2= 3150x60000-Af1
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2nd step: U-value • Thermal conductivity, k
– Material’s ability to conduct heat
• Thickness, b
• Thermal resistance, R
– R=b/k
• Thermal transmittance, U
– U=1/R
![Page 10: Building Envelope - Group B (ETTV)](https://reader034.vdocument.in/reader034/viewer/2022042718/55cf8ef6550346703b977839/html5/thumbnails/10.jpg)
3rd step: SC • A measure of the total amount of heat passing through the
glazing compared with that through a single 3mm clear glass
• SC=solar heat gain of any glass and shading combination / solar heat gain through a 3mm unshaded clear glass
• Between 0 to 1
• The lower the better
• Provided by manufacturer
• Affected by external shading devices
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Shading Coefficient
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4th step: CF • The solar correction factors for eight primary orientations of the walls
have been determined for the Singapore climate.
• the eight primary orientations are segmented as follows:
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4th step: CF Solar correction factors (CF) for walls
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5th step: ETTV • Find out individual ETTV of walls of different orientations
• Calculate the overall ETTV
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Work example 1
• An single-storey office has the internal layout plan shown in Fig.1. Section detail of the walls are shown in section A-A and B-B. The office is orientated in the North, East, South and West directions with the front façade facing the south.
• Calculate the ETTV for the building envelope.
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Fig. 1
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Section A-A
250mm r. c beam
Single glazing
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250 mm r. c beam
200mmr.c wall
Section B-B
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Answer (i) South façade: (a) Single glazing Af1 : 3.6 x 45= 162.0m2
(b) 250mm r.c beam Aw1:1.1 x 45 = 49.5m2
(ii) East façade: (a) Single glazing Af1 : 3.6 x 25 = 90m2
(b)250mm r.c beam Aw1 : 1.1 x 25 = 27.5m2
(iii) North façade: (a) 200mm r.c wall Aw2 : 4x45=180 m2
(b) r.c beam Aw1 :0.7x45 = 31.5m2
(iv) West façade: (a) 200mm r.c wall Aw2 : 4x25 =100m2
(b) r.c beam Aw1 : 0.7x25 =17.5m2
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U-Value Calculation • (a) 8mm single glazing (South & East Facades)
R = 0.044+0.008/1.053 +0.12 =0.172m K/W U=1/R=5.82W/m2
SCg = 0.61(by manufacturer)
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U-Value Calculation
• (b) 250mm r.c beam
R=0.044+0.012/1.298+0.25/1.442+0.012/0.053+0.12=0.369m2
U=1/R=2.71W/m2 K
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U-Value Calculation
• (c) 200mm r.c wall(North and west facades)
R=0.044+0.012/1.298+0.2/1.442+0.012/0.533+0.12=0.334m2 K/W
U=1/R=2.99W /m2 K
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ETTV Calculation General Equation:
ETTV=1/Ao [12(Aw x Uw )+3.4(Af xUf )+211xCF(Af xSC)]
• South façade(CF=0.83)
ETTVs =1/211.5[12(49.5x2.71)+3.4(162x5.82)+211x0.83(162x0.61)=104.59W/m2
• East facade (CF =1.13)
ETTVe =1/117.5[12x(27.5x2.71)+3.4(90x5.82)+211x1.13x(90x0.61)=134.17W/m2
• North façade(CF=0.80)
ETTVn =1/211.5[12x(180x2.99+31.5x2.71)=35.38W/m2
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ETTV Calculation • West façade
ETTVw = 1/117.5[12x(100x2.99+17.5x2.71)]= 35.38W/m2
• Overall for Whole Building
ETTV= (104.57x211.5+ 134.17x 117.5+ 35.38x 211.5+35.38x117.5)/(211.5+117.5+ 211.5+117.5)
= 75.26W/m2
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Work Example 2
The internal lay-out plan of an single-story office building is shown in Fig(A). Typical section details of wall are shown in section A-A, section B-B, section C-C. Calculate the ETTV for the building envelope.
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Answer (Areas)
1. South-west façade
250mm RC Beam: Aw1= 0.5x20=10m2
Single glazing wall: Af1 = 3x20=60m2
2. West-north façade
250mm RC Beam : Aw1= 1x30=30m2
200mm RA Wall : Aw1= 2.5x30=70m2
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Areas 3. North-east façade
250mm RC Beam : Aw1= 0.5x20=10m2
Double glazing window: Af1 = 2x20=40m2
200mm RC Wall : 1x20=20m2
4. East-south façade
250mm RC Beam : 1x30=30m2
200mm RC Wall : 2.5x30=70m2
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U-value calculation 1. 250mm RC Beam
Rt=0.044+0.012/1.298+0.012/0.533+0.25/1.422+0.12=0.3691m2
k/w
U=1/Rt=2.71w/m2k
2. 8mm single glazing wall
Rt=0.044+0.008/1.053+0.12=0.1716m2k/w
U=1/Rt=5.83w/m2k
SC=0.5(By manufacturer)
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U-value calculation 3. 200mm RC Wall
Rt=0.044+0.02/1.154+0.02/0.37+0.2/1.442+0.12= 0.3741m2k/w
U=1/=2.67w/m2k
4. Double glazing window
Rt=0.044+0.008/1.053+0.008/1.053+0.118+0.12= 0.290m2k/w
U=3.448w/m2k
SC=0.5(By manufacturer)
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ETTV calculation General equation:
ETTV=1/Ao [12(Aw * Uw )+3.4(Af *Uf )+211*CF(Af *SC)]
1. South-west façade(CF=1.06)
ETTVW=1/70[12(10*2.71)+3.4(60*5.83)+211*1.06(60*0.7)]=155.83w/m2
2. West-north façade
ETTVN=1/100[12(30*2.71+70*2.67)]=32.18w/m2
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ETTV calculation 3. North-east façade(CF=0.97)
ETTVE=1/70[12(10*2.71+20*2.67)+3.4(40*3.448)+211*0.97(40*0.5)]=78.98w/m2
4. East-south façade
ETTVS=1/100[(12(30*2.72+70*2.67)]=32.18w/m2
Total ETTV:
ETTVT=(155.83*70+32.18*100+78.98*70+32.18*100)/(70+100+70+100) = 67.27w/m2
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Sensitivity Analysis of ETTV
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Sensitivity Analysis • ETTV can be calculated by summing up three basic components of heat
gain through building envelope. These are
– Heat conduction through opaque walls
– Heat conduction through transparent window
– Solar radiation through transparent window
• Therefore, analysis can be done based on each component.
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Sensitivity Analysis
Heat conduction through opaque walls and transparent windows •Thermal transmittance ( U- value)
– The quantity of heat that flows through a unit area of a building section under steady – state conditions in unit time per unit temperature difference of the air on either side of the section
– The smaller value of thermal transmittance of the material of being used, the smaller amount of heat will be transmitted.
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Sensitivity Analysis
Heat conduction through opaque walls and transparent windows • Surface air film resistance ( Façade orientation and inclination)
– The transfer of heat to and from a surface of a body through air is reduced by the presence of a thin layer of relatively motionless air at the surface of the body
– Surface air film resistance is affected by wind velocity and therefore different resistance values for outside and inside air films are given.
– If you want to increase the thermal resistance, then you should use high emissive surface and try to reduce the slope of the roof as much as possible.
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Sensitivity Analysis
Heat conduction through opaque walls and transparent windows • Air space resistance
– Air is a relatively poor conductor of heat.
– The concept is the same as the air film resistance
– In addition, reflective material can be inserted in an air space to increases the thermal resistance of the air space.
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Sensitivity Analysis
Solar Radiation through transparent window. • Shading coefficient of fenestration (SC)
– The ratio of solar hear gain through the fenestration system having combination of glazing and shading device to the solar heat gain through an unshaded 3mm clear glass.
– The factors affecting SC are
• Inter – block shading
• Direct shading
• Diffused shading
• Reduced surface temperature
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Sensitivity Analysis Solar Radiation through transparent window Shading coefficient of fenestration (SC)
– Inter – block shading
• Neighboring buildings overshadowing another
• This will inadvertently affect the heat gains through façade
• Singapore’s ETTV methodology does not consider this factor
• Because assumption changes when the adjacent building changes
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Sensitivity Analysis
Solar Radiation through transparent window Shading coefficient of fenestration (SC)
– Direct shading
• Shading devices such as perforated screens
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Sensitivity Analysis
Solar Radiation through transparent window. •Shading coefficient of fenestration (SC)
– Indirect shading
• The sky factor was used as a benchmark figure
• Code’s standard procedures ignores this
– Reduced conduction heat gain
• Relates to heat gain through the opaque building envelope
• due to direct and diffused shading
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Sensitivity Analysis
Solar Radiation through transparent window. •Solar data
– Solar geometry
• The position of the sun
– Shadow angel
– Intensity of solar radiation
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Sensitivity Analysis
ETTV • Area of opaque wall or transparent windows (Window-to-wall
ratio) – The bigger the area, the more heat will be transmitted
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Quiz 1 (matching)
1st step U – value
2nd step CF
3rd step Areas
4th step ETTV
5th step SC
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Answer
1st step Areas
2nd step U – value
3rd step SC
4th step CF
5th step ETTV
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Quiz 2 (matching)
Thermal transmittance Reflective material can be inserted
Air space resistance Shading devices
Surface air film resistance Assumption changes when the adjacent building changes
Direct shading
The quantity of heat that flows through a unit area of a building section
Inter – block shading
Affected by wind velocity
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Answer Thermal transmittance The quantity of heat that flows through a
unit area of a building section
Air space resistance reflective material can be inserted
Surface air film resistance affected by wind velocity
Direct shading
Shading devices
Inter – block shading
assumption changes when the adjacent building changes
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