0.61 Layer 1: Guardian RLE 66/27 (e=0.020*, #2) Unit Size: 40-3/4" x 82-3/8" (1035 mm x 2092 mm) (Non-Standard Size) Reference must be made to Report No. D6115.01-301-46, dated 06/11/14 for complete test specimen description and data. 3/16" Layer 2: SERIES/MODEL: Outswing Aluminum Bi-Folding System TYPE: Swinging Door with Frame Standardized Thermal Transmittance (U-Factor) Gap: 0.49" NFRC 102-2010 THERMAL PERFORMANCE TEST REPORT Rendered to: COASTAL INNOVATIVE PRODUCTS 3/16" Summary of Results ZF-S: Super Spacer Premium 90% Argon* Clear Architectural Testing 2524 E. Jensen Ave Fresno, CA 93706 phone: 559-233-8705 fax: 717-764-4129 www.archtest.com
Welcome message from author
This document is posted to help you gain knowledge. Please leave a comment to let me know what you think about it! Share it to your friends and learn new things together.
Transcript
0.61
Layer 1: Guardian RLE 66/27 (e=0.020*, #2)Unit Size: 40-3/4" x 82-3/8" (1035 mm x 2092 mm) (Non-Standard Size)
Reference must be made to Report No. D6115.01-301-46, dated 06/11/14 for complete testspecimen description and data.
3/16"Layer 2:
SERIES/MODEL: Outswing Aluminum Bi-Folding SystemTYPE: Swinging Door with Frame
Standardized Thermal Transmittance (U-Factor)
Gap: 0.49"
NFRC 102-2010 THERMAL PERFORMANCETEST REPORT
Rendered to:
COASTAL INNOVATIVE PRODUCTS
3/16"
Summary of Results
ZF-S: Super Spacer Premium 90% Argon*Clear
Archi tectural Testing
2524 E. Jensen Ave Fresno, CA 93706 phone: 559-233-8705 fax: 717-764-4129 www.archtest.com
Report Number:Test Date:
Report Date:
06/11/14
9412 North Elm Street Suite C
Test Results Summary:
Client
37.8" x 82.3" (960 mm wide x 2090 mm high)
Test Procedure: U-factor tests were performed in a Guarded Hot Box in accordance withNFRC 102-2010, Procedure for Measuring the Steady-State Thermal Transmittance ofFenestration Systems .
Series/Model:
Btu/hr·ft2·F (CTS Method)Standardized U-factor (Ust): 0.61
Outswing Aluminum Bi-Folding System
NFRC Standard Size:
Test Sample Submitted by:
Overall Size:
NFRC 102-2010 THERMAL PERFORMANCE TEST REPORT
D6115.01-301-4604/23/14
Orange, California 92867
Rendered to:
COASTAL INNOVATIVE PRODUCTS
Test Sample Identification:
Swinging Door with FrameType:
40-3/4" x 82-3/8" (1035 mm x 2092 mm) (Non-Standard Size)
Archi tectural Testing
2524 E. Jensen Ave Fresno, CA 93706 phone: 559-233-8705 fax: 717-764-4129 www.archtest.com
Test Sample Description:
*Stated per Client/Manufacturer N/A Non-Applicable
Gap: ZF-S: Super Spacer PremiumClear
Gas Fill Method:
PaintExterior Finish:WhiteExterior Color:
Layer 1:Glazing Information:
Layer 2:
Guardian RLE 66/27 (e=0.020*, #2)0.49"3/16"
3/16"
Glazing Method:
N/A
Coped / Screws / Sealed
D6115.01-301-46
N/ADaylight Opening:
Glazing Method:
Material:40-3/4" x 82-3/8" (Non-Standard Size)AL: Aluminum (Non-thermally broken)
31-3/8" x 71-1/8"
WhiteCorner Joinery:
AL: Aluminum (Non-thermally broken)
PaintInterior Finish:
Panel:Material:
Daylight Opening: ChannelPaint
Interior Color:
Size:
Size:
Page 2 of 8
Frame:
37-3/8" x 78-7/8"
Corner Joinery:Interior Color:
Square Cut / Screws / Sealed
WhitePaint
Exterior Finish:
90% Argon*
Single-Probe Method*
Exterior Color:White Interior Finish:
Architectural Testing
Test Sample Description: (Continued)
Weatherstripping:
Hardware:
Drainage:
D6115.01-301-46
Polypile Bottom rail of the door panel.1 Row
Foam-filled vinyl gasket
Description Quantity Location
Polypile with center fin 2 Rows Lock jamb.
Hinge jamb/stile.
2 Rows
1 Lock stile.
1 Row
Lock jamb.
Foam-filled vinyl gasket
Description
All members of the frame.
Drainage Method Size
No visible weeps.
Quantity Location
Polypile with center fin
Bi-fold hinge 2
1Keeper
Handle with lock mechanism
Page 3 of 8
Location
Hinge stile.
Quantity
1 Row Head.
Architectural Testing
Measured Test Data
Heat Flows1. Total Measured Input into Metering Box (Qtotal) Btu/hr 2. Surround Panel Heat Flow (Qsp) Btu/hr 3. inches4.5. Metering Box Wall Heat Flow (Qmb) Btu/hr 6. EMF vs Heat Flow Equation (equivalent information) 0.0243*EMF + 0.0007. Flanking Loss Heat Flow (Qfl) Btu/hr 8. Net Specimen Heat Loss (Qs) Btu/hr
Areas1. Test Specimen Projected Area (As) ft2
2. Test Specimen Interior Total (3-D) Surface Area (Ah) ft2
3. Test Specimen Exterior Total (3-D) Surface Area (Ac) ft2
4. Metering Box Opening Area (Amb) ft2
5. Metering Box Baffle Area (Ab1) ft2
6. Surround Panel Interior Exposed Area (Asp) ft2
Test Conditions1. Average Metering Room Air Temperature (th) F2. Average Cold Side Air Temperature (tc) F3. Average Guard/Environmental Air Temperature F4. Metering Room Average Relative Humidity %5. Metering Room Maximum Relative Humidity %6. Metering Room Minimum Relative Humidity %7. Measured Cold Side Wind Velocity (Perpendicular Flow) mph8. Measured Warm Side Wind Velocity (Parallel Flow) mph9. Measured Static Pressure Difference Across Test Specimen 0.00" ± 0.04"H2O
Average Surface Temperatures1. Metering Room Surround Panel F2. Cold Side Surround Panel F
Results
2. Standardized Thermal Transmittance of Test Specimen (Ust)Btu/hr·ft2·F0.66
Page 4 of 8D6115.01-301-46
13.16
6.18
-0.4069.81
23.3124.68
74.68Surround Panel Conductance
6.12
72.00
12.66
6.23
Btu/hr·ft2·F0.61
0.04
25.82
66.51
5.00
36.4732.13
1080.6915.72
1. Thermal Transmittance of Test Specimen (Us)
0.20
Thermal Transmittance (U-factor)
1202.26
Btu/hr·ft2·F0.0357
31.17Surround Panel Thickness
Architectural Testing
Calculated Test Data
CTS Method1. Warm Side Emittance of Glass (e1)2. Cold Side Emittance of Glass3. Warm Side Frame Emittance*4. Cold Side Frame Emittance*5. Warm Side Sash/Panel/Vent Emittance*6. Cold Side Sash/Panel/Vent Emittance*7. Warm Side Baffle Emittance (eb1)8. Cold Side Baffle Emittance (eb2)9. Equivalent Warm Side Surface Temperature F
10. Equivalent Cold Side Surface Temperature F11. Warm Side Baffle Surface Temperature F12. Cold Side Baffle Surface Temperature F13. Measured Warm Side Surface Conductance (hh)14. Measured Cold Side Surface Conductance (hc)15. Test Specimen Thermal Conductance (Cs)16. Convection Coefficient (Kc) Btu/(hr·ft2·F1.25)17. Radiative Test Specimen Heat Flow (Qr1) Btu/hr18. Conductive Test Specimen Heat Flow (Qc1) Btu/hr19. Radiative Heat Flux of Test Specimen (qr1)20. Convective Heat Flux of Test Specimen (qc1)21. Standardized Warm Side Surface Conductance (hsth)22. Standardized Cold Side Surface Conductance (hstc)23. Standardized Thermal Transmittance (Ust)
Test Duration1.2.
*Stated per NFRC 101
0.900.90
0.30
Thermal Transmittance (U-factor)
D6115.01-301-46
0.90
The reported Standardized Thermal Transmittance (Ust) was determined using CTS Method,per Section 8.2(A) of NFRC 102.
3.
The test parameters were considered stable for two consecutive four hour test periodsfrom 00:09 hours, 04/23/14 to 08:09 hours, 04/23/14.
1.22 Btu/hr·ft2·F
71.38
Btu/hr·ft2·FBtu/hr·ft2·F
1.47
0.84
564.42
0.900.84
Page 5 of 8
Btu/hr·ft2·F5.28
1.56
516.26
22.1524.21
5.18
0.92
Btu/hr·ft2·FBtu/hr·ft2·F
8.56
N/A38.25
N/A
Btu/hr·ft2·F0.61
The environmental systems were started at 15:48 hours, 04/22/14.
The thermal performance test results were derived from 04:09 hours, 04/23/14 to 08:09hours, 04/23/14.
Btu/hr·ft2·F
Architectural Testing
Glass collapse determined using a digital glass and air space meter
Required annual calibrations for the Architectural Testing Inc. 'thermal test chamber' (ICN004287) in Fresno, California were last conducted in May 2013 in accordance withArchitectural Testing Inc. calibration procedure. A CTS Calibration verification was performedMarch 2014. A Metering Box Wall Transducer and Surround Panel Flanking LossCharacterization was performed September 2013.
The test sample was installed in a vertical orientation, the exterior of the specimen was exposedto the cold side. The direction of heat transfer was from the interior (warm side) to the exterior(cold side) of the specimen. The ratings were rounded in accordance to NFRC 601, NFRC Unitand Measurement Policy. The data acquisition frequency is 5 minutes.
“This test method does not include procedures to determine the heat flow due to either airmovement through the specimen or solar radiation effects. As a consequence, the thermaltransmittance results obtained do not reflect performances which are expected from fieldinstallations due to not accounting for solar radiation, air leakage effects, and the thermal bridgeeffects that have the potential to occur due to the specific design and construction of thefenestration system opening. The latter can only be determined by in-situ measurements.Therefore, it is important to recognize that the thermal transmittance results obtained from thistest method are for ideal laboratory conditions and should only be used for fenestration productcomparisons and as input to thermal performance analyses which also include solar, air leakageand thermal bridge effects.”
ANSI/NCSL Z540-2-1997 type B uncertainty for this test was 1.71%.
Center gap width at laboratory ambientconditions on day of testing
The sample was inspected for the formation of frost or condensation, which may influence thesurface temperature measurements. At the conclusion of the test, a layer of frost was present onall members of the frame and panel.
Estimated center gap width upon receipt ofspecimen in laboratory (after stabilization)
Edge Gap Width 0.49"
0.54"
0.45"Center gap width at test conditions
0.54"
Page 6 of 8
Glazing Deflection:
D6115.01-301-46
Door
Architectural Testing
For ARCHITECTURAL TESTING, INC.
Tested By: Reviewed By:
William Simon Smeds Kenny C. WhiteTechnician Laboratory Manager
Individual-In-Responsible-Charge
WSS:msD6115.01-301-46
Attachments (pages): This report is complete only when all attachments listed are included.
Architectural Testing, Inc. is accredited by the International Accreditation Service (IAS) under thespecific test methods listed under lab code TL-144, in accordance with the recognizedInternational Standard ISO/IEC 17025:2005. The laboratory’s accreditation or test report in noway constitutes or implies product certification, approval, or endorsement by IAS.
CTS Calibration Data (1)
This report does not constitute certification of this product nor an opinion or endorsement bythis laboratory. It is the exclusive property of the client so named herein and relates only to thespecimen tested. This report may not be reproduced, except in full, without the writtenapproval of Architectural Testing, Inc.
Appendix-D:
Surround Panel Wiring Diagram (1)Appendix-A: Appendix-B:
D6115.01-301-46
"Ratings included in this report are for submittal to an NFRC licensed IA for certificationpurposes and are not meant to be used for labeling purposes. Only those values identified on avalid Certification Authorization Report (CAR) are to be used for labeling purposes."
Page 7 of 8
Architectural Testing, Inc. will service this report for the entire test record retention period. Testrecords that are retained such as detailed drawings, datasheets, representative samples of testspecimens, or other pertinent project documentation will be retained by Architectural Testing,Inc. for the entire test record retention period. The test record retention end date for this reportis April 23, 2018.
Drawings (13)Baffle Wiring Diagram (1)Appendix-C:
Architectural Testing
This report produced from controlled document template ATI 00025(a), revised 03/14/2013.
All
D6115.01-301-46Page 8 of 8
0
Revision(s)
Revision Log
Page(s)
06/11/14 Original Report Issue. Work requested by Mr.Jeff Jarvis of Coastal Innovative Products
Date
Rev. #
Architectural Testing
CTS Test DateCTS Size ft2
CTS Glass/Core ConductanceWarm Side Air Temperature FCold Side Air Temperature FWarm Side Average Surface Temperature FCold Side Average Surface Temperature FConvection Coefficient (Kc)Measured Cold Side Surface Conductance (hc)Measured Thermal Transmittance
Btu/(hr·ft2·F1.25)Btu/hr·ft2·F
3.83
9. 5.1810. 0.30 Btu/hr·ft2·F
7.8. 0.30
5. -0.116. 54.89
3.
D6115.01-301-46Appendix A: CTS Calibration Data
Btu/hr·ft2·F4.
1.2. 21.53
06/22/13
69.800.40
+1 +2 +3
+4 +5
+6 +7 +8
D6115.01-301-46Appendix B: Surround Panel Wiring Diagram
+1 +2 +3
+4 +5 +6
+7 +8 +9
+10 +11 +12
+13 +14 +15
D6115.01-301-46Appendix C: Baffle Wiring Diagram
Appendix D: DrawingsD6115.01-301-46
Related Documents
