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42 11th ST - ENERGY SHEETS A An EZICC EVALUATION Most Widely Accepted and Trusted SERVICE ICC-ES Report ESR-1826 Reissued 02/2016 ICC-ES I (800) 423-6587 I (562) 699-0543 I www.icc-es.org This report is subject to renewal 02/2018. DIVISION: 07 00 00—THERMAL AND MOISTURE PROTECTION SECTION: 07 21 00—THERMAL INSULATION FILE COPY REPORT HOLDER: ICYNENE, INC. 6747 CAMPOBELLO ROAD MISSISSAUGA, ONTARIO L5N 2L7 CANADA EVALUATION SUBJECT: ICYNENE CLASSIC, CLASSIC MAX, CLASSIC ECO AND CLASSIC PLUS ICC ICC ICC 4 PMG LISTED �„` Look for the trusted marks of Conformity! M. "2014 Recipient of Prestigious Western States Seismic Policy Council 1...Cii- (WSSPC)Award in Excellence" A Subsidiary of co O 'ii Ca scc ICC-ES Evaluation Reports are not to be construed as representing aesthetics or any other attributes not C�.� specifically addressed, nor are they to be construed as an endorsement of the subject of the report or a ANSI recommendation for its use. There is no warranty by ICC Evaluation Service, LLC, express or implied, as to any finding or other matter in this report, or as to any product covered by the report. '"0°"�` "�'°°" "°�'°"�" Copyright©2016 ICC Evaluation Service, LLC. All rights reserved. PARAIS PAPA fLi ICC EVALUATION �S SERVICE Most Widely Accepted and Trusted ICC-ES Evaluation Report ESR-1826 Reissued February 2016 This report is subject to renewal February 2018. www.icc-es.orq I (800) 423-6587 I (562) 699-0543 A Subsidiary of the International Code Council® DIVISION: 07 00 00—THERMAL AND MOISTURE 2.0 USES PROTECTION Icynene Classic, Classic Max, Classic Eco and Classic Section: 07 21 00—Thermal Insulation Plus are used to provide thermal insulation in buildings and to seal areas such as plumbing and conduit penetrations REPORT HOLDER: against air infiltration. The insulations are for use in wall cavities and floor assemblies; and in attic and crawl space ICYNENE, INC. installations as described in Section 4.4. 6747 CAMPOBELLO ROAD MISSISSAUGA, ONTARIO L5N 2L7 The Classic, Classic Max and Classic Eco insulations are CANADA for use in Type V construction under the IBC and dwellings (905)363-4040 under the IRC; fire-resistance-rated construction when www.icvnene.com installed in accordance with Section 4.5; and in Types I through IV construction when installed in accordance with EVALUATION SUBJECT: Section 4.6. The Classic Plus insulation are for use in Type V-B ICYNENE CLASSIC, CLASSIC MAX, CLASSIC ECO AND construction under the IBC and nonfire-resistance-rated CLASSIC PLUS construction under the IRC. 1.0 EVALUATION SCOPE The attributes of the insulations have been verified as conforming to the provisions of ICC 700-2008 Section 1.1 Compliance with the following codes: 703.2.1.1.1(c) as an air impermeable insulation. Note that • 2012 and 2009 International Building Code®(IBC) decisions on compliance for those areas rest with the user • 2012 and 2009 International Residential Code®(IRC) of this report. The user is advised of the project-specific provisions that may be contingent upon meeting specific • 2012 and 2009 International Energy Conservation conditions, and the verification of those conditions is Code®(IECC) outside the scope of this report. These codes or standards • 2013 Abu Dhabi International Building Code(ADIBC)1 often provide supplemental information as guidance. The ADIBC is based on the 2009 IBC.2009 IBC code sections referenced 3.0 DESCRIPTION in this report are the same sections in the ADIBC. 3.1 General: • Other Codes(see Section 8.0) 3.1.1 Classic and Classic Max: Icynene Classic and Properties evaluated: Classic Max are low-density, open-cell, polyurethane foam plastic insulations and air barrier systems that are • Surface burning characteristics 100 percent water-blown with an installed nominal • Physical properties density of 0.5 pcf (8 kg/m3). The insulations are two- component, spray-applied products. The two components • Thermal performance(R-values) of the insulation are polymeric isocyanate (A-Component, • Attic and crawl space installation also known as Base Seal®) and proprietary resin (B-Component, Classic or Classic Max Resin). When • Fire resistance stored at temperatures between 50°F (10°C) and 100°F • Air permeability (38°C),the components have a shelf life of six months. • Noncombustible construction 3.1.2 Classic Eco: The Icynene Classic Eco foam plastic insulation is two-component, low-density, open cell, spray- 1.2 Evaluation to the following green standard: applied, foam plastic with a nominal density of • 2008 ICC 700 National Green Building StandardTM (ICC 0.5 pcf (8 kg/m3). The polyurethane foam is produced by 700-2008) combining a polymeric isocyanate (A component) and proprietary resin, Classic Eco (B component). When stored Attributes verified: at temperatures between 50°F (10°C) and 100°F (38°C), • See Section 2.0 the components have a shelf life of six months. /I.('•EN liralaation Reporis are not to be construed as representing aesthetics or any other attributes out specifically addressed,nor are they 10 be construed ANSI as an endorsement of the subject of the report or a reconuuendauon for its use.Mere is no warranty by 1('('Evaluation Service,l.LC,express or implied as to any finding or other mater in thrs report,or a,to any product covered by the report. aM"llli4 Copyright©2016 ICC Evaluation Service,LLC. All rights reserved. Page 1 of 8 ESR-1826 I Most Widely Accepted and Trusted Page 2 of 8 3.1.3 Classic Plus: The Icynene Classic Plus foam 3.5.2 DC 315: DC 315 intumescent coating is a water- plastic insulation is two-component, low density, open cell, based coating supplied in 5-gallon (19L) pails and spray-applied, foam plastic with a nominal density of 55-gallon (208L) drums. The coating material has a shelf 0.7 pcf(11 kg/m3). The polyurethane foam is produced by life of 24 months when stored in factory-sealed containers combining a polymeric isocyanate (A component) and at temperatures between 41°F (5°C)and 95°F (35°C). proprietary resin, Classic Plus (B component). When 4.0 INSTALLATION stored at temperatures between 50°F (10°C) and 100°F (38°C),the components have a shelf life of twelve months. 4.1 General: 3.2 Surface Burning Characteristics: The manufacturer's published installation instructions and 3.2.1 Classic and Classic Max: When tested in this report must be strictly adhered to and a copy of these accordance with ASTM E84/UL 723, at a thickness of instructions and this evaluation report must be available on 6 inches (152 mm) and a nominal density of 0.5 pcf the jobsite at all times during installation. (8 kg/m3), Icynene Classic and Classic Max have a flame 4.2 Application: spread index of 25 or less and a smoke developed index 4.2.1 General: Icynene Classic, Classic Max, Classic Eco of 450 or less.Thicknesses of up to 71/2 inches(190.5 mm) for wall cavities and 111/2 inches (292 mm) for ceiling and Classic Plus foam plastic insulations must be applied cavities are recognized based on room corner fire testing on the jobsite using two component, 1-to-1 ratio, spray in accordance with NFPA 286, when covered with equipment specified by Icynene, Inc. The foam plastic must not be sprayed onto a substrate that is wet, or minimum 1/2-inch-thick (13 mm) gypsum board or an covered with frost or ice, loose scales, rust, oil or grease. equivalent thermal barrier complying with the applicable The foam plastic insulation must not be used in electrical code. Greater thicknesses of insulation are recognized as outlet or junction boxes or in contact with rain or water, described in Section 4.4.1.2.1. and must be protected from the weather during and 3.2.2 Classic Eco: When tested in accordance with after application. Where the insulation is used as air- ASTM E84/UL 723, at a thickness of 6 inches (152 mm) impermeable insulation, such as in unvented attic spaces and a nominal density of 0.5 pcf(8 kg/m3), Icynene Classic regulated by IRC Section R806, the insulation must be Eco has a flame spread index of 25 or less and a smoke- installed at a minimum thicknesses noted in Section 3.4. developed index of 450 or less. Greater than 6-inch The insulation can be installed in one pass to the (152 mm) thicknesses of insulation are recognized, based maximum thickness. Where multiple passes are required, on the flame spread index of 25 or less, when the the cure time between passes is negligible. insulation is covered with minimum 1/2-inch-thick (13 mm) 4.2.2 Classic and Classic Max: The insulation must be gypsum wallboard or equivalent thermal barrier complying used in areas where the maximum service temperature is with the applicable code. no greater than 180°F (82°C). The insulation must be 3.2.3 Classic Plus: When tested in accordance with applied when the temperature is at or above 14°F (-10°C) ASTM E84/UL 723, at a thickness of 4 inches (152 mm) and be protected from the weather during and after and a nominal density of 0.7 pcf (11 kg/m3), Icynene application. Classic Plus has a flame spread index of 25 or less and a 4.2.3 Classic Eco: The insulation may be used in areas smoke developed index of 450 or less. Greater than where the maximum service temperature is no greater than 4-inch (102 mm) thicknesses of insulation are recognized, 180°F (82°C). The insulation must be applied when the based on the flame spread index of 25 or less, when the temperature is at or above 14°F (-10°C) and be protected insulation is covered with minimum 1/2-inch-thick (13 mm) from the weather during and after application. gypsum wallboard or equivalent thermal barrier complying with the applicable code. 4.2.4 Classic Plus: The insulation may be used in areas 3.3 Thermal Resistance: where the maximum service temperature is no greater than 180°F (82°C). The insulation must be applied when the Icynene Classic, Classic Max, Classic Eco and Classic temperature is at or above 14°F (-10°C) and be protected Plus have thermal resistance (R-values) at a mean from the weather during and after application. temperature of 75°F (24°C)as shown in Table 1. 4.3 Thermal Barrier: 3.4 Air Permeability: 4.3.1 Classic and Classic Max: Icynene spray-applied foam plastic insulations are 4.3.1.1 Application with a Prescriptive Thermal considered air-impermeable insulation in accordance with Barrier: Icynene Classic and Classic Max foam plastic 2012 IRC Sections R202 and R806.5 and 2009 IRC insulations must be separated from the interior of the Sections R202 and R806.4, at the following thicknesses: building by an approved thermal barrier, such as '/2 inch • Classic and Classic Max: Minimum, 3 inches (76 mm) (12.7 mm) gypsum wallboard installed using mechanical based on testing in accordance with ASTM E2178. fasteners in accordance with the applicable code, or an • Classic Eco: Minimum, 51/2 inches(140 mm) based on equivalent 15 minute thermal barrier complying with the testing in accordance with ASTM E283. applicable code. When installation is within an attic or crawl space as described in Section 4.4, a thermal barrier • Classic Plus: Minimum, 2 inches (51 mm) based on is not required between the foam plastic and the attic or testing in accordance with ASTM E2178. crawl space, but is required between the foam plastic 3.5 Intumescent Coatings: insulation and the interior of the building. Thicknesses of up to 71/2 inches (190.5 mm) for wall cavities and 3.5.1 No Burn Plus XD: No Burn Plus XD intumescent 111/2 inches (292 mm) for ceiling cavities are recognized coating is a latex-based coating supplied in 1-gallon (4L) based on room corner fire testing in accordance with NFPA and 5-gallon (19L) pails and 55-gallon (208 L) drums. The 286, when covered with minimum 1/2-inch-thick (13 mm) coating material has a shelf life of 12 months when stored gypsum board or equivalent thermal barrier complying with in factory-sealed containers at temperatures between 40°F the applicable code. (4.4°C)and 90°F(32.2°C). ESR-1826 I Most Widely Accepted and Trusted Page 3 of 8 4.3.1.2 Application without a Prescriptive Thermal 2. There are no interconnected attic, crawl space or Barrier or Ignition Barrier: The prescriptive 15-minute basement areas. thermal barrier or ignition barrier may be omitted when 3. Air in the attic or crawl space is not circulated to other installation is in accordance with this section. The parts of the building. insulation and coating may be spray-applied to the interior facing of walls, the underside or roof sheathing of roof 4. Combustion air is provided in accordance with IMC rafters, and in crawl spaces, and may be left exposed as Section 701. an interior finish without a prescribed 15-minute thermal 5. Attic ventilation is provided when required by IBC barrier or ignition barrier. The thickness of the foam plastic Section 1203.2 or IRC Section R806, except when applied to the underside of the roof sheathing must not air-impermeable insulation is permitted in unvented exceed 14 inches (356 mm). The thickness of the spray attics in accordance with 2012 IRC Section R806.5 or foam insulation applied to vertical wall surfaces must not 2009 IRC Section R806.4,as applicable. exceed 6 inches (152 mm). The foam plastic must be covered on all surfaces with DC 315 coating at a minimum 6. Under-floor(crawl space)ventilation is provided when thickness of 20 wet mils[13 dry mils (0.33 mm)], applied at required by IBC Section 1203.3 or IRC Section a rate of 1.25 gallons (4.7 L) per 100 square feet (9.2 m2). R408.1, as applicable. The coating must be applied over the insulation in 4.4.1.2.1 Attics - Classic and Classic Max: In attics, accordance with the coating manufacturer's instructions Icynene Classic and Classic Max foam plastic insulations and this report. Surfaces to be coated must be dry, clean, may be spray-applied to the underside of the roof and free of dirt, loose debris and other substances that sheathing and/or rafters, as described in this section. The could interfere with adhesion of the coating. The coating is thickness of the foam plastic applied to the underside of applied in one coat with low-pressure airless spray the roof sheathing must not exceed 14 inches (356 mm). equipment. The thickness of the spray foam insulation applied 4.3.2 Classic Eco: to vertical wall surfaces must not exceed 5.5 inches (140 mm). The insulation must be covered on all surfaces 4.3.2.1 Application with a Prescriptive Thermal Barrier: Icynene Classic Eco polyurethane foam plastic with one of the coatings described in Section 3.5. The insulation must be separated from the interior of the coating must be applied over the insulation in accordance building by must approved separated from m the of interior 1/2-inch-thick with the coating manufacturer's instructions and this report. Surfaces to be coated must be dry, clean, and free of dirt, (13 mm) gypsum wallboard or an equivalent 15-minute loose debris and other substances that could interfere with thermal barrier complying with, and installed in accordance with, IBC Section 2603.4 or IRC Section R316.4, as adhesion of the coating. The coating is applied in one coat applicable. with low-pressure airless spray equipment. The coating must be applied to a thickness as follows: 4.3.3 Classic Plus: • No Burn Plus XD at a minimum thickness of 6 wet mils 4.3.3.1 Application with a Prescriptive Thermal (0.15 mm) [4 dry mils (0.1 mm) dry film thickness], Barrier: Icynene Classic Plus polyurethane foam plastic applied at a rate of 0.4 gallon (1.5 L) per 100 square insulation must be separated from the interior of the feet(9.2 m2). building by an approved thermal barrier of 1/2-inch-thick • DC 315 at a minimum thickness of 4 wet mils (0.1 mm) (13 mm) gypsum wallboard or an equivalent 15-minute [3 dry mils], applied at a rate of 0.3 gallon (1.1 L) per thermal barrier complying with, and installed in accordance 100 square feet(9.2 m2). with, IBC Section 2603.4 or IRC Section R316.4, as applicable. The coatings must be applied when ambient and 4.4 Attics and Crawl Spaces: substrate temperature is at least 60°F (16°C) and no more than 95°F (35°C). All other surfaces (including glass) must 4.4.1 Classic and Classic Max: be protected against damage from the coating. The 4.4.1.1 Application with a Prescriptive Ignition Barrier: insulation may be installed in unvented attics when the When Icynene Classic and Classic Max foam plastic foam plastic is applied at a minimum thickness of insulations are installed within attics where entry is made 3.5 inches (89 mm) as described in this section in only for service of utilities, an ignition barrier must be accordance with 2012 IRC Section R806.5 or 2009 IRC installed in accordance with IBC Section 2603.4.1.6 and Section R806.4,as applicable. IRC Sections R316.5.3 and R316.5.4, as applicable. The 4.4.1.2.2 Attics-Classic Max: When Classic Max is ignition barrier must be consistent with the requirements applied in unvented attics conforming to 2012 IRC Section for the type of construction required by the applicable code R806.5 or 2009 IRC Section R806.4, the insulation may be and must be installed in a manner so that the foam plastic applied to the underside of roof sheathing and/or rafters to insulation is not exposed. The Classic or Classic Max a minimum thickness of 31/2 inches (90 mm) and may be insulation may be installed in unvented attics when the applied to vertical wall surfaces to a minimum thickness of foam plastic is applied at a minimum thickness of 3 inches 3 /2 inches (90 mm). Maximum thickness on the underside (76 mm) in accordance with 2012 IRC Section R806.5 or of roof sheathing or on vertical wall surfaces is 20 inches 2009 IRC Section R806.4, as applicable. (508 mm). The insulation may be left exposed to the attic 4.4.1.2 Application without a Prescriptive Ignition without a prescriptive ignition barrier or an intumescent Barrier: Where Icynene Classic and Classic Max foam coating. plastic insulations are installed in an attic or crawl space The attic must have attic access complying with IRC without a prescriptive ignition barrier, in accordance with Section R807, horizontally placed in the floor, and opening Sections 4.4.1.2.1, 4.4.1.2.2, 4.4.1.2.3 and 4.4.1.2.4, the outward toward the living space. Items penetrating the roof following conditions apply: deck or walls, such as skylight wells and vents, must be 1. Entry to the attic or crawl space is only for service of covered with a minimum of 3'/2 inches (90 mm) of the utilities and no storage is permitted. Classic Max insulation. 4.4.1.2.3 Crawl Spaces: In crawl spaces, Icynene ESR-1826 I Most Widely Accepted and Trusted Page 4 of 8 Classic and Classic Max insulations may be spray-applied and this report. Surfaces to be coated must be dry, clean, to vertical walls and the underside of floors, as described in and free of dirt, loose debris and other substances that this section. The thickness of the foam plastic applied to could interfere with adhesion of the coating. The coating is the underside of the floors must not exceed 14 inches applied in one coat with low-pressure airless spray (356 mm). The thickness of the spray foam plastic equipment. The coating must be applied to a thickness as insulation applied to vertical wall surfaces must not exceed follows: 31/2 inches (88.9 mm). The foam plastic does not require • No Burn Plus XD at a minimum thickness of 10 wet mils an ignition barrier or a coating. (0.3 mm) [6 dry mils (0.2 mm)], applied at a rate of 4.4.1.2.4 Use on Attic Floors: When used on attic floors, 0.63 gallon (2.4 L)per 100 square feet(9.2 m2) Icynene Classic and Classic Max foam plastic insulations • DC 315 at a minimum thickness of 8 wet mils (0.2 mm) may be installed at a maximum thickness of 111/2 inches [6 dry mils (0.2 mm)], applied at a rate of 0.5 gallon (292 mm) between joists in attic floors.The insulation must (1.9 L)per 100 square feet(9.2 m2) be separated from the interior of the building by an approved thermal barrier. The coatings specified in Section The coating must be applied when ambient and 4.4.1.2.1 and the ignition barrier in accordance with IBC substrate temperature is at least 60°F (16°C) and no more Section 2603.4.1.6 and IRC Section R316.5.3, may be than 95°F (35°C). All other surfaces (including glass) must omitted. be protected against damage from the coating. 4.4.2 Classic Eco: Icynene Classic Eco insulation may be installed in 4.4.2.1 Application with a Prescriptive Ignition Barrier: unvented attics when the foam plastic is applied at a When Icynene Classic Eco is installed within attics or crawl minimum thickness of 51/2 inches(140 mm)as described in spaces where entry is made only for service of utilities, an this section, in accordance with 2012 IRC Section R806.5 ignition barrier must be installed in accordance with IBC or 2009 IRC Section R806.4, as applicable. Section 2603.4.1.6 and IRC Sections R316.5.3 and 4.4.2.2.2 Crawl Spaces: In crawl spaces, Icynene R316.5.4, as applicable. The ignition barrier must be Classic Eco insulation may be spray-applied to vertical consistent with the requirements for the type of walls and the underside of floors, as described in this construction required by the applicable code and must be section. The thickness of the foam plastic applied to the installed in a manner so that the foam plastic insulation is underside of the floors must not exceed 14 inches not exposed. Icynene Classic Eco may be installed in (356 mm). The thickness of the spray foam plastic unvented attics when the foam plastic is applied at a insulation applied to vertical wall surfaces must not exceed minimum thickness of 5.5 inches (140 mm) in accordance 31/2 inches (88.9 mm). The foam plastic does not require with 2012 IRC Section R806.5 or 2009 IRC Section an ignition barrier or a coating. R806.4,as applicable. 4.4.2.2.3 Use on Attic Floors: Icynene Classic Eco 4.4.2.2 Application without a Prescriptive Ignition insulation may be installed at a maximum thickness of Barrier: Where Icynene Classic Eco insulation is installed 51/2 inches (152 mm) between joists in attic floors when in accordance with Sections 4.4.2.2.1, 4.4.2.2.2 and covered with one of the coatings applied as described in 4.4.2.2.3,the following conditions apply: Section 4.4.2.2.1. The insulation must be separated from 1. Entry to the attic or crawl space is to service utilities, the interior of the building by an approved thermal barrier. and no storage is permitted. 4.4.3 Classic Plus: 2. There are no interconnected attic or crawl space 4.4.3.1 Application with a Prescriptive Ignition Barrier: areas. When Icynene Classic Plus is installed up to a maximum 3. Air in the attic or crawl space is not circulated to other thickness of 4 inches (102 mm) within attics or crawl parts of the building. spaces where entry is made only for service of utilities, an ignition barrier must be installed in accordance with IBC 4. Combustion air is provided in accordance with IMC Section 2603.4.1.6 and IRC Sections R316.5.3 and Section 701. R316.5.4, as applicable. The ignition barrier must be 5. Attic ventilation is provided when required by IBC consistent with the requirements for the type of Section 1203.2 or IRC Section R806, except when construction required by the applicable code and must be air-impermeable insulation is permitted in unvented installed in a manner so that the foam plastic insulation is attics in accordance with 2012 IRC Section R806.5 or not exposed. Icynene Classic Plus may be installed in 2009 IRC Section R806.4,as applicable. unvented attics when the foam plastic is applied at a minimum thickness of 2 inches (51 mm) in accordance 6. Under-floor(crawl space) ventilation is provided when with 2012 IRC Section R806.5 or 2009 IRC Section required by IBC Section 1203.3 or IRC Section R806.4,as applicable. R408.1,as applicable. 4.4.3.2 Application without a Prescriptive Ignition 4.4.2.2.1 Attics and Crawl Spaces: In attics and crawl Barrier: Where Icynene Classic Plus insulation is installed spaces, Icynene Classic Eco insulation may be spray- in accordance with Sections 4.4.3.2.1, 4.4.3.2.2, and applied to the underside of the roof sheathing and/or 4.4.3.2.3,the following conditions apply: rafters, the underside of wood floors, and vertical surfaces, as described in this section. The thickness of the foam 1. Entry to the attic or crawl space is to service utilities, plastic applied to the underside of the top of the space and no storage is permitted. must not exceed 131/2 inches (343 mm). The thickness of 2. There are no interconnected attic or crawl space the spray foam plastic insulation applied to vertical wall areas. surfaces must not exceed 51/2 inches (140 mm). The foam plastic must be covered on all surfaces with one of the 3. Air in the attic or crawl space is not circulated to other coatings described in Section 3.5. The coating must be parts of the building. applied over the Icynene Classic Eco insulation in 4. Combustion air is provided in accordance with IMC accordance with the coating manufacturer's instructions Section 701. ESR-1826 I Most Widely Accepted and Trusted Page 5 of 8 5. Attic ventilation is provided when required by IBC Max insulation nominally 2 inches(51 mm)thick. Section 1203.2 or IRC Section R806, except when Axial loads applied to the wall assembly must be limited air-impermeable insulation is permitted in unvented to the least of the following: attics in accordance with 2012 IRC Section R806.5 or 2009 IRC Section R806.4,as applicable. • 1,805 pounds(8029 N) per stud. 6. Under-floor(crawl space)ventilation is provided when • Design stress of 0.78 F'c. required by IBC Section 1203.3 or IRC Section • Design stress of 0.78 F'c at a maximum le/d of 33. R408.1,as applicable. 4.5.1.2 Assembly 2 (Limited Load-bearing Wood Stud 4.4.3.2.1 Attics: In attics, Icynene Classic Plus insulation Wall): Minimum nominally 2-by-4 [11/2 by 31/2 inches may be spray-applied to the underside of the roof (38 mm by 89 mm)] southern pine (G = 0.55), No. 2 grade sheathing and/or rafters, the underside of wood floors, and studs spaced 16 inches (406 mm) on center with two vertical surfaces, as described in this section. The layers of 1/2-inch-thick (12.7 mm) Type X gypsum thickness of the foam plastic applied to the underside of wallboard installed vertically with joints staggered on each the top of the space must not exceed 14 inches(356 mm). face, attached with 8d box nails, 21/2 inches (64 mm) long The thickness of the spray foam plastic insulation applied and spaced 7 inches (178 mm) on center along the studs to vertical wall surfaces must not exceed 8 inches for the face layer and 6d cement coated box nails, 2 inches (203 mm). The foam plastic insulation must be covered on (51 mm) long and spaced 24 inches (610 mm) on center all exposed surfaces with DC315 intumescent coating at a along the studs. The stud cavity contains Icynene Classic minimum thickness of 4 wet mils (0.1 mm) [3 dry mils or Classic Max insulation nominally 2 inches(51 mm)thick. (0.08 mm)], applied at a rate of 0.25 gallon (0.95 L) per 100 square feet (9.2 m2). The coating must be applied Axial loads applied to the wall assembly must be limited over the Icynene Classic Plus insulation in accordance with to the least of the following: the coating manufacturer's instructions and this report. • 1,805 pounds(8029 N) per stud. Surfaces to be coated must be dry, clean, and free of dirt, loose debris and other substances that could interfere with • Design stress of 0.78 F'c. adhesion of the coating. The coating is applied in one coat Design stress of 0.78 F'c at a maximum le/d of 33. •with low-pressure airless spray equipment. The coating must be applied when ambient and 4.5.1.3 Assembly 3 (Floor/Ceiling): Minimum nominally substrate temperature is at least 60°F (16°C) and no more 2-by-10 [11/2 by 91/4 inches (38 mm by 235 mm)] Douglas than 95°F (35°C). All other surfaces (including glass) must fir, No. 2 grade wood joists spaced 24 inches (610 mm)on be protected against damage from the coating. center, with minimum 1-by-3 [3/4 by 21/2 inches (19.1 by 64 mm)] spruce bridging at mid-span. Floor decking Icynene Classic Plus insulation may be installed in must be minimum 1/2-inch-thick (12.7 mm) exterior grade unvented attics when the foam plastic is applied at a plywood installed perpendicular to joists and fastened with minimum thickness of 2 inches (51 mm) as described in 2-inch-long (51 mm) ring shank nails 6 inches(152 mm)on this section, in accordance with 2012 IRC Section R806.5 center at the joints and 12 inches (305 mm) on center at or 2009 IRC Section R806.4, as applicable. the intermediate joists. Plywood joints must occur over 4.4.3.2.2 Crawl Spaces: In crawl spaces, Icynene joists. Icynene Classic or Classic Max insulation must be Classic Plus insulation may be spray-applied to vertical applied to the underside of the plywood deck between the walls and the underside of floors, as described in this joists to a depth of 5 inches (127 mm). Two layers of section. The thickness of the foam plastic applied to the minimum 5/8-inch-thick (15.9 mm), Type X gypsum underside of the floors must not exceed 14 inches wallboard must be attached perpendicular to the joists on (356 mm). The thickness of the spray foam plastic the ceiling side of the assembly. The first layer must be insulation applied to vertical wall surfaces must not exceed attached with 11/4-inch-long (32 mm), Type W drywall 8 inches (203 mm). The insulation must be covered with screws, spaced 24 inches (610 mm) on center. The DC-315 coating is described in Section 4.4.3.2.1. second layer must be applied perpendicular to the joists, offset 24 inches(610 mm)from the base layer.The second 4.4.3.2.3 Use on Attic Floors: Icynene Classic Plus layer must be attached with 2-inch-long (51 mm), Type S insulation may be installed at a maximum thickness of drywall screws spaced 12 inches (305 mm) on center. 13 inches (330 mm) between joists in attic floors. The Additional fasteners must be installed along the butt joints insulation must be separated from the interior of the of the second layer, securing the two layers together. building by an approved thermal barrier. The insulation These fasteners must be 1'/2-inch-long (38 mm), Type G does not require an ignition barrier or a coating. drywall screws placed 2 inches (51 mm) back from each 4.5 One-hour Fire-resistance-rated Assemblies: end of the butt joint and spaced 12 inches (305 mm) on 4.5.1 Classic and Classic Max: center. The wallboard joints on the exposed side must be treated with paper tape embedded in joint compound and 4.5.1.1 Assembly 1 (Limited Load-bearing Wood Stud topped with an added coat of compound, and the fastener Wall): Minimum nominally 2-by-4 [11/2 by 31/2 inches heads must be coated with joint compound in accordance (38 mm by 89 mm)] southern pine (G =0.55), No. 2 grade with ASTM C840 or GA-216. studs spaced 16 inches (406 mm) on center with a base 4.5.1.4 Assembly 4(Non-loadbearing Steel Stud Wall): layer of /2-inch-thick (12.7 mm) wood fiber sound board Nominally 6-inch-deep (152.4 mm), No. 18 gage, installed horizontally on each face with vertical joints galvanized steel studs spaced 16 inches (406.4 mm) on located over the studs,attached with 6d box nails, 2 inches center, are friction fit into No. 18 gage galvanized steel (51 mm) long and spaced 24 inches (610 mm) on center floor and ceiling track with a layer of 5/8-inch-thick along the studs, and a second layer of 5/8-inch-thick (15.9 yp gypsum board applied to the interior (15.9 mm)Type X gypsum wallboard installed vertically on 15.9 mm),Type e X pp side with the long edge parallel to steel studs and secured each face, attached with 8d box nails, 21/2 inches (64 mm) using No. 6, 11/4-inch-long (31.7 mm), self- drilling drywall long and spaced 7 inches (178 mm) on center along the screws spaced 8 inches (203 mm) on center around the studs. The stud cavity contains Icynene Classic or Classic ESR-1826 I Most Widely Accepted and Trusted Page 6 of 8 ' perimeter and 12 inches (305 mm) on center in the field. Optional: It is permitted to add code-complying EPS, The gypsum board joints must be treated with vinyl or XPS, foil-faced, rigid polyurethane board stock or casein, dry or premixed joint compound applied in two polyurethane spray foam on the exterior of the wall coats to cover all exposed screw heads and gypsum board (between the DensGlass sheathed wall and the brick), butt joints, and a minimum 2-inch-wide (51 mm) paper, while maintaining the 1-inch (25.4 mm) air space. The plastic, or fiberglass tape embedded in the first layer of length of the brick ties must be increased to account for the compound over butt joints of the gypsum board. The stud thickness of the insulation. cavity is filled with Icynene Classic or Classic Max 4.6 Exterior Walls in Type I, II, Ill and IV Construction: insulation up to 6 inches (152 mm) thick. Dens Glass® Exterior Sheathing, 1/2 inch (12.7 mm) thick, is installed 4.6.1 General: When used on exterior walls of Types I, II, parallel to steel studs with vertical joints offset a minimum Ill or IV construction, the assembly must comply with IBC of 16 inches (406 mm) from the vertical joints of the Section 2603.5 and this section, and the Classic, Classic gypsum board and the horizontal joints offset a minimum of Max and Classic Eco insulations must be installed at a 24 inches (610 mm) from the horizontal joints of the maximum thickness of 6 inches (152 mm). The potential gypsum board. The sheathing is attached using No. 6, heat of Icynene insulations tested in accordance with 1 /4-inch-long (31.7 mm), self-drilling drywall screws NFPA 259 is as follows: spaced 8 inches (203 mm) on center around the perimeter Classic and Classic Max: 494 Btu/ft 2 (5.6 MJ/m2) per and in the field. Hohmann & Barnard DW-10 brick ties, • 6 inches (152 mm) long by 11/2-inches (38 mm) wide, are inch of thickness spaced 16 inches (406.4 mm) on center vertically on each • Classic Eco: 168 Btu/ft2 (1.9 MJ/m2) per inch of steel stud,and secured, using two 15/8-inch-long (41.3 mm) thickness. self-drilling screws, through 4-inch (102 mm) red clay brick [31/2 inches (88.9 mm) by 21/4 inches (57.1 mm) by 4.6.2 Exterior Face: Nominally 6-inch-deep (152 mm), 73/4 inches (197 mm)] laid in a running bond pattern with No. 18 gage, galvanized steel studs spaced 16 inches Type S mortar, leaving a nominally 1-inch (25.4 mm) air (406 mm) on center, are fastened to No. 18 gage, gap between the brick and the exterior sheathing. galvanized steel floor and ceiling track using No. 8, Optional: It is permitted to add code-complying, '/8-inch-long (22.2 mm), self-tapping pan head framing p screws. GP Dens Glass® Exterior Sheathing, /2 inch expanded polystyrene (EPS), extruded polystyrene (XPS), (12.7 mm) thick, is installed over the exterior side of steel foil-faced, rigid polyurethane board stock or polyurethane studs with the long end perpendicular to the steel studs, spray foam on the exterior of the wall (between the using No. 6, T yp e S, 1'/4-inch (31.7 mm) Ion g. self-tapping DensGlass® sheathed wall and the brick), while bugle head screws spaced 8 inches (203 mm) on center maintaining the 1-inch (25.4 mm) air space. The length of around the perimeter and in the field. The stud cavity is the brick ties must be increased to account for the filled with Icynene Classic, Classic Max or Classic Eco thickness of the insulation. insulation to a nominal thickness of 6 inches (152 mm). 4.5.2 Classic Eco (Non-loadbearing Steel Stud Wall): 4.6.3 Interior Face: Type X gypsum board, 5/8 inches Nominally 6-inch-deep (152 mm) deep, No. 18 gage, (15.9 mm) thick, is installed with the long dimension galvanized steel studs spaced 16 inches (406 mm) on perpendicular to steel studs with No. 6, Type S, 11/4 inch- center, are friction-fit into No. 18 gage galvanized steel long (31.7 mm), self-tapping, bugle head screws spaced floor and ceiling track with a layer of 5/8-inch-thick 8 inches (203 mm) on center around the perimeter and in (15.9 mm), Type X gypsum board installed to the interior the field. The gypsum board joints must be treated with side with the long edge parallel to steel studs and secured vinyl or casein, dry or premixed joint compound applied in using No. 6, 11/4-inch-long (31.7 mm), self-drilling drywall two coats to cover all exposed screw heads and gypsum screws spaced 8 inches (203 mm) on center around the board butt joints, and a minimum 2-inch-wide (51 mm) perimeter and 12 inches (305 mm) on center in the field. paper, plastic, or fiberglass tape embedded in the first The gypsum board joints must be treated with vinyl or layer of compound over butt joints of the gypsum board. casein, dry or premixed joint compound applied in two coats to cover all exposed screw heads and gypsum board 4.6.4 Exterior Wall Covering: Details of the exterior wall butt joints, with a minimum 2-inch-wide (51 mm) paper, covering must be provided to the code official by the report plastic, or fiberglass tape embedded in the first layer of holder, designer or specifier, with an engineering analysis compound over butt joints of the gypsum board. The stud demonstrating that (1) the exterior wall covering conforms cavity is filled with Icynene Classic Eco insulation up to to ASTM E136 and (2) the addition of the wall covering to 6 inches (152 mm) thick. Dens Glass® Exterior Sheathing, the assembly described in this section does not negatively 1/2 inch (12.7 mm) thick, is installed parallel to steel studs affect conformance of the assembly with the requirements with vertical joints offset a minimum of 16 inches (406 mm) of IBC Section 2603.5. from the vertical joints of the gypsum board and the 5.0 CONDITIONS OF USE horizontal joints offset a minimum of 24 inches (610 mm) The Icynene Classic, Classic Max, Classic Eco and Classic from the horizontal joints of the gypsum board. The Plus spray-applied polyurethane foam plastic insulations sheathing is attached using No. 6, 11/4-inch-long described in this report comply with, or are suitable (31.7 mm), self-drilling drywall screws spaced 8 inches alternatives to what is specified in, those codes listed in (203 mm) on center around the perimeter and in the field. Section 1.0 of this report, subject to the following Hohmann & Barnard DW-10 brick ties, 6 inches (152 mm) long by 11/2 inches (38 mm) wide and spaced 16 inches conditions: (406 mm) on center vertically on each steel stud, are 5.1 This evaluation report and the manufacturer's secured, using two 15/8-inch-long (41.3 mm) self-drilling published installation instructions, when required by screws,through 4-inch(102 mm) red clay brick [31/2 inches the code official, must be submitted at the time of (88.9 mm) by 21/4 inches (57.1 mm) by 73/4 inches permit application. (197 mm)] laid in a running bond pattern with Type S 5.2 The insulation must be installed in accordance with mortar. A nominally 1-inch (25.4 mm) air gap is left the manufacturer's published installation instructions, between the brick and the exterior sheathing. this evaluation report and the applicable code. If there ESR-1826 I Most Widely Accepted and Trusted Page 7 of 8 is a conflict between the installation instructions and 6.7 Test report in accordance with NFPA 285, and related this report,this report governs. engineering analysis (Classic, Classic Max and 5.3 The insulation must be separated from the interior of Classic Eco). the building by an approved 15-minute thermal 6.8 Reports of tests in accordance with NFPA 259 barrier, except as noted in this report. (Classic,Classic Max and Classic Eco). 5.4 Since the performance of Classic Max, when installed 6.9 Reports of fire tests in accordance with ASTM E970 in unvented attics without a code-prescribed ignition (Classic, Classic Max and Classic Plus). barrier or an intumescent coating, is based on fire 6.10 For Classic Max, an engineering evaluation, including performance of an unvented attic, the installation full-scale fire testing, small-scale testing and fire must be approved by the code official as conforming modeling(Section 4.4.1.2.2). with the provisions of Section 4.4.1.2.2 and Conditions 1 to 5 of Section 4.4.1.2. 7.0 IDENTIFICATION 5.5 When Classic Max insulation is installed under All packages and containers of Classic, Classic Max, Section 4.4.1.2.2 of this report, a certificate must be Classic Eco and Classic Plus insulations must be labeled placed in the attic stating that the foam plastic with the Icynene, Inc., name and address; the product insulation has been installed in accordance with name; component designation (A or B); the flame spread Conditions 1 to 5 of Section 4.4.1.2 and the terms of index and the smoke-developed index; the shelf life Section 4.4.1.2.2 of ESR-1826; any alterations to the expiration date; the name of the inspection body (ICC-ES); attic or insulation must be consistent with those and the evaluation report number(ESR-1826). requirements. Intumescent coatings are identified with the 5.6 The insulation must not exceed the thicknesses and manufacturer's name and address,the product trade name densities noted in this report. and use instructions. 5.7 The insulation must be protected from the weather 8.0 OTHER CODES during and after application. 8.1 Scope: 5.8 The insulation must be applied by licensed dealers and installers certified by Icynene, Inc. In addition to the codes referenced in Section 1.0, the products recognized in this report were evaluated for 5.9 Use of the insulation in areas where the probability of compliance with the requirements of the following codes: termite infestation is "very heavy" must be in • 2006 International Building Code®(2006 IBC) accordance with IRC Section R318.4 or IBC Section 2603.8,as applicable. • 2006 International Residential Code®(2006 IRC) 5.10 Jobsite certification and labeling of the insulation must • 2006 International Energy Conservation Code® (2006 comply with IRC Sections N1101.4 and N1101.4.1 IECC) and IECC Sections 303.1.1 and 303.1.2, as 8.2 Uses: applicable. 5.11 A vapor retarder must be installed in accordance with The products comply with the above-mentioned codes as the applicable code. described in Sections 2.0 to 7.0 of this report, with the revisions noted below. 5.12 Icynene Classic, Classic Max, Classic Eco and • Application with a Prescriptive Ignition Barrier: See Classic Plus foam plastic insulations are Sections 4.4.1.1 (Classic and Classic Max) 4.4.2.1 manufactured in Mississauga, Ontario, Canada, under a quality control program with inspections by ICC-ES. (Classic Eco) and 4.4.3.1 (Classic Plus), except attics must be vented in accordance with 2006 IBC Section 6.0 EVIDENCE SUBMITTED 1203.2, and crawl space ventilation must be in 6.1 Data in accordance with the ICC-ES Acceptance accordance with 2006 IBC Section 1203.3, as Criteria for Spray-applied Foam Plastic Insulation applicable. Additionally, an ignition barrier must be (AC377), dated November 2012 (editorially corrected installed in accordance with 2006 IRC Section R314.5.3 April 2013). or R314.5.4,as applicable. • Application without a Prescriptive Ignition Barrier: 6.2 Reports of tests in accordance with AC377 Appendix See Sections 4.4.1.2 (Classic and Classic Max), 4.4.2.2 X [Classic and Classic Max (Section 4.4.1.2.1); (Classic Eco) and 4.4.3.2 (Classic Plus), except attics Classic Eco (Section 4.4.2.2.1) and Classic Plus must be vented in accordance with 2006 IBC Section (Sections 4.4.3.2.1 and 4.4.3.2.3)] and Appendix C 1203.2 or 2006 IRC Section R806, and crawl space [Classic and Classic Max (Section 4.4.1.2.3); and ventilation must be in accordance with 2006 IBC Section Classic Eco(Section 4.4.2.2.2)]. 1203.3 or 2006 IRC Section R408, as applicable. 6.3 Test reports on air leakage rate in accordance with • Jobsite Certification and Labeling: See Section 5.10, ASTM E283(Classic Eco). except jobsite certification and labeling must comply 6.4 Test report on air leakage rate in accordance with with 2006 IECC Sections 102.1.1 and 102.1.11, as ASTM E2178 (Classic, Classic Max and Classic applicable. Plus). • Protection Against Termites: See Section 5.9, except 6.5 Reports of room corner fire testing in accordance with use of the insulation in areas where the probability of NFPA 286 (Classic, Classic Max, Classic Eco, and termite infestation is "very heavy" must be in Classic Plus). accordance with 2006 IRC Section R320.5. 6.6 Test reports in accordance with ASTM E119 (Classic, Classic Max and Classic Eco). ESR-1826 I Most Widely Accepted and Trusted Page 8 of 8 TABLE 1—THERMAL RESISTANCE(R-VALUES) R-VALUE(°F•ft2•h/Btu) THICKNESS Classic and Classic Max Classic Eco Classic Plus (inches) 1 3.7 3.7 4.0 2 7.4 7.4 8.0 3 11 11 12 3.5 13 13 14 4 14 14 16 5 18 18 20 5.5 20 20 22 6 22 22 24 7 25 25 28 7.5 27 27 30 8 29 29 32 9 32 32 36 9.5 34 34 38 10 36 36 40 11.5 41 41 42 13.5 — 49 54 14 50 50 56 For SI: 1 inch=25.4 mm, 1°F•ft2•h/Btu=0.176 110°K•m2/W. 'R-values are calculated based on tested K values at 1-and 3.5-inch thicknesses. 2R-values greater than 10 are rounded to the nearest whole number. FILE COPY FORM R405-2014 FLORIDA ENERGY EFFICIENCY CODE FOR BUILDING CONSTRUCTION Florida Department of Business and Professional Regulation - Residential Performance Method Project Name: Beliles Lots 9-10 Builder Name: Street: Permit Office: Atlantic Beach City, State,Zip: Atlantic Beach, FL,32233 Permit Number: Owner: Inspried Homes Florida Jurisdiction: 261100 Design Location: FL,Jacksonville 1. New construction or existing New(From Plans) 9. Wall Types(5395.6 sqft.) Insulation Area 2. Single family or multiple family Single-family a. Frame Wood, Exterior R=19.0 4923.10 ft2 b. Frame-Wood,Adjacent R=19.0 472.50 ft2 3. Number of units, if multiple family 1 c. N/A R= ft2 4. Number of Bedrooms 4 d. N/A R= ft2 5. Is this a worst case? No 10.Ceiling Types (2395.0 sqft.) Insulation Area a. Roof Deck(Unvented) R=21.0 2395.00 ft2 6. Conditioned floor area above grade(ft2) 4673 b. N/A R= ft2 Conditioned floor area below grade(ft2) 0 c. N/A R= ft2 11. Ducts R ft2 7. Windows(1080.4 sqft.) Description Area a. Sup: 1st System,Ret: 1st System, AH: 1st Syste 6 467.3 a. U-Factor: Dbl, U=0.32 1080.40 ft2 b. Sup: 2nd System, Ret:2nd System,AH:2nd Sys 6 467.3 SHGC: SHGC=0.28 b. U-Factor: N/A ft2 12.Cooling systems kBtu/hr Efficiency SHGC: a.Central Unit 23.2 SEER:14.00 b.Central Unit 34.2 SEER:14.00 c. U-Factor: N/A ft2 SHGC: 13. Heating systems kBtu/hr Efficiency d. U-Factor: N/A ft2 a. Electric Heat Pump 23.2 HSPF:8.20 SHGC: b. Electric Heat Pump 34.2 HSPF:8.20 Area Weighted Average Overhang Depth: 5.580 ft. Area Weighted Average SHGC: 0.280 14. Hot water systems 8. Floor Types (2395.0 sqft.) Insulation Area a. Propane Tankless Cap: 1 gallons EF:0.590 a.Slab-On-Grade Edge Insulation R=0.0 1803.00 ft2 b. Conservation features b. Floor over Garage R=19.0 592.00 ft2 None c. N/A R= ft2 15.Credits CF, Pstat Glass/Floor Area: 0.231 Total Proposed Modified Loads: 110.07 PASS Total Baseline Loads: 120.04 I hereby certify that the plans and specifications covered by Review of the plans and :.*4'CKE STgj •..,. this calculation are in compliance with the Florida Energy specifications covered by this e. %+ ,= E •.:0,4.,':. Code. Nome Energy Services calculation indicates compliance y ,/ ,, y .JAlexa Jabgtyen) with the Florida Energy Code. unr '%. "...z..:,,,,��,�O• PREPARED BY: --___'_ '\ ` , Before construction is completed a DATE: -_ -_ _- 2/22/2016_ this building will be inspected for r •'y compliance with Section 553.908 t.. * .. .� . ..1• ,.¢ I hereby certify that this building, as •-, ed, is compliance Florida Statutes. ?.. �' ..:..S with the Florida Energy Code. ,/ ': •• %./1,,-;OD{�..... OWNER/AGENT: ---- BUILDING OFFICIAL: DATE: - a/I1._ - DATE: - - Compliance requires certification by the air handler unit manufacturer that the air handler enclosure qualifies as certified factory-sealed in accordance with R403.2.2.1. -Compliance requires an Air Barrier and Insulation Inspection Checklist in accordance with R402.4.1.1 and an envelope leakage test report in accordance with R402.4.1.2. 2/22/2016 12:46 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 1 of 6 FOAM R405-2014 PROJECT Title: Beliles Lots 9-10 Bedrooms: 4 Address Type: Lot Information Building Type: User Conditioned Area: 4673 Lot# 9-10 Owner: Inspried Homes Florida Total Stories: 3 Block/SubDivision: #of Units: 1 Worst Case: No PlatBook: Builder Name: Rotate Angle: 0 Street: Permit Office: Atlantic Beach Cross Ventilation: County: Duval Jurisdiction: 261100 Whole House Fan: City,State,Zip: Atlantic Beach, Family Type: Single-family FL, 32233 New/Existing: New(From Plans) Comment: CLIMATE IECC Design Temp Int Design Temp Heating Design Daily Temp Design Location TMY Site Zone 97.5% 2.50/0 Winter Summer Degree Days Moisture Range FL,Jacksonville FL_JACKSONVILLE_INT 2 32 93 70 75 1281 49 Medium BLOCKS Number Name Area Volume 1 Blocks 1803 18030 2 Block2 2870 24700.8 SPACES Number Name Area Volume Kitchen Occupants Bedrooms Intl!ID Finished Cooled Heated 1 1st System 1803 18030 Yes 4 1 1 Yes Yes Yes 2 2nd System 2870 24700.8 No 1 3 1 Yes Yes Yes FLOORS # Floor Type Space Perimeter Perimeter R-Value Area Joist R-Value Tile Wood Carpet 1 Slab-On-Grade Edge Insulatio 1st System 202 ft 0 1803 ft2 ____ 0.3 0 0.7 2 Floor over Garage 2nd System ____ 592 ft2 19 0.3 0 0.7 ROOF Roof Gable Roof Solar SA Emitt Emitt Deck Pitch V # Type Materials Area Area Color Absor. Tested Tested Insul. (deg) 1 Hip Composition shingles 2679 ft2 0 ft2 Medium 0.85 No 0.9 No 21 26.6 ATTIC V # Type Ventilation Vent Ratio(1 in) Area RBS IRCC 1 Full attic Unvented 0 2395 ft2 N N 2/22/2016 12:46 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 2 of 6 FORM R405-2014 CEILING V # Ceiling Type Space R-Value Area Framing Frac Truss Type 1 Under Attic(Unvented) 1st System 0.1 1920 ft2 0 Wood 2 Under Attic(Unvented) 2nd System 0.1 475 ft2 0 Wood - WALLS Adjacent Cavity Width Height Sheathing Framing Solar Below Orni zo wan type_ Space R-.Value- F1 _ in . .__Et . In .. _.Area _. _R,/alue Fraction Absor- Grade%_ 1 N Exterior Frame-Wood 1st System 19 14.75 0 10 0 147.5 ft2 0 0.23 0.8 0 2 E Exterior Frame-Wood 1st System 19 7.667 0 10 0 76.7 ft2 0 0.23 0.8 0 3 W Garage Frame-Wood 1st System 19 22.25 0 10 0 222.5 ft2 0 0.23 0.8 0 4 N Garage Frame-Wood 1st System 19 7 0 10 0 70.0 ft2 0 0.23 0.8 0 5 N Garage Frame-Wood 1st System 19 13.5 0 10 0 135.0 ft2 0 0.23 0.8 0 6 W Garage Frame-Wood 1st System 19 4.5 0 10 0 45.0 ft2 0 0.23 0.8 0 7 W Exterior Frame-Wood 1st System 19 5.5 0 10 0 55.0 ft2 0 0.23 0.8 0 8 W Exterior Frame-Wood 1st System 19 6.5 0 10 0 65.0 ft2 0 0.23 0.8 0 9 W Exterior Frame-Wood 1st System 19 6 0 10 0 60.0 ft2 0 0.23 0.8 0 10 S Exterior Frame-Wood 1st System 19 13 0 10 0 130.0 ft2 0 0.23 0.8 0 11 S Exterior Frame-Wood 1st System 19 13.58 0 10 0 135.8 ft2 0 0.23 0.8 0 12 S Exterior Frame-Wood 1st System 19 13 0 10 0 130.0 ft2 0 0.23 0.8 0 13 S Exterior Frame-Wood 1st System 19 12.5 0 10 0 125.0 ft2 0 0.23 0.8 0 14 E Exterior Frame-Wood 1st System 19 18 0 10 0 180.0 ft2 0 0.23 0.8 0 15 E Exterior Frame-Wood 1st System 19 23 0 10 0 230.0 ft2 0 0.23 0.8 0 16 N Exterior Frame-Wood 1st System 19 18.5 0 10 0 185.0 ft2 0 0.23 0.8 0 17 W Exterior Frame-Wood 2nd System 19 3 0 9 0 27.0 ft2 0 0.23 0.8 0 18 N Exterior Frame-Wood 2nd System 19 9 0 10 0 90.0 ft2 0 0.23 0.8 0 19 E Exterior Frame-Wood 2nd System 19 2 0 9 0 18.0 ft2 0 0.23 0.8 0 20 N Exterior Frame-Wood 2nd System 19 5 0 9 0 45.0 ft2 0 0.23 0.8 0 21 E Exterior Frame-Wood 2nd System 19 4.5 0 9 0 40.5 ft2 0 0.23 0.8 0 22 N Exterior Frame-Wood 2nd System 19 15 0 9 0 135.0 ft2 0 0.23 0.8 0 23 W Exterior Frame-Wood 2nd System 19 12.66 0 9 0 114.0 ft2 0 0.23 0.8 0 24 N Exterior Frame-Wood 2nd System 19 10 0 9 0 90.0 ft2 0 0.23 0.8 0 25 W Exterior Frame-Wood 2nd System 19 13.5 0 9 0 121.5 ft2 0 0.23 0.8 0 26 W Exterior Frame-Wood 2nd System 19 4 0 9 0 36.0 ft2 0 0.23 0.8 0 27 W Exterior Frame-Wood 2nd System 19 9.583 0 9 0 86.2 ft2 0 0.23 0.8 0 28 W Exterior Frame-Wood 2nd System 19 6.75 0 9 0 60.8 ft2 0 0.23 0.8 0 29 S Exterior Frame-Wood 2nd System 19 6.167 0 9 0 55.5 ft2 0 0.23 0.8 0 30 E Exterior Frame-Wood 2nd System 19 1.333 0 9 0 12.0 ft2 0 0.23 0.8 0 31 S Exterior Frame-Wood 2nd System 19 12 0 9 0 108.0 ft2 0 0.23 0.8 0 32 S Exterior Frame-Wood 2nd System 19 8.5 0 9 0 76.5 ft2 0 0.23 0.8 0 33 W Exterior Frame-Wood 2nd System 19 4.5 0 9 0 40.5 ft2 0 0.23 0.8 0 34 S Exterior Frame-Wood 2nd System 19 19 0 9 0 171.0 ft2 0 0.23 0.8 0 35 E Exterior Frame-Wood 2nd System 19 1.333 0 9 0 12.0 ft2 0 0.23 0.8 0 36 S Exterior Frame-Wood 2nd System 19 18.5 0 9 0 166.5 ft2 0 0.23 0.8 0 37 E Exterior Frame-Wood 2nd System 19 16.5 0 9 0 148.5 ft2 0 0.23 0.8 0 38 E Exterior Frame-Wood 2nd System 19 25 0 9 0 225.0 ft2 0 0.23 0.8 0 2/22/2016 12:46 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 3 of 6 FORM R405-2014 WALLS Adjacent Cavity Width Height Sheathing Framing Solar Below Space # Ornt To Wall Type R-Value Et In Ft In Area R-Value Fraction Absor. Grade,o 39 N Exterior Frame-Wood 2nd System 19 23 0 9 0 207.0 ft2 0 0.23 0.8 0 40 N Exterior Frame-Wood 2nd System 19 9 0 8 0 72.0 ft2 0 0.23 0.8 0 41 W Exterior Frame-Wood 2nd System 19 22.5 0 8 0 180.0 ft2 0 0.23 0.8 0 42 E Exterior Frame-Wood 2nd System 19 14 0 8 0 112.0 ft2 0 0.23 0.8 0 43 N Exterior Frame-Wood 2nd System 19 11 0 8 0 88.0 ft2 0 0.23 0.8 0 44 W Exterior Frame-Wood 2nd System 19 9 0 8 0 72.0 ft2 0 0.23 0.8 0 45 S Exterior Frame-Wood 2nd System 19 6 0 8 0 48.0 ft2 0 0.23 0.8 0 46 N Exterior Frame-Wood 2nd System 19 9 0 8 0 72.0 ft2 0 0.23 0.8 0 47 E Exterior Frame-Wood 2nd System 19 14.58 0 8 0 116.6 ft2 0 0.23 0.8 0 48 S Exterior Frame-Wood 2nd System 19 8 0 8 0 64.0 ft2 0 0.23 0.8 0 49 E Exterior Frame-Wood 2nd System 19 18.5 0 8 0 148.0 ft2 0 0.23 0.8 0 50 W Exterior Frame-Wood 2nd System 19 18.5 0 8 0 148.0 ft2 0 0.23 0.8 0 51 N Exterior Frame-Wood 2nd System 19 5.5 0 8 0 44.0 ft2 0 0.23 0.8 0 52 S Exterior Frame-Wood 2nd System 19 11 0 8 0 88.0 ft2 0 0.23 0.8 0 53 E Exterior Frame-Wood 2nd System 19 4 0 8 0 32.0 ft2 0 0.23 0.8 0 54 W Exterior Frame-Wood 2nd System 19 4 0 8 0 32.0 ft2 0 0.23 0.8 0 DOORS V # Ornt Door Type Space Storms U-Value Width Height Area Ft In Ft In 1 N Insulated 1st System None .4 2.8 8 22.4 ft2 2 N Insulated 2nd System None .4 3 6.7 20.1 ft2 WINDOWS Orientation shown is the entered, Proposed orientation. / Wall Overhang V # Ornt ID Frame Panes NFRC U-Factor SHGC Area Depth Separation Int Shade Screening 1 N 1 Vinyl Low-E Double Yes 0.32 0.28 37.3 ft2 1 ft 0 in 1 ft 0 in None None 2 N 1 Vinyl Low-E Double Yes 0.32 0.28 31.5 ft2 6 ft 0 in 2 ft 0 in None None 3 N 1 Vinyl Low-E Double Yes 0.32 0.28 3.5 ft2 6 ft 0 in 0 ft 0 in None None 4 W 7 Vinyl Low-E Double Yes 0.32 0.28 24.0 ft2 10 ft 0 in 1 ft 0 in None None 5 S 10 Vinyl Low-E Double Yes 0.32 0.28 8.0 ft2 1 ft 0 in 1 ft 0 in None None 6 S 11 Vinyl Low-E Double Yes 0.32 0.28 30.0 ft2 1 ft 0 in 10 ft 0 in None None 7 S 13 Vinyl Low-E Double Yes 0.32 0.28 54.0 ft2 1 ft 0 in 10 ft 0 in None None 8 E 14 Vinyl Low-E Double Yes 0.32 0.28 96.0 ft2 10 ft 0 in 1 ft 0 in None None 9 E 15 Vinyl Low-E Double Yes 0.32 0.28 128.0 ft2 10 ft 0 in 1 ft 0 in None None 10 N 16 Vinyl Low-E Double Yes 0.32 0.28 26.7 ft2 1 ft 0 in 10 ft 0 in None None 11 N 18 Vinyl Low-E Double Yes 0.32 0.28 51.6 ft2 1 ft 0 in 1 ft 0 in None None 12 N 22 Vinyl Low-E Double Yes 0.32 0.28 54.0 ft2 1 ft 0 in 1 ft 0 in None None 13 N 24 Vinyl Low-E Double Yes 0.32 0.28 13.3 ft2 1 ft 0 in 1 ft 0 in None None 14 W 25 Vinyl Low-E Double Yes 0.32 0.28 18.0 ft2 1 ft 0 in 1 ft 0 in None None 15 W 27 Vinyl Low-E Double Yes 0.32 0.28 8.0 ft2 1 ft 0 in 1 ft 0 in None None 16 S 31 Vinyl Low-E Double Yes 0.32 0.28 30.0 ft2 1 ft 0 in 1 ft 0 in None None 17 S 32 Vinyl Low-E Double Yes 0.32 0.28 9.0 ft2 1 ft 0 in 1 ft 0 in None None 2/22/2016 12:46 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 4 of 6 FORM R405-2014 WINDOWS Orientation shown is the entered, Proposed orientation. Wall Overhang V # Ornt ID Frame Panes NFRC U-Factor SHGC Area Depth Separation Int Shade Screening 18 S 34 Vinyl Low-E Double Yes 0.32 0.28 32.0 ft2 1 ft 0 in 1 ft 0 in None None 19 S 36 Vinyl Low-E Double Yes 0.32 0.28 36.0 ft2 1 ft 0 in 1 ft 0 in None None 20 E 37 Vinyl Low-E Double Yes 0.32 0.28 96.0 ft2 11 ft 0 in 1 ft 0 in None None 21 E 38 Vinyl Low-E Double Yes 0.32 0.28 128.0 ft2 11 ft 0 in 1 ft 0 in None None 22 N 39 Vinyl Low-E Double Yes 0.32 0.28 42.0 ft2 1 ft 0 in 1 ft 0 in None None 23 N 39 Vinyl Low-E Double Yes 0.32 0.28 8.0 ft2 1 ft 0 in 1 ft 0 in None None 24 N 40 Vinyl Low-E Double Yes 0.32 0.28 30.0 ft2 1 ft 0 in 1 ft 0 in None None 25 N 46 Vinyl Low-E Double Yes 0.32 0.28 18.0 ft2 1 ft 0 in 1 ft 0 in None None 26 E 47 Vinyl Low-E Double Yes 0.32 0.28 33.5 ft2 10 ft 0 in 1 ft 0 in None None 27 S 48 Vinyl Low-E Double Yes 0.32 0.28 24.0 ft2 1 ft 0 in 1 ft 0 in None None 28 E 53 Vinyl Low-E Double Yes 0.32 0.28 5.0 ft2 1 ft 0 in 1 ft 0 in None None 29 W 54 Vinyl Low-E Double Yes 0.32 0.28 5.0 ft2 1 ft 0 in 1 ft 0 in None None GARAGE ✓ # Floor Area Ceiling Area Exposed Wall Perimeter Avg. Wall Height Exposed Wall Insulation 1 630 ft2 384 ft2 56 ft 10 ft 1 INFILTRATION # Scope Method SLA CFM 50 ELA EqLA ACH ACH 50 1 Wholehouse Proposed ACH(50) .000291 3560.9 195.49 367.64 .311 5 HEATING SYSTEM V # System Type Subtype Efficiency Capacity Block Ducts 1 Electric Heat Pump None HSPF:8.2 23.2 kBtu/hr 1 sys#1 2 Electric Heat Pump None HSPF:8.2 34.2 kBtu/hr 2 sys#2 COOLING SYSTEM # System Type Subtype Efficiency Capacity Air Flow SHR Block Ducts 1 Central Unit None SEER: 14 23.2 kBtu/hr 696 cfm 0.75 1 sys#1 2 Central Unit None SEER: 14 34.2 kBtu/hr 1026 cfm 0.75 2 sys#2 HOT WATER SYSTEM V # System Type SubType Location EF Cap Use SetPnt _Conservation_ 1 Propane Tankless Exterior 0.59 1 gal 70 gal 120 deg None 2/22/2016 12:46 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 5 of 6 FORM R405-2014 SOLAR HOT WATER SYSTEM FSEC Collector Storage Cert # Company Name System Model# Collector Model# Area Volume FEF None None ft2 DUCTS V/ ----Supply---- ----Return--- Air CFM 25 CFM25 HVAC# # Location R-Value Area Location Area Leakage Type Handler TOT OUT ON RLF Heat Cool 1 1st System 6 467.3 ft 1st System 116.82 Default Leakage 1st System (Default) (Default) 1 1 2 2nd System 6 467.3 ft 2nd System 116.82 Default Leakage 2nd System (Default) (Default) 2 2 TEMPERATURES Programable Thermostat:Y Ceiling Fans: Coolin Jan Feb ]Mar A r Ma X Jun X Jul X Au X Se ixi Oct Nov DeHeating Jan Feb lXMar lXi Apr f [May t [Jun 1 [Jul f [Aug 4 [Sep Oct lXJ Nov tX]DeVentin Jan Feb X Mar [ A r [ Ma Jun Jul f Au [ Se Oct [X Nov [ JJ Dec Thermostat Schedule: HERS 2006 Reference Hours Schedule Type 1 2 3 4 5 6 7 8 9 10 11 12 Cooling(WD) AM 78 78 78 78 78 78 78 78 80 80 80 80 PM 80 80 78 78 78 78 78 78 78 78 78 78 Cooling(WEH) AM 78 78 78 78 78 78 78 78 78 78 78 78 PM 78 78 78 78 78 78 78 78 78 78 78 78 Heating(WD) AM 66 66 66 66 66 68 68 68 68 68 68 68 PM 68 68 68 68 68 68 68 68 68 68 66 66 Heating(WEH) AM 66 66 66 66 66 68 68 68 68 68 68 68 PM 68 68 68 68 68 68 68 68 68 68 66 66 2/22/2016 12:46 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 6 of 6 FORM R405-2014 ENERGY PERFORMANCE LEVEL (EPL) DISPLAY CARD ESTIMATED ENERGY PERFORMANCE INDEX* = 92 The lower the EnergyPerformance Index, the more efficient the home. , Atlantic Beach, FL, 32233 1. New construction or existing New(From Plans) 9. Wall Types Insulation Area 2. Single family or multiple family Single-family a. Frame Wood, Exterior R=19.0 4923.10 ft2 b. Frame-Wood,Adjacent R=19.0 472.50 ft2 3. Number of units,if multiple family 1 c. N/A R= ft2 4. Number of Bedrooms 4 d. N/A R= ft2 10.Ceiling Types Insulation Area . 5. Is this a worst case? No a.Roof Deck(Unvented) R=21.0 2395.00 ft2 6. Conditioned floor area(ft2) 4673 b. N/A R= ft2 7. Windows" Description Area c. N/A R= ft2 a. U-Factor: Dbl, U=0.32 1080.40 ft2 11. Ducts R ft2 a. Sup: 1st System, Ret: 1st System,AH: 1st Syste 6 467.3 SHGC: SHGC=0.28 b.Sup: 2nd System, Ret:2nd System,AH:2nd Sys 6 467.3 b. U-Factor: N/A ft2 SHGC: 12.Cooling systems kBtu/hr Efficiency c. U-Factor: N/A ft2 a.Central Unit 23.2 SEER:14.00 SHGC: b.Central Unit 34.2 SEER:14.00 d. U-Factor: N/A ft2 13. Heating systems kBtu/hr Efficiency SHGC: a. Electric Heat Pump 23.2 HSPF:8.20 Area Weighted Average Overhang Depth: 5.580 ft. b. Electric Heat Pump 34.2 HSPF:8.20 Area Weighted Average SHGC: 0.280 8. Floor Types Insulation Area 14.Hot water systems a.Slab-On-Grade Edge Insulation R=0.0 1803.00 ft2 a. Propane Cap: 1 gallons EF:0.59 b. Floor over Garage R=19.0 592.00 ft2 c. N/A R= ft2 b. Conservation features None 15.Credits CF, Pstat I certify that this home has complied with the Florida Energy Efficiency Code for Building :•'•"EKE ST Construction through the above energy saving features which will be installed (or exceeded) =y�O� ATFo ; in this home before final inspectio Otherwise, a new EPL Display Card will be completed ;y ;;;,''��%.��, : ,4,':. based on installed Code corn!): 1. ,�,,,�'ifr.,,, ,�..sa',:� .a _ 4'2 t ..f--:.," . off. Builder Signature: .017111111 AP Date: 24 C /4 t:o`-.`f, c 6 t ` Address of New Home: City/FL Zip: Ar...r1,errkc. �`," 3 2233 OD�''� 'Note: This is not a Building Energy Rating. If your Index is below 70, your home may qualify for energy efficient mortgage(EEM) incentives if you obtain a Florida EnergyGauge Rating. Contact the EnergyGauge Hotline at(321) 638-1492 or see the EnergyGauge web site at energygauge.com for information and a list of certified Raters. For information about the Florida Building Code, Energy Conservation, contact the Florida Building Commission's support staff. **Label required by Section R303.1.3 of the Florida Building Code, Energy Conservation, if not DEFAULT. 2/22/2016 12:47 PM EnergyGauge®USA-FlaRes2014 -Section R405.4.1 Compliant Software Page 1 of 1 FORM R405-2014 Florida Department of Business and Professional Regulations Residential Whole Building Performance and Prescriptive Methods ADDRESS Permit Number: Atlantic Beach, FL,32233 MANDATORY REQUIREMENTS See individual code sections for full details. ? 401.3 Energy Performance Level(EPL)display card(Mandatory). The building official shall require that an energy performance level(EPL) display card be completed and certified by the builder to be accurate and correct before final approval of the building for occupancy. Florida law [Section 553.9085, Florida Statues]requires the EPL display card to be included as an addendum to each sales contract for both presold and nonpresold residential buildings.The EPL display card contains information indicating the energy performance level and efficiencies of components installed in a dwelling unit.The building official shall verify that the EPL display card completed and signed by the builder accurately reflects the plans and specifications submitted to demonstrate compliance for the building.A copy of the EPL display card can be found in Appendix C. ? R402.4 Air leakage(Mandatory). The building thermal envelope shall be constructed to limit air leakage in accordance with the requirements of Sections R402.1 through R402.4.4. 9 R402.4.1 Building thermal envelope. The building thermal envelope shall comply with Sections R402.4.1.1 and R402.4.1.2.The sealing methods between dissimilar materials shall allow for differential expansion and contraction. • R402.4.1.1 Installation. The components of the building thermal envelope as listed in Table R402.4.1.1 shall be installed in accordance with the manufacturer's instructions and the criteria listed in Table 402.4.1.1,as applicable to the method of construction. Where required by the code official,an approved third party shall inspect all components and verify compliance. • R402.4.1.2 Testing. The building or dwelling unit shall be tested and verified as having an air leakage rate of not exceeding 5 air changes per hour in Climate Zones 1 and 2,and 3 air changes per hour in Climate Zones 3 through 8.Testing shall be conducted with a blower door at a pressure of 0.2 inches w.g. (50 Pascals).Where required by the code official,testing shall be conducted by an approved third party.A written report of the results of the test shall be signed by the party conducting the test and provided to the code official.Testing shall be performed at any time after creation of all penetrations of the building thermal envelope. During testing: 1. Exterior windows and doors,fireplace and stove doors shall be closed,but not sealed,beyond the intended weatherstripping or other infiltration control measures; 2. Dampers including exhaust, intake,makeup air,backdraft and flue dampers shall be closed,but not sealed beyond intended infiltration control measures; 3. Interior doors, if installed at the time of the test,shall be open; 4. Exterior doors for continuous ventilation systems and heat recovery ventilators shall be closed and sealed; 5. Heating and cooling systems,if installed at the time of the test,shall be turned off;and 6. Supply and return registers,if installed at the time of the test,shall be fully open. ? R402.4.2 Fireplaces.New wood-burning fireplaces shall have tight-fitting flue dampers and outdoor combustion air. ? R402.4.3 Fenestration air leakageWindows, skylights and sliding glass doors shall have an air infiltration rate of no more than 0.3 cfm per square foot(1.5 Us/m2),and swinging doors no more than 0.5 cfm per square foot(2.6 L/s/m2),when tested according to NFRC 400 or AAMA/WDMA/CSA 101/I.S.2/A440 by an accredited,independent laboratory and listed and labeled by the manufacturer. Exception: Site-built windows, skylights and doors. ? R402.4.4 Recessed lighting. Recessed luminaires installed in the building thermal envelope shall be sealed to limit air leakage between conditioned and unconditioned spaces.All recessed luminaires shall be IC-rated and labeled as having an air leakage rate not more than 2.0 cfm(0.944 Us)when tested in accordance with ASTM E 283 at a 1.57 psf(75 Pa)pressure differential. All recessed luminaires shall be sealed with a gasket or caulk between the housing and the interior wall or ceiling covering. ? R403.1.1 Thermostat provision(Mandatory). At least one thermostat shall be provided for each separate heating and cooling system. ? R403.1.3 Heat pump supplementary heat(Mandatory).Heat pumps having supplementary electric-resistance heat shall have controls that,except during defrost,prevent supplemental heat operation when the heat pump compressor can meet the heating load. ? R403.2.2 Sealing(Mandatory Ali ducts, air handlers, and filter boxes and building cavities that form the primary air containment passageways for air distribution systems shall be considered ducts and plenum chambers,shall be constructed and sealed in accordance with Section C403.2.7.2 of the Commercial Provisions of this code and shall be shown to meet duct tightness criteria by post-construction or rough-in testing below. Duct tightness shall be verified by testing to Section 803 of the RESNET Standards by either an energy rater certified in accordance with Section 553.99,Florida Statutes,or as authorized by Florida Statutes,to be"substantially leak free"by either of the following: 1. Post-construction test:Total leakage shall be less than or equal to 4 cfm(113 Umin)per 100 square feet(9.29 m2)of conditioned floor area when tested at a pressure differential of 0.1 inches w.g. (25 Pa)across the entire system,including the manufacturer's air handler enclosure.All register boots shall be taped or otherwise sealed during the test. 2. Rough-in test:Total leakage shall be less than or equal to 4 cfm(113 Umin)per 100 square feet(9.29 m2)of conditioned floor area when tested at a pressure differential of 0.1 inches w.g. (25Pa)across the system,including the manufacturer's air handler enclosure. All registers shall be taped or otherwise sealed during the test. If the air handler is not installed at the time of the test,total leakage shall be less than or equal to 3 cfm (85 Umin)per 100 square feet(9.29 m2)of conditioned floor area. Exceptions: 1. The total leakage test is not required for ducts and air handlers located entirely within the building envelope. 2. Duct testing is not mandatory for buildings complying by Section R405 of this code. 2/22/2016 12:40 PM EnergyGauge®USA-FlaRes2014 -Section R405.4.1 Corn Page 1 of 3 FORM R405-2014 MANDATORY REQUIREMENTS - (Continued) R403.2.2.1 Sealed air handler. Air handlers shall have a manufacturer's designation for an air leakage of no more than 2 percent of the design air flow rate when tested in accordance with ASHRAE 193. R403.2.3 Building Cavities(Mandatory). Building framing cavities shall not be used as ducts or plenums. R403.3 Mechanical system piping insulation(Mandatory). Mechanical system piping capable of carrying fluids above 105°F (41°C) or below 55°F(13°C)shall be insulated to a minimum of R-3., R403.3.1 Protection of piping insulation. Piping insulation exposed to weather shall be protected from damage, including that caused by sunlight,moisture,equipment maintenance, and wind,and shall provide shielding from solar radiation that can cause degradation of the material. Adhesive tape shall not be permitted. R403.4.1 Circulating hot water systems(Mandatory). Circulating hot water systems shall be provided with an automatic or readily accessible manual switch that can turn off the hot-water circulating pump when the system is not in use. R403.4.3 Heat traps(Mandatory). Storage water heaters not equipped with integral heat traps and having vertical pipe risers shall have heat traps installed on both the inlets and outlets. External heat traps shall consist of either a commercially available heat trap or a downward and upward bend of at least 3 1 inches(89 mm)in the hot water distribution line and cold water line located as close as possible to the storage tank. R403.4.4 Water heater efficiencies(Mandatory). Water heater efficiencies 9 R403.4.4.1 Storage water heater temperature controls . R403.4.4.1.1 Automatic controls. Service water heating systems shall be equipped with automatic temperature controls capable of adjustment from the lowest to the highest acceptable temperature settings for the intended use.The minimum temperature setting range shall be from 100°F to 140°F(38°C to 60°C). . R403.4.4.1.2 Shut down. A separate switch or a clearly marked circuit breaker shall be provided to permit the power supplied to electric service systems to be turned off.A separate valve shall be provided to permit the energy supplied to the main burner(s) of combustion types of service water heating systems to be turned off. 9 R403.4.4.2 Water heating equipment. Water heating equipment installed in residential units shall meet the minimum efficiencies of • Table C404.2 in Chapter 4 of the Florida Building Code, Energy Conservation,Commercial Provisions,for the type of equipment installed. Equipment used to provide heating functions as part of a combination system shall satisfy all stated requirements for the appropriate water heating category. Solar water heaters shall met the criteria Section R403.4.4.2.1. ▪ R403.4.4.2.1 Solar water heating systems.Solar systems for domestic hot water production are rated by the annual solar energy factor of the system.The solar energy factor of a system shall be determined from the Florida Solar Energy Center Directory of Certified Solar Systems.Solar collectors shall be tested in accordance with ISO Standard 9806,Test Methods for Solar Collectors, and SRCC Standard TM-1,Solar Domestic Hot Water System and Component Test Protocol,Collectors in installed solar water heating systems should meet the following criteria: 1. Be installed with a tilt angle between 10 degrees and 40 degrees of the horizontal;and 2. Be installed at an orientation within 45 degrees of true south. R403.5 Mechanical ventilation(Mandatory). The building shall be provided with ventilation that meets the requirements of the Florida Building Code,Residential or Florida Building Code,Mechanical,as applicable,or with other approved means of ventilation. Outdoor air intakes and exhausts shall have automatic or gravity dampers that close when the ventilation system is not operating. R403.5.1 Whole-house mechanical ventilation system fan efficacy. Mechanical ventilation system fans shall meet the efficacy requirements of Table R403.5.1. Exception:Where mechanical ventilation fans are integral to tested and listed HVAC equipment,they shall be powered by an electronically commutated motor. R403.5.2 Ventilation air. Residential buildings designed to be operated at a positive indoor pressure or for mechanical • ventilation shall meet the following criteria: 1. The design air change per hour minimums for residential buildings in ASHRAE 62,Ventilation for Acceptable Indoor Air Quality, shall be the maximum rates allowed for residential applications. 2. No ventilation or air-conditioned system make air shall be provided to conditioned space from attics,crawlspaces,attached closed garages or outdoor spaces adjacent to swimming pools or spas. 3. If ventilation air is drawn from enclosed spaces(s),then the walls of the space(s)from which air is drawn shall be insulated to a minimum of R-11 and the ceiling shall be insulated to a minimum or R-19,space permitting,or R-10 otherwise. R403.6 Heating and cooling equipment(Mandatory). The following sections are mandatory for cooling and heating equipment. ? R403.6.1 Equipment sizing. Heating and cooling equipment shall be sized in accordance with ACCA Manual S based on the equipment loads calculated in accordance with ACCA Manual J or other approved heating and cooling calculation methodologies, based on building loads for the directional orientation of the building.The manufacturer and model number of the outdoor and indoor units(if split system)shall be submitted along with the sensible and total cooling capacities at the design conditions described in Section R302.1.This code does not allow designer safety factors,provisions for future expansion or other factors which affect equipment sizing.System sizing calculations shall not include loads created by local intermittent mechanical ventilation such as standard kitchen and bathroom exhaust systems. • R403.6.1.1 Cooling equipment capacity. Cooling only equipment shall be selected so that its total capacity is not less than the calculated total load,but not more than 1.15 times greater than the total load calculated according to the procedure selected in Section 403.6,or the closest available size provided by the manufacturer's product lines.The corresponding latent capacity of the equipment shall not be less than the calculated latent load. 9I99/9111R 19.A(1 PIA Fnnrrninoiincail I ICA-FInRcc9(11A _Cnnfinn mAm A 1 (nn, Donn O.,f • FORM R405-2014 MANDATORY REQUIREMENTS - (Continued) R403.6.1.1 Cooling equipment capacity.(continued) The published value for AHRI total capacity is a nominal, rating-test value and shall not be used for equipment sizing. Manufacture's expanded performance data shall be used to select cooling-only equipment.This selection shall be used to select cooling-only equipment.This selection shall be based on the outdoor design dry bulb temperature for the load calculation(or entering water temperature for water-source equipment),the blower cfm provided by the expanded performance data, the design value for entering wet bulb temperature and the design value for entering dry bulb temperature. Design values for entering wet bulb and dry bulb temperature shall be for the indoor dry bulb and relative humidity used for the load calculation and shall be adjusted for return side gains if the return duct(s)is installed in an unconditioned space. Exceptions: 1. Attached single-and multi-family residential equipment sizing may be selected so that its cooling capacity is less than the calculated total sensible load but not less than 80 percent of that load. 2. When signed and sealed by a Florida-registered engineer, in attached single-and multi-family units,the capacity of equipment may be sized in accordance with good design practice. R403.6.1.2 Heating equipment capacity • R403.6.1.2.1 Heat pumps. Heat pumps sizing shall be based on the cooling requirements as calculated according to Section R403.6.1.1 and the heat pump total cooling capacity shall not be more than 1.15 times greater than the design cooling load. • R403.6.1.2.2 Electric resistance furnaces. Electric resistance furnaces shall be sized within 4 kW of the design requirements calculated according to the procedure selected in Section R403.6.1. • R403.6.1.2.3 Fossil fuel heating equipment. The capacity of fossil fuel heating equipment with natural draft atmospheric burners shall not be less than the design load calculated in accordance with Section R403.6.1. R403.6.1.3 Extra capacity required for special occasions. Residences requiring excess cooling or heating equipment capacity on an intermittent basis,such as anticipated additional loads caused by major entertainment events, shall have equipment sized or controlled to prevent continuous space cooling or heating within that space by one or more of the following options: 1. A separate cooling or heating system is utilized to provide cooling or heating to the major entertainment areas. 2. A variable capacity system sized for optimum performance during base load periods is utilized. R403.7 Systems serving multiple dwelling units(Mandatory). Systems serving multiple dwelling units shall comply with Sections C403 and C404 of the Commercial Provisions in lieu of Section R403. R403.8 Snow melt system controls(Mandatory). Snow and ice-melting systems, supplied through energy service to the building,shall include automatic controls capable of shutting off the system when the pavement temperature is above 55°F,and no precipitation is falling and an automatic or manual control that will allow shutoff when the outdoor temperature is above 40°F. R403.9 Swimming pools,inground spas and portable spas(Mandatory). The energy requirements for residential pools and inground spas shall be as specified in Sections R403.9.1 through R403.9.3 and in accordance with ANSI/APSP-15.The energy requirements for portable spas shall be in accordance with ANSI/APSP-14. R403.9.1 Pool and spa heaters. All pool heaters shall be equipped with a readily accessible on-off switch that is mounted outside the heater to allow shutting off the heater without adjusting the thermostat setting. R403.9.1.1 Gas and oll-fired pool and spa heaters. All gas-and oil-fired pool and space heaters shall have a minimum • thermal efficiency of 82 percent for heaters manufactured on or after April 16,2013 when tested in accordance with ANSI Z 21.56. Pool heaters fired by natural gas or LP gas shall not have continuously burning pilot lights. • R403.9.1.2 Heat pump pool heaters. Heat pump pool heaters shall have a minimum COP of 4.0 when tested in accordance with AHRI 1160,Table 2,Standard Rating Conditions-Low Air Temperature.A test report from an independent laboratory is required to verify procedure compliance.Geothermal swimming pool heat pumps are not required to meet this standard. R403.9.2 Time switches. Time switches or other control method that can automatically turn off and on heaters and pumps according to a preset schedule shall be installed on all heaters and pumps. Heaters, pumps and motors that have built in timers shall be deemed in compliance with this equipment. Exceptions: • 1. Where public health standards require 24-hour pump operations. 2. Where pumps are required to operate solar-and waste-heat-recovery pool heating systems. 3. Where pumps are powered exclusively from on-site renewable generation. R403.9.3 Covers. Heated swimming pools and inground permanently installed spas shall be equipped with a vapor-retardant cover on or at the water surface or a liquid cover or other means proven to reduce heat loss. Exception: Outdoor pools deriving over 70 percent of the energy for heating from site-recovered energy,such as a heat pump or ▪ solar energy source computed over an operating season. RR404.1 Lighting equipment(Mandatory). A minimum of 75 percent of the lamps in permanently installed lighting fixtures shall be high-efficacy lamps or a minimum of 75 percent of permanently installed lighting fixtures shall contain only high efficacy lamps. Exception: Low-voltage lighting shall not be required to utilize high-efficacy lamps. R404.1.1 Lighting equipment(Mandatory). Fuel gas lighting systems shall not have continuously burning pilot lights R405.2 Performance ONLY. All ducts not entirely inside the building thermal envelope shall be insulated to a minimum of R-6. R405.2.1 Performance ONLY. Ceilings shall have minimum insulation of R-19.Where single assemby of the exposed deck and beam type or concrete deck roofs do not have sufficent space, R-10 is allowed. 2/22/2016 12:40 PM EnergyGauge@ USA-FlaRes2014 -Section R405.4.1 Com Page 3 of 3 FORM R405-2014 TABLE 402.4.1.1 AIR BARRIER AND INSULATION INSPECTION COMPONENT CRITERIA Project Name: Beliles Lots 9-10 Builder Name: Street: Permit Office: Atlantic Beach City, State,Zip: Atlantic Beach, FL,32233 Permit Number: Owner: lnspried Homes Florida Jurisdiction: 261100 Design Location: FL,Jacksonville COMPONENT CRITERIA CHECK Air barrier and thermal barrier A continuous air barrier shall be installed in the building envelope. Exterior thermal envelope contains a continuous barrier. Breaks or joints in the air barrier shall be sealed. Air-permeable insulation shall not be used as a sealing material. Ceiling/attic The air barrier in any dropped ceiling/soffit shall be aligned with the insulation and any gaps in the air barrier shall be sealed. ✓/ Access openings, drop down stairs or knee wall doors to unconditioned attic spaces shall be sealed. Corners and headers shall be insulated and the junction of the foundation Walls and sill plate shall be sealed. The junction of the top plate and the top or exterior walls shall be sealed. Exterior thermal envelope insulation for framed walls shall be installed in ✓ substantial contact and continuous alignment with the air barrier. Knee walls shall be sealed. Windows, skylights and doors The space between window/door jambs and framing and skylights and L/ framing shall be sealed. Rim joists Rim joists are insulated and include an air barrier. ✓ Floors (including above-garage Insulation shall be installed to maintain permanent contact with underside and cantilevered floors) of subfloor decking. The air barrier shall be installed at any exposed edge of insulation. Crawl space walls Where provided in lieu of floor insulation, insulation shall be permanently attached to the crawlspace walls. N)p Exposed earth in unvented crawl spaces shall be covered with a Class I vapor retarder with overlapping joints taped. Shafts, penetrations Duct shafts, utility penetrations, and flue shaft openings to exterior or unconditioned space shall be sealed. Narrow cavities Batts in narrow cavities shall be cut to fit, or narrow cavities shall be filled by insulation that on installation readily conforms to the available cavity ✓ spaces. Garage separation Air sealing shall be provided between the garage and conditioned spaces. Recessed lighting Recessed light fixtures installed in the building thermal envelope shall be ✓ air tight, IC rated,and sealed to the drywall. Plumbing and wiring Batt insulation shall be cut neatly to fit around wiring and plumbing in exterior walls, or insulation that on installation readily conforms to available ✓ space shall extend behind piping and wiring. Shower/tub on exterior wall Exterior walls adjacent to showers and tubs shall be insulated and the air barrier installed separating them from the showers and tubs. Electrical/phone box on The air barrier shall be installed behind electrical or communication boxes or air sealed boxes shall be installed. HVAC register boots HVAC register boots that penetrate building thermal envelope shall be sealed to the sub-floor or drywall. Fireplace An air barrier shall be installed on fireplace walls. Fireplaces shall have gasketed doors 2/22/2016 12:40 PM EnergyGauge®USA-FlaRes2014 Section R405.4.1 Compliant Software Page 1 of 1 FILE COPY Bellies Lots 9 & 10 HVAC Load Calculations for lnspried Homes Florida R H RESIDENTIAL C HVAC LOADS Prepared By: Alexa Laughren Home Energy Services PO Box 28162 Jacksonville, FL 32226 904-757-3569 Monday, February 22,2016 Rhvac is an ACCA approved Manual J and Manual D computer program. Calculations are performed per ACCA Manual J 8th Edition, Version 2, and ACCA Manual D. Rhvac-Residential &Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services ` t Beliles Lots 9& 10 Jacksonville,FL 32218 /J. Page 2 Project Report General Project Information Project Title: Beliles Lots 9 & 10 Project Date: Monday, February 22, 2016 Client Name: Inspried Homes Florida Client Comment: Company Name: Home Energy Services Company Representative: Alexa Laughren Company Address: PO Box 28162 Company City: Jacksonville, FL 32226 Company Phone: 904-757-3569 Company E-Mail Address: admin @hesjax.com Company Website: www.hesjax.com Design Data Reference City: Jacksonville, Florida Building Orientation: Front door faces North Daily Temperature Range: Medium Latitude: 30 Degrees Elevation: 26 ft. Altitude Factor: 0.999 Outdoor Outdoor Outdoor Indoor Indoor Grains Dry Bulb Wet Bulb Rel.Hum Rel.Hum Dry Bulb Difference Winter: 32 29.92 n/a n/a 70 n/a Summer: 94 77 47% 50% 75 48 Check Figures Total Building Supply CFM: 1,899 CFM Per Square ft.: 0.412 Square ft. of Room Area: 4,613 Square ft. Per Ton: 1,115 Volume (ft')of Cond. Space: 50,740 Building Loads Total Heating Required Including Ventilation Air: 49,550 Btuh 49.550 MBH Total Sensible Gain: 41,729 Btuh 84 % Total Latent Gain: 7,902 Btuh 16 % Total Cooling Required Including Ventilation Air: 49,631 Btuh 4.14 Tons (Based On Sensible + Latent) Notes Rhvac is an ACCA approved Manual J and Manual D computer program. Calculations are performed per ACCA Manual J 8th Edition, Version 2, and ACCA Manual D. All computed results are estimates as building use and weather may vary. Be sure to select a unit that meets both sensible and latent loads according to the manufacturer's performance data at your design conditions. rte•\ rha Mnndav Fehruary 22. 2016. 1:46 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services Bellies Lots 9& 10 Jacksonville.FL 32218 Page 3 Miscellaneous Report System 1 1st System Outdoor Outdoor Outdoor Indoor Indoor Grains Input Data Dry Bulb Wet Bulb Rel.Hum Rel.Hum Dry Bulb Difference Winter: 32 29.92 80% n/a 70 n/a Summer: 94 77 47% 50% 75 48.06 System 2 2nd System Outdoor Outdoor Outdoor Indoor Indoor Grains Input Data Dry Bulb Wet Bulb Rel.Hum Rel.Hum Dry Bulb Difference Winter: 32 29.92 80% n/a 70 n/a Summer: 94 77 47% 50% 75 48.06 Duct Sizing Inputs Main Trunk Runouts Calculate: Yes Yes Use Schedule: Yes Yes Roughness Factor: 0.00300 0.01000 Pressure Drop: 0.1000 in.wg./100 ft. 0.1000 in.wg./100 ft. Minimum Velocity: 650 ft./min 450 ft./min Maximum Velocity: 900 ft./min 750 ft./min Minimum Height: 0 in. 0 in. Maximum Height: 0 in. 0 in. Outside Air Data Winter Summer Infiltration Specified: 0.250 AC/hr 0.250 AC/hr 211 CFM 211 CFM Infiltration Actual: 0.250 AC/hr 0.250 AC/hr Above Grade Volume: X 50,743 Cu.ft. X 50,743 Cu.ft. 12,686 Cu.ft./hr 12,686 Cu.ft./hr X 0.0167 X 0.0167 Total Building Infiltration: 211 CFM 211 CFM Total Building Ventilation: 0 CFM 0 CFM ---System 1-- Infiltration &Ventilation Sensible Gain Multiplier: 20.88 = (1.10 X 0.999 X 19.00 Summer Temp. Difference) Infiltration &Ventilation Latent Gain Multiplier: 32.65 = (0.68 X 0.999 X 48.06 Grains Difference) Infiltration &Ventilation Sensible Loss Multiplier: 41.76 = (1.10 X 0.999 X 38.00 Winter Temp. Difference) Winter Infiltration Specified: 0.250 AC/hr(83 CFM) Summer Infiltration Specified: 0.250 AC/hr(83 CFM) ---System 2-- Infiltration &Ventilation Sensible Gain Multiplier: 20.88 = (1.10 X 0.999 X 19.00 Summer Temp. Difference) Infiltration &Ventilation Latent Gain Multiplier: 32.65 = (0.68 X 0.999 X 48.06 Grains Difference) Infiltration &Ventilation Sensible Loss Multiplier: 41.76 = (1.10 X 0.999 X 38.00 Winter Temp. Difference) Winter Infiltration Specified: 0.250 AC/hr(129 CFM) Summer Infiltration Specified: 0.250 AC/hr(129 CFM) C•\ 1RPlilas rhg Monday Fehruary 22 2016 1.46 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services Bellies Lots 9&10 Jacksonville,FL 32218 Page 4 Load Preview Report _ -- - Net ft Sen Lat Net Sys Sys Sys Scope Ton /Ton Area Grin Gain Gain Loss: CFM. CFM CFM Sum Building 4.14 1,115 4,613 41,729 7,902 49,631 49,550 1,002 1,899 1,899 System 1 1.71 1,057 1,804 16,981 3A98 20,479 24,437 494 773 773 1(x15 Zone 1 1,804 16.981 3,498 20,479 24,437 494 773 773 10x15 1-FoyerNestibule/Bevator/Stair 400 2,049 700 2,749 5,606 113 93 93 1-6 2-Mud Room 108 1,114 318 1,432 2,935 59 51 51 1-4 3-Powder Room 41 0 0 0 0 0 0 0 0-0 4-Laundry 42 162 88 250 642 13 7 7 1-4 5-G WIC 28 0 0 0 0 0 0 0 0-0 6-Guest Bath 78 564 257 821 1,876 38 26 26 1-4 7-Guest Bedroom 163 1,706 184 1,890 1,594 32 78 78 1-51 8-Butlers Pantry 60 0 0 0 0 0 0 0 0-0 9-IGt hen 234 2,291 376 2,667 1,232 25 104 104 1-61 10-Dining 225 2,749 413 3,162 4,353 88 125 125 2-5' 11-Great Room 426 6,345 1,162 7,507 6,199 125 289 289 3-61 System 2 2.43 1,156 2,809 24,748 4,404 29,152 25,113 508 1,126 1,126 12x17 Long 1-Clg.:79%, 111g.: 71% 2,336 25,607 2,778 28,385 17,903 362 1,165 1,165 12x17 12-2nd Floor Stair 162 1,034 167 1,201 1,364 28 47 47 1-41 13-Mech 50 211 56 267 371 8 10 10 1-41 14-Study 190 2,628 358 2,986 2,423 49 120 120 2-41 15-Bedroom 3 189 1,870 261 2,131 1,877 38 85 85 1-5 16-Bath 3 70 101 0 101 125 3 5 5 1-4 17-Br 3 WIC 32 127 44 171 207 4 6 6 1-4 18-Bath 4 57 374 107 481 538 11 17 17 1-4 19-Br 4 WIC 42 352 158 510 609 12 16 16 1-4 20-Bedroom 4 180 1,604 133 1,737 1,058 21 73 73 1-5 21-Craft/Laundry 2 102 968 95 1,063 586 12 44 44 1-4 22-His WIC 70 101 0 101 125 3 5 5 1-41 23-Her WIC 83 76 0 76 95 2 3 3 1-41 24-Owners Bath 252 1,544 276 1,820 1,688 34 70 70 1-51 25-Owners Bedroom 305 6,185 389 6,574 2,841 57 281 281 3-61 26-Rec Room&Wet Bar 552 8,432 734 9,166 3,996 81 384 384 4-6 Zone 2-0g.:21%,Htg.:29% 473 6,633 1,626 8259 7210 146 302 302 6x8 27-3rd Floor Stair 203 1,353 558 1,911 2,273 46 62 62 1-5 28-Powder Room 45 235 148 383 498 10 11 11 1-4 29-Exercise Room 225 5,045 920 5,965 4,439 90 230 230 3-5 Sum d room airflows may be greeter then system arflow,because system has multiple zones. ("A \Roliloc rhQ Monday February 22. 2(116. 146 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services iii, Bellies Lots 9&10 Jacksonville,FL 32218 Page 5 Duct Size Preview _ _ Room or _--- --- Minimum Maximum Rough. Design SPI Duct Duct Htg i Clg Act. Duct Duct Name Source Velocity Velocity Factor L/100 Loss; Velocity Length Flow ' Flow Flow Size System 1 Supply Runouts Zone 1 1-Foyer/Vestibule/Elevator/Stair Built-In 450 750 0.01 0.1 474.8 113 93 93 1-6 2-Mud Room Built-In 450 750 0.01 0.1 581 59 51 51 1-4 3-Powder Room Built-In 450 750 0.01 0.1 0 0 0 0 0-0 4-Laundry Built-In 450 750 0.01 0.1 84.6 13 7 7 1-4 5-G WIC Built-In 450 750 0.01 0.1 0 0 0 0 0-0 6-Guest Bath Built-In 450 750 0.01 0.1 294.1 38 26 26 1-4 7-Guest Bedroom Built-In 450 750 0.01 0.1 569.4 32 78 78 1-5 8-Bulers Panty Built-In 450 750 0.01 0.1 0 0 0 0 0-0 9-Kitchen Built-In 450 750 0.01 0.1 530.9 25 104 104 1-6 10-Dining Built-In 450 750 0.01 0.1 458.6 88 125 125 2-5 11-Great Room Built-In 450 750 0.01 0.1 490.1 125 289 289 3-6 Other Ducts In System 1 Supply Main Truric Built-In 650 900 0.003 0.1 741.7 494 773 773 10x15 System 2 Supply Runouts Zone 1 12-2nd Floor Stair Built-In 450 750 0.01 0.1 538.9 28 47 47 1-4 13-Mech Built-In 450 750 0.01 0.1 109.9 8 10 10 1-4 14-Study Built-In 450 750 0.01 0.1 685.1 49 120 120 2-4 15-Bedroom 3 Built-In 450 750 0.01 0.1 623.8 38 85 85 1-5 16-Bath 3 Built-In 450 750 0.01 0.1 52.6 3 5 5 1-4 17-Br3WIC Built-In 450 750 0.01 0.1 66.4 4 6 6 1-4 18-Bath 4 Built-In 450 750 0.01 0.1 194.8 11 17 17 1-4 19-Br4WIC Built-In 450 750 0.01 0.1 183.7 12 16 16 1-4 20-Bedroom 4 Built-In 450 750 0.01 0.1 535.1 21 73 73 1-5 21-Craft/Laundry 2 Built-In 450 750 0.01 0.1 504.9 12 44 44 1-4 22-His WIC Built-In 450 750 0.01 0.1 52.6 3 5 5 1-4 23-Her WIC Built-In 450 750 0.01 0.1 39.8 2 3 3 1-4 I 24-Owners Bath Built-In 450 750 0.01 0.1 515.1 34 70 70 1-5 25-Owners Bedroom Built-In 450 750 0.01 0.1 477.7 57 281 281 3-6 26-Rec Room&Wet Bar Built-In 450 750 0.01 0.1 488.5 81 384 384 4-6 Zone 2 27-3rd Floor Stair Built-In 450 750 0.01 0.1 451.6 46 62 62 1-5 28-Powder Room Built-In 450 750 0.01 0.1 122.6 10 11 11 1-4 29-Exercise Room Built-In 450 750 0.01 0.1 561.1 90 230 230 3-5 Other Ducts In System 2 Supply Main Trunk Built-In 650 900 0.003 0.1 794.8 508 1,126 1,126 12x17 Summary System 1 Heating Flow: 494 Cooling Flow. 773 System 2 Heating Flaw: 506 Cooling Flow 1126 C.\ _ \RPIiMPS rhA Monday. February 22. 2016. 1:46 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services '�r 1 Bellies Lots 9& 10 Jacksonville, FL 32218 �..t Page 6 Total Building Summary Loads Component Area Sen Lat Sen Total Description Quan Loss Gain Gain Gain 4A-6-o: Glazing-Double pane low-e (e = 0.20 or less), 1080.4 13,135 0 14,289 14,289 high performance, operable window, e=0.05 on surface 2, any frame, u-value 0.32, SHGC 0.28 11J: Door-Metal - Fiberglass Core 42.5 969 0 617 617 12E-Osw: Wall-Frame, R-19 insulation in 2 x 6 stud 2894.7 7,480 0 4,208 4,208 cavity, no board insulation. siding finish, wood studs 12E-Osw: Part-Frame, R-19 insulation in 2 x 6 stud cavity, 1378.1 2,931 0 1,149 1,149 no board insulation, siding finish, wood studs 18A1-21o: Roof/Ceiling-Roof Joists Between Roof Deck 2610.2 4,661 0 3,680 3,680 and Ceiling or Foam Encapsulated Roof Joists, Spray Foam Insulation, Dark or Bold-Color Asphalt Shingle, Dark Metal, Dark Membrane, Dark Tar and Gravel, R-21 open cell 1/2 lb. spray foam, 5.5 inches in 2 x 6 joist cavity, 1 inch on joist 22A-ph: Floor-Slab on grade, No edge insulation, no 202 10,422 0 0 0 insulation below floor, any floor cover, passive, heavy moist soil 20P-19: Floor-Over open crawl space or garage, Passive, 590.5 1,122 0 413 413 R-19 blanket insulation, any cover Subtotals for structure: 40,720 0 24,356 24,356 People: 5 1,000 1,150 2,150 Equipment: 0 10,050 10,050 Lighting: 0 0 0 Ductwork: 0 0 0 0 Infiltration: Winter CFM: 211, Summer CFM: 211 8,830 6,902 4,416 11,318 Ventilation: Winter CFM: 0, Summer CFM: 0 0 0 0 0 AED Excursion: 0 0 1,757 1,757 Total Building Load Totals: 49,550 7,902 41,729 49,631 Check Figures Total Building Supply CFM: 1,899 CFM Per Square ft.: 0.412 Square ft. of Room Area: 4,613 Square ft. Per Ton: 1,115 Volume (ft3)of Cond. Space: 50,740 Building Loads Total Heating Required Including Ventilation Air: 49,550 Btuh 49.550 MBH Total Sensible Gain: 41,729 Btuh 84 Total Latent Gain: 7,902 Btuh 16 Total Cooling Required Including Ventilation Air: 49,631 Btuh 4.14 Tons (Based On Sensible + Latent) Notes Rhvac is an ACCA approved Manual J and Manual D computer program. Calculations are performed per ACCA Manual J 8th Edition, Version 2, and ACCA Manual D. All computed results are estimates as building use and weather may vary. Be sure to select a unit that meets both sensible and latent loads according to the manufacturer's performance data at your design conditions. r•\ \PcIiIce rhO Monday Fahniary 22 2rl1R 1.46 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services Bellies Lots 9& 10 Jacksonville, FL 32218 / Page 7 Building Pie Chart Infiltration 18% Floor 23% Door 2% Building - r, Loss br.. 49,550 b tO,i Btuh Roof 9% Glass 27% Wall 21% Roof Floor 1% AED Excursion 4% Wall 11 Infiltration 23% Building Gain 49,631 'y,, Btuh l ' Glass 29% Equipment 20% Door 1°/0 People 4% r �RPIIIAC rhq Monday. February 22. 2016. 1:46 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services Beliles Lots 9& 10 Jacksonville.FL 32218 AtVr Page 8 Manual S Performance Data - System 1 - 1st System Cooling Loads and Design Conditions Outdoor Dry Bulb: 94 Sensible Gain: 16,981 Outdoor Wet Bulb: 77 Latent Gain: 3,498 Indoor Dry Bulb: 75 Total Gain: 20,479 Indoor RH: 50 Load SHR: 0.83 Elevation: 26 Supply Airflow: 773 Latitude: 30 Entering Dry Bulb: 75 Altitude Factor: 1 Entering Wet Bulb: 62.5 Equipment Performance Data at System Design Conditions Air Source Heat Pump Model: 25HCC524A*030+CNPV*2417AL*, Nominal Capacity: 23,200 Entered Interpolation Data: EDB Total Power 75°F I E°F Air Flow ODB Capacity Input Sensible °F CFM °F MBtuh kW SIT Capacity MBtuh 85 700 85 22.25 1.65 0.925 20.58 95 21.17 1.87 0.948 20.06 62 85 22.8 1.68 0.969 22.11 800 95 21.69 1.89 0.992 21.51 85 24.52 1.67 0.711 17.44 700 95 23.33 1.88 0.726 16.941 67 800 85 25.04 1.69 0.696 17.441 L__ 95 23.8 1.9 0.76 18.091 Other Adjustments: Elevation Derating: 1, Miscellaneous: 1, Direct Capacity Adjustment: -3.23 Interpolation Results: Percent Load of Load Sensible Capacity: 17,260 16,981 102% Latent Capacity: 1,597 3,498 46% Total Capacity: 18,857 20,479 92% Power Input: 1.87 r•\ \Ronne rha Monday. February 22. 2016. 1:46 PM Rhvac-Residential &Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services Bellies Lots 9& 10 Jacksonville. FL 32218 / Page 9 Manual S Performance Data - System 2 - 2nd System Cooling Loads and Design Conditions Outdoor Dry Bulb: 94 Sensible Gain: 24,748 Outdoor Wet Bulb: 77 Latent Gain: 4,404 Indoor Dry Bulb: 75 Total Gain: 29,152 Indoor RH: 50 Load SHR: 0.85 Elevation: 26 Supply Airflow: 1,126 Latitude: 30 Entering Dry Bulb: 75 Altitude Factor: 1 Entering Wet Bulb: 62.5 Equipment Performance Data at System Design Conditions Air Source Heat Pump Model: 25HCC536A*030+CNPV*4217AL*, Nominal Capacity: 34,200 Entered Interpolation Data: ED8 EWB Air Flow ODB Total Power 75.3°F `F CFM °F Capacity Input Sensble MBtuh kW SIT Capacity MBtuh 85 33.74 2.5 0.994 33.54 1200 62 95 32.07 2.78 0.993 31.861 1350 85 34.51 2.53 1 34.51 95 33.01 2.81 1 33.01 85 36.9 2.52 0.762 28.13; 67 1200--__ 95 35 2.8 0.781 27.341 1350 85 37.43 2.55 0.796 29.81 95 35.47 2.83 0.818 29 Other Adjustments: Elevation Derating: 1, Miscellaneous: 1, Direct Capacity Adjustment: -5.339 Interpolation Results: Percent Load of Load Sensible Capacity: 26,679 24,748 108% Latent Capacity: 1,086 4,404 25% Total Capacity: 27,765 29,152 95% Power Input: 2.77 C:\ ...\Beliles.rh9 Monday. February 22. 2016. 1:46 PM Rhvac-Residential&Light Commercial HVAC Loads Elite Software Development,Inc. Home Energy Services Beliles Lots 9& 10 Jacksonville,FL 32218 i Page 10 System 1 Room Load Summary Htg Min Run Run Clg Clg Min Act Room Area Sens Htg Duct Duct Sens Lat Clg Sys No Name SF Btuh CFM Size Vel Btuh Btuh CFM CFM ---Zone 1--- 1 FoyerNestibule/EI 400 5,606 113 1-6 475 2,049 700 93 93 evator/Stair 2 Mud Room 108 2,935 59 1-4 581 1,114 318 51 51 3 Powder Room 41 0 0 0-0 0 0 0 0 0 4 Laundry 42 642 13 1-4 85 162 88 7 7 5 G WIC 28 0 0 0-0 0 0 0 0 0 6 Guest Bath 78 1,876 38 1-4 294 564 257 26 26 7 Guest Bedroom 163 1,594 32 1-5 569 1,706 184 78 78 8 Butlers Pantry 60 0 0 0-0 0 0 0 0 0 9 Kitchen 234 1,232 25 1-6 531 2,291 376 104 104 10 Dining 225 4,353 88 2-5 459 2,749 413 125 125 11 Great Room 426 6,199 125 3-6 490 6,345 1,162 289 289 System 1 total 1,804 24,437 494 16,981 3,498 773 773 System 1 Main Trunk Size: 10x15 in. Velocity: 742 ft./min Loss per 100 ft.: 0.098 in.wg Cooling System Summary Cooling Sensible/Latent Sensible Latent Total Tons Split Btuh Btuh Btuh Net Required: 1.71 83%/ 17% 16,981 3,498 20,479 Actual: 1.93 75%/25% 17,400 5,800 23,200 Equipment Data Heating System Cooling System Type: Air Source Heat Pump Air Source Heat Pump Model: 25HCC524A*030 25HCC524A*030 Indoor Model: CNPV'2417AL* Brand: CARRIER AIR CONDITIONING CARRIER AIR CONDITIONING Description: Air Source Heat Pump Air Source Heat Pump Efficiency: 8.2 HSPF 14 SEER Sound: 0 0 Capacity: 24,000 Btuh 23,200 Btuh Adjusted Capacity: n/a 18,857 Btuh Sensible Capacity: n/a 17,400 Btuh Adjusted Sensible Capacity: n/a 17,260 Btuh Latent Capacity: n/a 5,800 Btuh Adjusted Latent Capacity: n/a 1,597 Btuh AHRI Reference No.: n/a 8588635 C:\ ...1Beliles.rh9 Monday. February 22. 2016. 1:46 PM pRhvac esidential&Light Commercial HVAC Loads Elite Software Development,Inc. rgy Services �` Bellies Lots 9& 10 ille,FL 32218 Page 11 m 2 Room Load Summary Htg Min Run Run Clg Clg Min Act om Area Sens Htg Duct Duct Sens Lat Clg Sys me SF Btuh CFM Size Vet Btuh Btuh CFM CFM 1--- d Floor Stair 162 1,364 28 1-4 539 1,034 167 47 47 ech 50 371 8 1-4 110 211 56 10 10 udy 190 2,423 49 2-4 685 2,628 358 120 120 droom 3 189 1,877 38 1-5 624 1,870 261 85 85 16 Bath 3 70 125 3 1-4 53 101 0 5 5 17 Br 3 WIC 32 207 4 1-4 66 127 44 6 6 18 Bath 4 57 538 11 1-4 195 374 107 17 17 19 Br WIC 42 609 12 1-4 184 352 158 16 16 20 Bedroom 4 180 1,058 21 1-5 535 1,604 133 73 73 21 Craft/Laundry 2 102 586 12 1-4 505 968 95 44 44 22 His WIC 70 125 3 1-4 53 101 0 5 5 23 Her WIC 83 95 2 1-4 40 76 0 3 3 24 Owners Bath 252 1,688 34 1-5 515 1,544 276 70 70 25 Owners Bedroom 305 2,841 57 3-6 478 6,185 389 281 281 26 Rec Room&Wet 552 3,996 81 4-6 488 8,432 734 384 384 Bar Zone 1 subtotal 2,336 17,903 362 25,607 2,778 1,165 1,165 ---Zone 2--- 27 3rd Floor Stair 203 2,273 46 1-5 452 1,353 558 62 62 28 Powder Room 45 498 10 1-4 123 235 148 11 11 29 Exercise Room 225 4,439 90 3-5 561 5,045 920 230 230 Zone 2 subtotal 473 7,210 146 6,633 1,626 302 302 System 2 total 2,809 25,113 508 24,748 4,404 1,126 1,126 System 2 Main Trunk Size: 12x17 in. Velocity: 795 ft./min Loss per 100 ft.: 0.091 in.wg Note: Since the system is multizone, the Peak Fenestration Gain Procedure was used to determine glass sensible gains at the room and zone levels, so the sums of the zone sensible gains and airflows for cooling shown above are not intended to equal the totals at the system level. Room and zone sensible gains and cooling CFM values are for the hour in which the glass sensible gain for the zone is at its peak. Sensible gains at the system level are based on the"Average Load Procedure + Excursion" method. Cooling System Summary Cooling Sensible/Latent Sensible Latent Total Tons Split Btuh Btuh Btuh Net Required: 2.43 85%/ 15% 24,748 4,404 29,152 Actual: 2.85 75%/ 25% 25,650 8,550 34,200 Equipment Data Heating System Cooling System Type: Air Source Heat Pump Air Source Heat Pump Model: 25HCC536A*030 25HCC536A*030 Indoor Model: CNPV*4217AL* Brand: CARRIER AIR CONDITIONING CARRIER AIR CONDITIONING Description: Air Source Heat Pump Air Source Heat Pump Efficiency: 8.2 HSPF 14 SEER Sound: 0 0 Capacity: 34,200 Btuh 34,200 Btuh Adjusted Capacity: n/a 27,765 Btuh Sensible Capacity: n/a 25,650 Btuh Adjusted Sensible Capacity: n/a 26,679 Btuh Latent Capacity: n/a 8,550 Btuh Adjusted Latent Capacity: n/a 1,086 Btuh AHRI Reference No.: n/a 8588713 (`"k \Rorioc rha Monday. February 22. 2016. 1:46 PM