THERMAL SIMULATION REPORT. TCL2013-Origin-01 Prepared For:

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THERMAL SIMULATION REPORT Report Number: TCL2013-Origin-01 Prepared For: Origin Frames Ltd Unit 3 Sunters End Hillbottom Road Sands Industrial Estate High Wycombe Bucks HP12 4HS Window System

1 THERMAL SIMULATION REPORT Report Number: TCL2013-Origin-01 Prepared For: Origin Frames Ltd Unit 3 Sunters End Hillbottom Road Sands Industrial Estate High Wycombe Bucks HP12 4HS Window System Identifier: Origin Window Fixed Outer Frame Identifier: Origin Outer Frame Mullion Frame Identifier: Origin Transom / Mullion Vent Frame Identifier: Origin Vent Glazing System: Clear Float 90% Argon Planitherm 4S Spacer Bar: Swiss Spacer Ultimate Notes: Results Thermal Transmittance (U window ) 1.5 W/(m 2 K) (Window Configuration as per GGF Document 2.2) (1230mm wide x 1480mm high vent next to fixed light) Report Prepared By Dr Gary Morgan Therm Consulting Signed: G Morgan Date: 2 nd December 2013 The simulations in this report were performed using Win Iso 2D Pro version 7.57, strictly in accordance with the requirements of EN ISO :2012 The simulation files generated are attached to this report as appendices

0.0034437 All 0.00132125 1mm, 0.00132125 F3 0.00112625 F5 0.00112625 F7 0.00344 F10 0.00324875 F11 0.0025 0.0025 0.0025 0.0025 0.0025 0.0025 0.0025 0.0025 1 Sample Style: Report Number: Issue No 22.

THE BFRC AND CAN ONLY BE USED IN CONJUNCTION WITH A BFRC LICENCE Frame offset: No Blue line illustrates opening light length (air leakage) Input Values: Yellow input, green intermediary, blue finals

of decimal places to enter Parameter Symbol Units Total window height 0DP l w 1480 mm Total window width 0DP b w 1230 mm Nominal 4mm etc to 0DP, others 1DP Glazing dimensions and properties:

Trans. - 3DP U g 1.070 W/(m² K) g -value - 2DP g?

7233 Opening light 1.3020 0.4530 0.5898 0.5811 Total glazing, Ag 1.3226 1.3043 Frame (m) (m) (m 2 ) (m 2 ) F1 0.6150 0.0500 0.0287 0.0300 F2 0.6150 0.0500 0.0287 0.0300 F3 1.4800 0.0500 0.0715 0.

4800 0.0680 0.0972 0.1007 F11 1.3800 0.0390 0.0523 0.0555 Total Frame 0.4978 0.5161 Total Window, Aw 1.8204 1.8204 Percentage fixed light glass area 40.25% 39.

00 Frame dimensions: Frame Gasket Frame & width, bf protrusion, gasket bgf widths (bf) (mm) (mm) (mm) frame values round to nearest F1 fixed sill 50 2.5 52.5 gaskets to 1DP F2 fixed head 50 2.5 52.5 fixed jamb 50 2.

2 All mm, F F F F F Sample Style: Report Number: Issue No 22.1: 11/03/2013 Casement Fixed Light / Side Hung Report Date: Project Details: TCL2013-Origin01 2nd December 2013 Origin Window - Planitherm 4S and Swiss Ultimate THIS SPREADSHEET IS THE PROPERTY OF THE BFRC AND CAN ONLY BE USED IN CONJUNCTION WITH A BFRC LICENCE Frame offset: No Blue line illustrates opening light length (air leakage) Input Values: Yellow input, green intermediary, blue finals X' DP is no.of decimal places to enter Parameter Symbol Units Total window height 0DP l w 1480 mm Total window width 0DP b w 1230 mm Nominal 4mm etc to 0DP, others 1DP Glazing dimensions and properties: Thickness of pane 1 4 mm Pane 1/2 distance 20 mm Gas fill (1/2) Argon 90% Thickness of pane 2 4 mm Complete next 3 cells for TG IGU Pane 2/3 distance Thickness of pane 3 Gas fill (2/3) mm mm Glazing Trans. - 3DP U g W/(m² K) g -value - 2DP g? Thermal transmittance of window from hot box test U w - 2DP W/(m² K) Window Dimensions: Area Length Width No With gasket gasket Section (m) (m) (m 2 ) (m 2 ) Fixed Light Opening light Total glazing, Ag Frame (m) (m) (m 2 ) (m 2 ) F F F F F F F F F F F Total Frame Total Window, Aw Percentage fixed light glass area 40.25% 39.73% Percentage opening light glass area 32.40% 31.92% Percentage glass area (total) 72.65% 71.65% Solar Factor, g -value: F w 0.9 g w 0.00 Frame dimensions: Frame Gasket Frame & width, bf protrusion, gasket bgf widths (bf) (mm) (mm) (mm) frame values round to nearest F1 fixed sill gaskets to 1DP F2 fixed head fixed jamb Total F4 + F5 sash sill F4 fixed sash sill 50 n/a 50.0 moving sash sill F6 + F7 sash head F6 fixed sash head 50 n/a 50.0 moving sash head F8 + F9 sash jamb F8 Fixed sash jamb 50 n/a 50.0 F9 moving sash jamb F10 + F11 mullion fixed mullion moving mullion Total gasket area m 2 Where a Uw value from hot box testing is available, no L 1 f 2D or L Ψ 2D values need to be entered Frame conductance: All L values to 4DP. All b values to 0DP W/(m K) bp (mm) W/(m K) bg (mm) F1 fixed sill Frame: F2 fixed head F3 fixed jamb L f 2D L Ψ 2D F4 + F5 sash sill F6 + F7 sash head F8 + F9 sash jamb F10 + F11 mullion Section Frame width, bf Frame U- value, Uf Frame areas, Af Frame heat inear trans, flow, HU Linear length, lg Junction heat flow, Hψ (m) (W/(m² K)) (m 2 ) (W/K) (W/(m K)) (m) (W/K) F1 fixed sill F2 fixed head F3 fixed jamb F4 + F5 sash sill F6 + F7 sash head F8 + F9 sash jamb F10 + F11 mullion Totals Total Air Leakage loss: Air leakage at 50 Pa per hour & per unit length of opening light (BS ) - 2DP m³/(m h) Opening light length m Total air leakage m 3 /h L m 3 /(m 2?h) Heat loss = L W/(m 2 K) U window No bars; or attached bars 1.53 Single cross bar in IGU 1.6 Multiple cross bar in IGU 1.7 Glazing bar (Georgian bar) 1.9 BFRC Rating kwh/(m 2 yr)?10 Label index N/A EWER Rating Scale A+ 0 to <10 A -10 to <0 B -20 to <-10 C -30 to <-20 D -50 to <-30 E -70 to <-50 F W/(m² K) Window Rating N/A Other parameters needed for calculation, taken from simulations: d p =d g = m 0.13 m 2 K p = W/(m K) R se = 0.04 K /W R se = /W R p = m 2 K /W R = tot K /W U p = W/(m² K) BFRC Rating = 218.6g window x (U window + Effective L50) = N/A Climate zone is: UK Thermal transmittance, W/(m 2 K) U window 1.5 Solar factor g window N/A Window air leakage heat loss, W/(m 2 K) L factor N/A BFRC Certified Simulator Name: Dr Gary Morgan Simulator 016

4 Simulation software: WinIso2D 7.57 Date: File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\fixed - U value - Garys Swiss Ultimate.f2d Calculation of the linear thermal transmission coefficient Ψ according to EN ISO Simulation model: Dimensions (width x height): 240,00 x 100,00 mm Number of elements in simulation model: X-direction: 259; Y-direction: 228 Boundary conditions: External: Temperature Θe: 0,00 C Surface resistance Rse: 0,040 m²k/w Internal: Temperature Θi: 20,00 C Surface resistance Rsi 1: 0,130 m²k/w Surface resistance Rsi 2: 0,200 m²k/w Results: Temperature difference dt: 20,00 K Total heat flow Q: 7,274 W/m 2D thermal conductance L2D: 0,364 W/mK Length top/left: U-value top/left: 1,070 W/m²K Length bottom/right: 0,00 mm U-value bottom/right: 0,000 W/m²K Ψ-value: 0,039 W/mK

5 Materials: Material R T ( C) Q(gesamt) (m²k/w) (W/m) konform ****ADIABAT**** 0,000 0,000 0,000 1 boundary condition intside 0,13, 0,130 20,000 6,484 X 1 boundary condition outside 0,04, 0,040 0,000-7,272 X 0 C, 80% 1 boundary condition intside 0,20, 0,200 20,000 0,792 X profiles) profiles <=2mm) Material L Emiss (W/mK) konform 4 polyamide % GF 0,300 0,900 X 5 EPDM 0,250 0,900 X 2 float 1.0 1,000 0,837-3 alu (Si-Leg.) 160 copy 160,000 0,900-6 butyle 0,240 0,900 X 6 Swiss Ultimate Effective 0,140 0,900 X SZR L= ,026 0,900 -

$Simulation software: WinIso2D 7.57 Date: 02.12.2013 File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\fixed - U value - Garys Swiss Ultimate.$

6 Simulation software: WinIso2D 7.57 Date: File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\fixed - U value - Garys Swiss Ultimate.f2d Calculation of the thermal transmission coefficient U f according to EN ISO : Simulation model: Dimensions (width x height): 240,00 x 100,00 mm Number of elements in simulation model: X-direction: 259; Y-direction: 228 Boundary conditions: External: Temperature Θe: 0,00 C Surface resistance Rse: 0,040 m²k/w Internal: Temperature Θi: 20,00 C Surface resistance Rsi 1: 0,130 m²k/w Surface resistance Rsi 2: 0,200 m²k/w Results: Temperature difference dt: 20,00 K Total heat flow Q: 6,355 W/m 2D thermal conductance L2D: 0,318 W/mK Length 1: U-value 1: 1,031 W/m²K Length 2: 0,00 mm U-value 2: 0,000 W/m²K U f-value: 2,437 W/m²K

7 Materials: Material R T ( C) Q(gesamt) (m²k/w) (W/m) konform ****ADIABAT**** 0,000 0,000 0,000 1 boundary condition intside 0,13, 0,130 20,000 6,484 X 1 boundary condition outside 0,04, 0,040 0,000-7,272 X 0 C, 80% 1 boundary condition intside 0,20, 0,200 20,000 0,792 X profiles) profiles <=2mm) Material L Emiss (W/mK) konform 4 polyamide % GF 0,300 0,900 X 5 EPDM 0,250 0,900 X 2 float 1.0 1,000 0,837-3 alu (Si-Leg.) 160 copy 160,000 0,900-6 butyle 0,240 0,900 X 6 Swiss Ultimate Effective 0,140 0,900 X SZR L= ,026 0,900 -

8 Simulation software: WinIso2D 7.57 Date: File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\vent - U value Garys Swiss Ultimate.f2d Calculation of the linear thermal transmission coefficient Ψ according to EN ISO Simulation model: Dimensions (width x height): 278,67 x 100,00 mm Number of elements in simulation model: X-direction: 413; Y-direction: 309 Boundary conditions: External: Temperature Θe: 0,00 C Surface resistance Rse: 0,040 m²k/w Internal: Temperature Θi: 20,00 C Surface resistance Rsi 1: 0,130 m²k/w Surface resistance Rsi 2: 0,200 m²k/w Results: Temperature difference dt: 20,00 K Total heat flow Q: 8,479 W/m 2D thermal conductance L2D: 0,424 W/mK Length top/left: U-value top/left: 1,070 W/m²K Length bottom/right: 0,00 mm U-value bottom/right: 0,000 W/m²K Ψ-value: 0,033 W/mK

9 Materials: Material R T ( C) Q(gesamt) (m²k/w) (W/m) konform ****ADIABAT**** 0,000 0,000 0,000 1 boundary condition intside 0,13, 0,130 20,000 7,055 X 1 boundary condition outside 0,04, 0,040 0,000-8,477 X 0 C, 80% 1 boundary condition intside 0,20, 0,200 20,000 1,427 X profiles) profiles <=2mm) profiles, sparse ventilated) Material L Emiss (W/mK) konform 3 alu (Si-Leg.) ,000 0,900 X 4 polyamide % GF 0,300 0,900 X 5 EPDM 0,250 0,900 X 2 float 1.0 1,000 0,837-5 Q-lon 0,060 0,900-6 butyle 0,240 0,900 X 6 Swiss Ultimate Effective 0,140 0,900 X SZR L= ,026 0,900 -

$Simulation software: WinIso2D 7.57 Date: 02.12.2013 File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\vent - U value Garys Swiss Ultimate.$

10 Simulation software: WinIso2D 7.57 Date: File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\vent - U value Garys Swiss Ultimate.f2d Calculation of the thermal transmission coefficient U f according to EN ISO : Simulation model: Dimensions (width x height): 278,67 x 100,00 mm Number of elements in simulation model: X-direction: 413; Y-direction: 309 Boundary conditions: External: Temperature Θe: 0,00 C Surface resistance Rse: 0,040 m²k/w Internal: Temperature Θi: 20,00 C Surface resistance Rsi 1: 0,130 m²k/w Surface resistance Rsi 2: 0,200 m²k/w Results: Temperature difference dt: 20,00 K Total heat flow Q: 7,667 W/m 2D thermal conductance L2D: 0,383 W/mK Length 1: U-value 1: 1,031 W/m²K Length 2: 0,00 mm U-value 2: 0,000 W/m²K U f-value: 2,106 W/m²K

11 Materials: Material R T ( C) Q(gesamt) (m²k/w) (W/m) konform ****ADIABAT**** 0,000 0,000 0,000 1 boundary condition intside 0,13, 0,130 20,000 7,055 X 1 boundary condition outside 0,04, 0,040 0,000-8,477 X 0 C, 80% 1 boundary condition intside 0,20, 0,200 20,000 1,427 X profiles) profiles <=2mm) profiles, sparse ventilated) Material L Emiss (W/mK) konform 3 alu (Si-Leg.) ,000 0,900 X 4 polyamide % GF 0,300 0,900 X 5 EPDM 0,250 0,900 X 2 float 1.0 1,000 0,837-5 Q-lon 0,060 0,900-6 butyle 0,240 0,900 X 6 Swiss Ultimate Effective 0,140 0,900 X SZR L= ,026 0,900 -

$Simulation software: WinIso2D 7.57 Date: 02.12.2013 File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\mullion - U value Garys Swiss Ultimate.$

12 Simulation software: WinIso2D 7.57 Date: File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\mullion - U value Garys Swiss Ultimate.f2d Calculation of the linear thermal transmission coefficient Ψ according to EN ISO Simulation model: Dimensions (width x height): 486,01 x 100,00 mm Number of elements in simulation model: X-direction: 586; Y-direction: 334 Boundary conditions: External: Temperature Θe: 0,00 C Surface resistance Rse: 0,040 m²k/w Internal: Temperature Θi: 20,00 C Surface resistance Rsi 1: 0,130 m²k/w Surface resistance Rsi 2: 0,200 m²k/w Results: Temperature difference dt: 20,00 K Total heat flow Q: 14,404 W/m 2D thermal conductance L2D: 0,720 W/mK Length top/left: U-value top/left: 1,071 W/m²K Length bottom/right: U-value bottom/right: 1,070 W/m²K Ψ-value: 0,068 W/mK

13 Materials: Material R T ( C) Q(gesamt) (m²k/w) (W/m) konform ****ADIABAT**** 0,000 0,000 0,000 1 boundary condition intside 0,13, 0,130 20,000 12,167 X 1 boundary condition outside 0,04, 0,040 0,000-14,400 X 0 C, 80% 1 boundary condition intside 0,20, 0,200 20,000 2,241 X profiles) profiles <=2mm) profiles, sparse ventilated) Material L Emiss (W/mK) konform 3 alu (Si-Leg.) ,000 0,900 X 4 polyamide % GF 0,300 0,900 X 5 EPDM 0,250 0,900 X 2 float 1.0 1,000 0,837-5 Q-lon 0,060 0,900-6 butyle 0,240 0,900 X 6 Super Spacer Standard 0,122 0,900 X SZR L= ,026 0,900-4 polyurethane(pur)-resin ,400 0,900 X 6 Swiss Ultimate Effective 0,140 0,900 X SZR L= ,026 0,900 -

14 Simulation software: WinIso2D 7.57 Date: File: D:\MyDocs from Thermbridge\Therm Output Files\Origin Frames\December 2013\Winiso file\mullion - U value Garys Swiss Ultimate.f2d Calculation of the thermal transmission coefficient U f according to EN ISO : Simulation model: Dimensions (width x height): 486,01 x 100,00 mm Number of elements in simulation model: X-direction: 586; Y-direction: 334 Boundary conditions: External: Temperature Θe: 0,00 C Surface resistance Rse: 0,040 m²k/w Internal: Temperature Θi: 20,00 C Surface resistance Rsi 1: 0,130 m²k/w Surface resistance Rsi 2: 0,200 m²k/w Results: Temperature difference dt: 20,00 K Total heat flow Q: 12,735 W/m 2D thermal conductance L2D: 0,637 W/mK Length 1: U-value 1: 1,031 W/m²K Length 2: U-value 2: 1,031 W/m²K U f-value: 2,289 W/m²K

15 Materials: Material R T ( C) Q(gesamt) (m²k/w) (W/m) konform ****ADIABAT**** 0,000 0,000 0,000 1 boundary condition intside 0,13, 0,130 20,000 12,167 X 1 boundary condition outside 0,04, 0,040 0,000-14,400 X 0 C, 80% 1 boundary condition intside 0,20, 0,200 20,000 2,241 X profiles) profiles <=2mm) profiles, sparse ventilated) Material L Emiss (W/mK) konform 3 alu (Si-Leg.) ,000 0,900 X 4 polyamide % GF 0,300 0,900 X 5 EPDM 0,250 0,900 X 2 float 1.0 1,000 0,837-5 Q-lon 0,060 0,900-6 butyle 0,240 0,900 X 6 Super Spacer Standard 0,122 0,900 X SZR L= ,026 0,900-4 polyurethane(pur)-resin ,400 0,900 X 6 Swiss Ultimate Effective 0,140 0,900 X L= ,026 0,900 -

Customer: Ashton Industrial Sales Ltd. South Road, Harlow Essex CM20 2AR UNITED KINGDOM. Project/Customer: Profilex HM spacer

Page 1 of 11 Customer: Ashton Industrial Sales Ltd. South Road, Harlow Essex CM20 2AR UNITED KINGDOM Project/Customer: Profilex HM spacer Content: U f simulation of profiles in accordance to EN ISO 10077-2