© RCABC 2019

| style="color: black; background-color: #ffffcc; width: 100%;text-align:left" |  The content of this Standard was significantly revised and supplemented in October 2019 and is effect December 1, 2019.  Therefore, the reader should consider all of the content to be new since publication.  Projects bid after November 30, 2019 must conform to the Standards published in this document.  

{{hilite |Highlighted text within the body of the online Standard and its Parts indicates revisions made within the last twelve (12) months.|| 2021-February-7 }}

In this '''Manual''', all references to

#the British Columbia Building Code or other standards presume the current edition that is in force.

#materials are assumed to be Accepted by the RGC, unless stated otherwise.

:;''Contractor'' (“contractor”): means the installer of a Project.  For the purpose of issuing a '''''RoofStar Guarantee''''', ''Contractor'' shall be read to mean a Member of the RCABC.

:;''Finished Roof{{hilite |/Waterproofing|| 2021-February-7 }} Assembly'': means the fully constructed ''Roof Assembly'' together with, where installed, any paver, ballast or type of '''Roof Covering''' ('''14.1.1 Definitions'''). See also '''''Roof Assembly''''' and '''''Roof System'''''.

:;''Guarantor'': means the RGC '''''RoofStar Guarantee Program''''' and may be used interchangeably.

:;''Manual'': means the '''''Roofing Practices Manual'''''.

:;''Project'': means the designed or constructed waterproofing or water-shedding system.

:;''System'': means the organization and securement of various interacting materials (apart from the supporting deck structure), designed and installed to prevent the transmission of water through the system into the conditioned space of a building (adapted from ASTM D6630-08 Standard Guide for Low slope Insulated Roof membrane Assembly Performance).

:;''Waterproofing System'': means a membrane or liquid-applied system that, regardless of slope, waterproofs a roof or structure at grade.  These systems are typically installed on slopes less than 1:4 (3” in 12”).

:;''Water-shedding System'': means a roof system that, with sufficient slope, sheds water away from a structure but does not necessarily waterproof it.

:;''Eave Protection'': means a self-adhering membrane applied in parallel courses along the eaves, up the roof slope to a point measured vertically from the inside of the exterior wall, and intended to block the ingress of water that may leak behind shingles or metal roof panels as the result of snow or ice buildup on the roof surface.

:;''Linear Metal Flashings'': are flashings cut and shaped from flat metal stock, to redirect water at roof perimeters and edges, and are used in valleys and drainage spillways.

:;''Underlayment,'': sometimes referred to as Waterproof Shingle Underlayment (WSU), means a roll material that is either self-adhering or mechanically fastened (typically with large head nails), and which

::#provides a secondary water-shedding surface between the shingles or metal panels and the building interior.

::#keeps shingles or metal panels from adhering to the underlying substrate.

Refer to the [http://rpm.rcabc.org/index.php?title=Glossary '''Glossary'''] for further definitions of key terms used in this '''Manual'''.

<li>When a roof is designed and constructed so that the resulting roof slope is less than 1:6 (as, for example, dead valleys and the roof areas below a dormer), the roof area must be designed as a Waterproofing Roof Assembly.

<li>In this '''Manual''', a high snow load area is considered a regional area with a Specified Snow Load higher than 3.5 kPa.

<li>To determine whether or not a building is located in a high snow load area, the Design Authority must calculate the anticipated snow loads for the roof, using the building code having jurisdiction. The following references are extracted from the ''British Columbia Building Code'':

The '''Guarantee Standards''', Guiding Principles, Recommendations and Reference Materials in this '''Manual''' pertain to both new roofing construction and replacement roofing, unless explicitly stated otherwise.

<li>Existing self-adhered eave protection membrane may be left in place, but must be covered with a new layer of RoofStar-accepted membrane, in keeping with the Standards in this Manual.

<li>'''Insurance Coverage''' – limits carried on the Contractor’s policy must equal or exceed the minimum requirements set by RCABC, and coverage must be unhindered by warranties that limit or exclude coverage when Hot Work is required.

<li>'''Education and training''' – workers who perform hot work must be trained by the Contractor and kept current with acceptable methods.

<li>'''Fire Safety Plan''' – the Contractor must assess the hazards to property and persons and produce a written Fire Safety Plan prior to the start of work.  The Fire Safety Plan must be kept on the Project site and must be kept current until the Project is completed.

<li>'''RoofStar Guarantee Standards''' – the Contractor must adhere to the RoofStar Guarantee Standards at each juncture where the interface of different membranes applications constitutes part of the Fire Safety Plan.

<li>'''Fire Watch''' – the Contractor must, as part of the Fire Safety Plan, conduct a fire watch

<li>'''Hot Work Notification''' – notify the Project authority or the AHJ, as and when required, that Hot Works will be performed.

While integrity and functionality of a new roof or waterproofed deck is the foundation of a '''''RoofStar Guarantee''''', it is no less important to ensure that the finished Project exhibits excellent workmanship.  {{hilite | Therefore, the following Standards apply|| 2021-February-7 }}:

<li>{{hilite | The Contractor must take reasonable measures to protect the Project from damage by the weather, during and at the completion of construction.  Open penetrations and flashings must be temporarily sealed off from the weather, even when other trades are responsible to make a permanent seal or install overlapping materials.  See also '''4.1 General''' || 2021-February-7 }}.

A '''''RoofStar Guarantee''''' is available for almost any roof design, provided it is designed and built to the Standards in this ''Manual''. When a '''''RoofStar 15-year Guarantee''''' is specified, only Waterproofing (Roof) Systems and Architectural Sheet Metal (ASM) Roof Systems may qualify, and Waterproofing Roofs must be designed and constructed to satisfy both the Standards in this ''Manual'' and the membrane manufacturer’s 20-year Material Warranty; both the '''''RoofStar Guarantee''''' and the manufacturer Material Warranty will be delivered to the Owner when the Project is complete.  Nevertheless, there are limitations and conditions. They are listed on the Guarantee Certificate, and include (without limitation) the following (as they are applicable to the type of Project):  

<li>{{hilite | The '''''RoofStar Guarantee''''' covers leaks resulting from new materials purchased, supplied and installed by the Contractor.  All new materials incorporated into a Project intended to qualify for a RoofStar Guarantee must be expressly Accepted by the RGC and listed in the Roofing Practices Manual.  Accepted Materials include (without limitation)|| 2021-February-7 }}

<li>{{hilite | primary and secondary roof system materials || 2021-February-7 }}.

{{hilite | All materials or products supplied by anyone other than an Associate Member, or which are installed by someone other than the Contractor, will be excluded from coverage under the Guarantee, and may void the Guarantee entirely || 2021-February-7 }}.

<li>Notwithstanding the definition of a Waterproofing or Water-shedding System, the '''''RoofStar Guarantee''''' does not cover the quality, installation or performance of the supporting deck structure.

<li>The '''''RoofStar Guarantee''''' (subject to the limitations described herein or stated on the Guarantee Certificate) is a guarantee against leaks only, caused only by a failure of {{hilite | new materials installed by the Contractor, or resulting from the Contractor 's installation of new materials.

The term "new materials" includes primary and secondary roofing materials, linear metal flashings, and both penetration flashings and roof drains that have been expressly accepted for use on a Project designed and constructed to qualify for a '''''RoofStar Guarantee'''''.  Only materials listed in the '''''Roofing Practices Manual''''' in the Accepted Materials Division of this Manual qualify for a '''''RoofStar Guarantee'''''.

The re-use of any existing material on a Project may void the Guarantee || 2021-February-7 }}.

<li>the failure of a drain or flashing supplied or installed by anyone other than the Contractor.

<li>neglected maintenance of the Project.

<li>modifications to the Project made by anyone other than the Contractor.

<li>replacement (new for old) of any Overburden.

<li>Overburdens may be installed on conventionally insulated or Protected (“inverted”) roofs, but not all designs are suitable for any type, size or depth of Overburden (see '''14 THE ROOF as a PLATFORM'''). <span class="recommended">The RGC recommends that a roof supporting overburden be designed and constructed as a Protected Membrane Roof Assembly</span>. The RoofStar Guarantee may be void if a roof is designed and constructed with overburden that exceeds the capabilities of a conventional roof assembly.

<li>Only a fully adhered membrane may be used in a ''Protected'' (PMRA, or “inverted”) Waterproofing Project.

<li>'''Integrity Scans''': An Integrity Scan, performed by an RGC-recognized service provider to ensure the waterproofing is leak and damage-free, is required on all Waterproofing roof and grade-level Projects when overburden, amenities or equipment are or will be installed on the completed Waterproofing Assembly by

<li>anyone other than the Contractor.

<li>the Contractor, when the overburden, amenities or equipment exceed 150 mm (6”) in depth.

::See '''Figure 1.1''' for further reference.

<li>'''Electronic Leak Detection''' is mandatory for Grade-level Waterproofing Projects, but optional for Waterproofing roofs.

<li>When concrete walls or structures are constructed without a pre-curb, all concrete surfaces must be fully and continuously enveloped with the primary roof membrane.

<li>While the application of non‐penetrating bonded tiling or other architectural finishes to the waterproofing membrane is acceptable for a RoofStar Guarantee, and is subject to approval by the membrane manufacturer, the removal, reinstallation or replacement of any bonded finish, in order to investigate and repair leaks under the terms of the Guarantee, is the responsibility of others.

<li>RGC must be notified in writing of any modifications or repairs to the RoofStar-guaranteed Project.

<li>The Owner must ensure that any modification or repair work done on the Project during the guarantee period is performed to '''''RoofStar Guarantee Standards''''' by a roofing contractor, and is inspected by a RoofStar-accepted observation firm.

<li>'''Maintenance''': the building Owner must ensure that the Project and its components are properly maintained. Debris in drains, caulking on or around metal flashings, and wind scouring of gravel are considered maintenance issues.

<li>'''Removal and Reinstallation of Overburdens''': in order to investigate and repair a leak, the '''''RoofStar Guarantee Program''''' must be allowed to remove Overburdens, to expose the membrane. The '''''RoofStar Guarantee''''' pays for the removal and reinstallation of <u>accessible overburdens only</u>, when they are installed by the Contractor, regardless of the Project design. The cost to remove, care for and reinstall any Overburden that exceeds these limits or conditions, which is inaccessible, or which was supplied or installed by others, will be borne by the Owner.  

===Design===

<li>The British Columbia Building Code, or the building code having jurisdiction, prevails in all cases except where it is exceeded by the '''''RoofStar Guarantee Standards''''' published in this '''Manual'''.

<li>Notwithstanding the '''''RoofStar Guarantee Standards''''' published in this '''Manual''', the '''''RoofStar Guarantee''''' does not extend coverage to the supporting roof deck or to its securement, which is the responsibility of the ''Design Authority'' and the building contractor.

<li>Prior to the application of the roof system, the supporting deck structure (roof deck) and other surfaces receiving membranes must be smooth, straight, clean and free of

<li>All supporting decks must provide a suitable nailing substrate for asphalt shingles, and be acceptable to the shingle manufacturer.  Suitability includes, without limitation,

<li>stiffness that minimizes deck deflection.

<li>The British Columbia Building Code, or the building code having jurisdiction, prevails in all cases except where it is exceeded by the RoofStar Guarantee Standards published in this Manual.

<li>Notwithstanding the RoofStar Guarantee Standards published in this Manual, the RoofStar Guarantee does not extend coverage to the supporting roof deck or to its securement, which is the responsibility of the Design Authority and the building contractor.

<li>Prior to the application of the roof system, the supporting deck structure (roof deck) and other surfaces receiving membranes must be smooth, straight, clean and free of  

<li><span class="principles">Walls, parapets, curbs, blocking and penetrations should be constructed or placed prior to the commencement of roofing work. This work is provided by other trades</span>.

<li><span class="principles">The supporting deck structure should be dimensionally stable and capable of accommodating roof system component movement</span>.

<li>Wood decks shall be constructed of plywood that is  

<li>Oriented Strand Board (OSB) and other non-veneered panels are acceptable deck materials, but the Design Authority is responsible to determine the grade and thickness in order to meet the required pull-out resistance for the expected fasteners.

<li>Shiplap and dimensional lumber are not acceptable deck materials.

<li>Knotholes and cracks in decks shall be considered defects and must be covered with sheet metal nailed in place.

<li>Plywood used as an overlay on existing roof decks must be at least 12.7 mm (1/2”) thick and must conform to CSA 0151-04, Canadian Softwood Plywood, Grade C or better; or CSA 0121-M 1978 (R2003) Douglas Fir Plywood, Grade C or better.

<li>When an existing roof deck is

<li>constructed with damaged or excessively cupped shiplap or dimensional lumber (excessive cupping is considered 25 mm (1”) or more when measured against the mid-span deflection of the deck), the damaged or distorted material must be removed and replaced with new material.

See also '''5 DECK and WALL OVERLAYS'''.

<li>When cedar or tiles, supported by spaced strapping or board decks (plank, mill, or shiplap), are replaced with asphalt shingles,  

<li>the existing strapping or decking must be overlaid with plywood  

<li>conforming to the Standards in this Manual.

<li>plywood deck overlays must be secured in keeping with the BCBC (Div. B, 9.23), but in any event shall not be less than 23 fasteners

<li>Steel decks are not suitable for asphalt shingle application and therefore must be overlaid with a sub-deck that permits ventilation below the sub-deck.  Sub-deck sheathing must meet the minimum requirements for wood decks (See '''2.2.1 Wood Decks''').

<span class="reference">Electrical cables (including conduit) or boxes installed inside, on top of, or beneath a roof assembly expose roofing workers to electrical shock, {{hilite | and may inhibit the installation of some roof systems designed to resist wind uplift.  Furthermore, electrical cables on, in or under the roof assembly || 2021-February-7 }} expose the building and the public to both shock and fire.  Hidden electrical wiring and boxed junctions can be extremely difficult to document before work begins, and while some technologies are purportedly accurate in identifying energized circuits before they are damaged, false readings make these technologies less than reliable.  During replacement roofing, avoiding damage to electrical circuits from cutters and fasteners is sometimes next to impossible.  It is therefore desirable to design buildings with realistic separations between electrical wiring and boxes, and roof assemblies</span>.

<span class="reference">For more about this topic, see the reprinted Safety Bulletin issued by the BC Safety Authority, republished in the November 10, 2015</span> [http://www.rcabc.org/technical/technical-updates/ '''Technical Update'''].

<span class="reference">Currently, neither the ''Canadian Electrical Code, Part I'' nor the ''British Columbia Electrical Code'' explicitly prohibit, nor explicitly permit, the installation electrical cables and boxes anywhere in close proximity to a roof assembly</span>.  <span class="principles">The ''Design Authority'' therefore has the latitude to write restrictions concerning the location of electrical installations, and consequently eliminate shock and fire hazards.  To do so, apply the following standards when preparing ''Project'' specifications to qualify for a '''''RoofStar Guarantee'''''</span>.

##the supporting deck structure equals or exceeds 76 mm (3”) in thickness {{hilite | ('''Figure 2.7.1-2''') || 2021-February-7 }}, or

#If existing electrical cables or boxes do not conform to the standards in '''2.7.1 New Construction''', the ''Design Authority'' must consider the attachment of the roof system above the electrical system, and the requirements set out in '''3 SECURING the ROOF ASSEMBLY'''.

<li>Shingles shall be installed to resist wind, in conformity with CSA A123.51, or as specified by the shingle manufacturer, whichever requirement is greater.

The following minimum standards apply to any roof assembly, regardless of requirements published elsewhere.  

<li>Fasteners and adhesives must be capable of securing the roof assembly components to resist uplifting wind loads.

<li>manufactured in conformity to CSA B111.

<li>of sufficient length to penetrate through, or at least 19 mm (3/4”) into, the roof deck (sheathing).

<li>When the roof system incorporates an insulation assembly on the exterior side of the supporting deck structure, self-drilling screws with recessed heads must be used in combination with plates as follows:

<li>Bitumen is not typically used as an adhesive for insulation and other components on water-shedding roofs, but if it is specified, it must be Type 3 or SEBS.  Pay attention to the slope limitations specified by the manufacturer of the product.

<li>Nail penetration into or through the deck must be at least 19 mm (¾”) when measured from the top face of the deck.

<li>Only nails driven perpendicular to the shingle and supporting deck surface shall be deemed acceptable.

<li>perpendicular to the surface of the deck, and must not be under-driven, over-driven or crookedly driven.   

<li>into or through the deck at least 19 mm (¾”) when measured from the top face of the deck.

<li>steel decks at least 20 mm (3/4") – <span class="principles">fasteners should penetrate the top flutes only</span>.

<li>On '''Low Slopes''' and '''Common Slopes''' (up to 1:1 (12" in 12")), at least four (4) nails for each full shingle shall be used.

<li>On '''Steep Slopes''' (1:1 (12" in 12") up to and including 21:12), at least 6 nails for each full shingle shall be used.

<li>Notwithstanding any nailing patterns specifically accepted by the '''''RoofStar Guarantee Program''''', shingles installed on '''Extreme Slopes''' (slopes greater than 21:12) shall be

<li>All roofing components installed by the contractor must be  

{{hilite | Also see '''1.6 (2) RoofStar Guarantee: Coverage and Limitations''' for restrictions and limitations on any roofing material, linear metal flashing, penetration flashing or drain used on a Project qualifying for a '''''RoofStar Guarantee'''''|| 2021-February-7 }}.

<li>Notwithstanding the foregoing, asphalt shingles must conform to ''CSA A123.5''.

<li>Roofing Cement must be asphalt-base conforming to ''CGSB 37-GP-5Ma''.

===Design===

<li><span class="reference">A roof deck overlay is installed as part of the Roof Assembly, on the top surface of the roof deck but beneath the roofing materials. On roofs covered with asphalt shingles, the most common deck overlay is plywood, installed to provide a suitable nailable surface for shingles; it often is installed over decks that are rough, uneven or gapped. Roof deck overlay materials may also be applied to other types of supporting deck structures, depending on the roof design criteria</span>.

<li><span class="reference">Wall overlays are less common on Projects using asphalt shingles, but may be required to provide a suitable surface for self-adhering membrane flashing</span>.

<li><span class="reference">For roof assemblies designed above a vaulted conditioned space, see also</span> '''6.1.3.2 Ventilation'''.

<li>Deck and wall overlays must be suitable for, and compatible with, any membrane or panel application.  Plywood, measuring at least 12.7 mm (1/2”) in thickness, is acceptable as a deck or wall overlay.

<li>Walls that require resurfacing for membrane application must be covered with an accepted wall overlay.  See Accepted [http://rpm.rcabc.org/index.php/Wall_Overlays '''Wall Overlays'''].

<li>Deck overlays must be

<li>installed over any deck that is not suitable as a substrate for asphalt shingles (see '''2 SUPPORTING STRUCTURES: Decks and''' Walls).

<li>independently fastened to the supporting deck.

<li>Wall overlays  

<li>Steel decks are not suitable for asphalt shingle application and therefore must be overlaid with a sub-deck that permits ventilation below the sub-deck.  See also '''2.2.1 Wood Decks''' and '''2.2.2 Steel Decks'''.

<li>A mechanically-fastened overlay is required for any deck structure that does not meet the criteria for a suitable deck surface set out in '''2.2.1 Wood Decks'''.  Wood deck overlays must be securely fastened with ring-shanked nails having a shank at least 3 mm thick and a head at least 9.5 mm in diameter.  Fasteners must penetrate structural material at least 19 mm (3/4”).

<li>Where the wall surface is unsuitable to receive a membrane, it must be covered with an accepted overlay material.

<li>Wall overlays must be  

See more information on [http://rpm.rcabc.org/index.php?title=Air_and_Vapour_Control '''Air and Vapour Control'''] in ''Division B: Essential Elements''.

<span class="reference">Air and vapour control layers, along with thermal barriers, water resistive barriers and water-shedding surfaces, serve to separate the outside environment from the interior environments of a structure. Continuous air control layers are perhaps the most critical. Building Codes in force in each jurisdiction, and the '''National Energy Code''' (2011), require the selection and proper installation of “a continuous air barrier system comprised of air-barrier assemblies to control air leakage into and out of the conditioned space” (NEC 2011)</span>.

<span class="reference">'''Air control layers''' control “flow of air through the building enclosure, either inward or outward” (''Guide for Designing Energy Efficient Building Enclosures'', '''Homeowner Protection Office'''). Controlling air flow into and out of conditioned spaces affects the performance of “thermally efficient enclosure assemblies” (ibid), impacts the potential for condensation in between materials, and directly influences rain water penetration of the building envelope. Some air control layers are considered vapour permeable, others vapour-impermeable. The suitability of one over the other, in the application of a roofing system, is left to the discernment of the ''Design Authority''</span>. <span class="recommended">Consequently, the '''''RoofStar Guarantee Program''''' strongly recommends that designers and builders of roof systems intended to qualify for a '''''RoofStar Guarantee''''' carefully consider the regulatory design and installation requirements for effective, continuous air control systems</span>.

<span class="reference">'''Vapour control layers''' regulate or prohibit the movement of water vapour from one space to another by means of diffusion. Consequently, these control layers are referred to as either vapour-permeable or impermeable. Diffusion is a slow process, in contrast to air movement, and its regulation is not always mandatory or even desirable. Consequently, because continuous vapour control layers “are not needed within all climate zones and assemblies”, they are considered non-critical and may be left to the discretion of the ''Design Authority''</span>. <span class="recommended">Nevertheless, where continuous vapour control layers are required and specified by provincial or municipal building codes (current and in force), the '''''RoofStar Guarantee Program''''' requires that a suitable vapour control system be selected by the ''Design Authority'' and properly installed by the roofing contractor in conformity with the vapour control layer manufacturer’s published instructions, and with the ''Design Authority’s'' specified details</span>.

#Air and vapour control layer performance is not part of the '''''RoofStar Guarantee''''', and air and vapour control materials are not listed in the ''Accepted Materials'' Division of this '''Manual'''. Therefore, the decision to specify air and vapour control layers, the placement of continuous air and vapour control layers in relation to a roof assembly and its components, and the selection of suitable materials for that application, is the sole responsibility of the ''Design Authority''.  <span class="recommended">The ''Design Authority'' is urged to review and consider the performance characteristics of materials available for such applications</span>.

#Neither the '''''RoofStar Guarantee Program''''' nor the roofing contractor will accept any responsibility for damage to, or failure of, the roof system caused by the use or absence of air or vapour control layers.

<span class="recommended">Roof systems for facilities such as these, with high-humidity environments, may be susceptible to the accumulation of moisture within the roof assembly unless an effective air and vapour controls are installed</span>.

<li>The design and selection of the ventilation system is the responsibility of the Design Authority, and may be achieved by incorporating into the roof design both intake and exhaust vents, including (without limitation),

<li>meet the minimum requirements set out by the Code having jurisdiction, even in conditions where snow cover is present (see ''British Columbia Building Code'', Part 9 for Housing and Small Buildings, Section 9.19 Roof Spaces, 9.19.1.3 Clearances).  Roofs that do not provide adequate ventilation do not qualify for a RoofStar Guarantee.

See also ''Building Ventilation'' in '''Division B''' of this '''Manual'''.

<li>The material selected for air and vapour control layers must be compatible with any other materials in the roof or wall assembly to which the control layer may come in contact.  This includes, without limitation, contact with primers and adhesives, substrates, solvents and cleaners.

<li><span class="principles">Fully supported air and vapour control layers should possess a minimum published static puncture resistance rating of 150 N (34 lbf) (ref. CGSB-37.56-M for both test method and standard limits) and be either self-adhering or torch-applied; a high puncture resistance is necessary for the membrane to withstand accidental damage during construction</span>.  For unsupported air and vapour control layers, see '''6.2.3''' below. Therefore, while responsibility for the selection of suitable air and vapour control layers rests with the ''Design Authority'', a roof designed and built to qualify for a '''''RoofStar Guarantee''''' shall not include either polyethylene sheet plastic or bitumen-impregnated kraft paper.

<li><span class="recommended">Notwithstanding any of the foregoing, the '''''RoofStar Guarantee Program''''' strongly recommends that any air or vapour control systems be installed over a smooth, continuous plane (for example, concrete or plywood). Consequently, a deck overlay board installed on corrugated steel roof decks in highly recommended</span>. Where no deck overlay board is installed and the air and vapour control layers are partially unsupported (for example, on a steel deck), the control layers each must have a published static puncture resistance of at least 400 N (90 lbf). Furthermore, both the side laps and end laps must be fully supported.

<li><span class="recommended">Should the air or vapour control layers be used as a temporary roof during ''Project'' construction by either the roofing contractor or by other trades, a minimum 2mm thick bituminous membrane is recommended</span>.

<li>Proper installation and continuity of air and vapour control layers within the roof assembly is the responsibility of the roofing contractor. Therefore,  air and vapour control layers in the roof assembly must

<li>extend beyond the end of the roof assembly at least 100 mm (4”), in new construction, to provide sufficient room for the installation of matching control layers to so that they provide a positive (water-shedding) lap seal union between courses of material.

<li>Installation must be smooth and uniform, without wrinkles or fish-mouths, and must also conform to the manufacturer’s published requirements and the Design Authority’s design details.

:;''Heat-sensitive insulation'': means insulation that may be physically or chemically altered when exposed to heat greater than 70°C (158°F) - for example, heat from a torch or from liquefied bitumen.  Heat-sensitive insulation includes EPS, XPS and Polyurethane.

:;''Heat-resistant insulation'': means insulation that resists heat and will not physically or chemically change when exposed to heat greater than 70°C (158°F), including liquefied bitumen.  Insulation boards of this type include fibreboard, polyisocyanurate and mineral wool.  Note that heat-resistant does not mean or even infer 'fire-proof'.  While some heat-resistant insulation materials will resist burning for a period of time, only mineral wool insulation will not burn.

See the [http://rpm.rcabc.org/index.php?title=Glossary '''Glossary'''] for other terms used in this '''Manual'''.

<li>Consult the Building Code having jurisdiction for the minimum required thermal resistance of the roof assembly.

<li>Insulation materials rely on various standards for the determination of thermal resistance, which means that not all data can be easily compared. Furthermore, not all insulation products perform with consistent thermal resistance as temperature changes, and some insulation performance declines with age. The ''Design Authority'' is therefore urged to consider the Long Term Thermal Resistance (LTTR) for each product, in relation to its placement within the roof assembly and the anticipated outside and interior climates of the building.

<li>In warm seasons, the roof surface may reach temperatures higher than 85°C (185°F), affecting the performance and stability of some insulation. Combining insulation types in a roof assembly may help mitigate these temperature swings and consequential distortion of the assembly. The ''Design Authority'' therefore must consider these variables when specifying materials and their installation.

<li><span class="recommended">Only heat-resistant insulation is recommended for use in an insulated, ventilated roof assembly covered with asphalt shingles</span>.  <span class="principles">When heat-sensitive insulation is desirable, the ''Design Authority'' should calculate the anticipated maximum temperature for the upper surface of the insulation assembly and ensure the insulation material’s service temperature is suitable for the design</span>.

<li>Insulation assemblies with a cumulative thermal resistance greater than RSI-2.64 (R-15) (based on published values measured at 24°C) must be installed in multiple layers that are offset and staggered (see '''7.3 Application'''). Within that multi-layered assembly, any single layer of insulation may have a thermal resistance greater than RSI-2.64 (R-15) provided no one layer exceeds 60% of the cumulative thermal resistance of the combined assembly of insulation and insulation overlay boards.

<li>The maximum width and length of insulation boards installed with mechanical fasteners is limited only by the manufacturer

:;''Eave Protection'': means a self-adhering membrane applied in parallel courses along the eaves, up the roof slope to a point measured vertically from the inside of the exterior wall, and intended to block the ingress of water that may leak behind shingles or metal roof panels as the result of snow or ice buildup on the roof surface.

:;''Underlayment,'': sometimes referred to as Waterproof Shingle Underlayment (WSU), means a roll material that is either self-adhering or mechanically fastened (typically with large head nails), and which

::#provides a secondary water-shedding surface between the shingles or metal panels and the building interior.

::#keeps shingles or metal panels from adhering to the underlying substrate.

See the [http://rpm.rcabc.org/index.php?title=Glossary '''Glossary'''] for other terms used in this '''Manual'''.

<li>Eave protection is required on all '''Common Slope''', '''Steep Slope''' and '''Extreme Slope''' roofs, but is not required

<li>An underlayment is required  

<li>beneath all water-shedding roof materials, irrespective of slope.

<li><span class="recommended">In all applications, a non-adhering roof field underlayment may be specified as a separation layer over any self-adhering membrane (used as eave and rake protection, or as a full underlayment on Low Slope or Flat Roofs), to separate the shingles from the membrane and thus prohibit bonding of the two.  This approach may simplify future shingle replacement, as a result, spare the supporting deck structure from damage during tear-off</span>.

<li>Metal flashings along the eave and rake (gable) edges are required on all Projects and must be separated from direct contact with wood surfaces.  See also '''10 PERIMETERS and WALLS''', and '''13 METAL FLASHINGS'''.

<li>Eave Protection must be  

<li>at least {{hilite | 1.4|| 2021-February-7 }} mm thick {{hilite |or, in the alternative, another RGC-accepted eave protection membrane supported in writing by the asphalt shingle manufacturer.  Written confirmation from the manufacturer must be submitted to the Guarantor as part of the project documentation|| 2021-February-7 }}.

<li>At least one ply of 15 lb. non-perforated asphalt saturated felt conforming to ''CSA A123.3 M1979'' and / or ''ASTM D226-95'', and as acceptable under the '''''RoofStar Guarantee Program''''' (see [http://rpm.rcabc.org/index.php?title=Eave_Protection_%26_Underlayment_(Asphalt_Shingles,_Cedar_Shakes_%26_Shingles) '''Eave Protection & Underlayment'''] for shingle roofing).

<li>Eave protection is required on all '''Common Slope''', '''Steep Slope''' and '''Extreme Slope''' roofs, but is not required

<li>where the roof overhang exceeds 915 mm (3′) measured along the roof slope from the edge of the roof to the inner face of the exterior wall.

<li>Self-adhering eave protection is required irrespective of roof slope, and must  

<li>extend up the slope to a point, when measured vertically from the inner face of an exterior wall,

<li>extend up all abutments (walls, skylights, etc.) at least 150 mm (6″) above the finished roof surface.

<li>Horizontal runs of eave protection must be positively lapped at least 50 mm (2″) and end laps (vertical joints) must be at least 150 mm (6″).

<li>An underlayment must be installed  

<li>parallel to the eave, and each course of underlayment must positively overlap adjacent material by  

<li>beneath all water-shedding roof materials, irrespective of slope.

<li>When the roof slope is less than 1:3, the underlayment over the entire roof – in the field, on vertical surfaces and beneath all penetrations – must be self-adhering.  See 8.2.1 Eave Protection and Underlayments for material requirements.

<li>Where negative (backward) laps are unavoidable, only a RoofStar-accepted self-adhering underlayment may be used. Negative laps must be at least 150 mm (6”), and seams must be roller-pressed and sealed with a compatible mastic along the seam edge.

<li><span class="recommended">To prevent shingles from bonding to self-adhering membranes, and simplify future roof replacement, a non-bonding underlayment may be used as a separation layer between the shingles and the membrane</span>.

<li>In addition to the General requirements above, '''Low Slope''' roofs may be fully covered with  

<li>one layer of self-adhering eave protection membrane equal to or exceeding the minimum thickness requirements, or

<li><span class="reference">The Standards published in this Part, and in those that follow, reflect the level of attention to design and application required by the designed slope of the roof.  Shingles are water-shedding materials, and low slopes may affect the flow of water, necessitating more rigorous requirements to keep water from reaching the supporting deck structure and the conditioned space of the building</span>.

<li>All asphalt shingles shall be manufactured in compliance with the material standards found in ''CSA A123.5'', and shall in any event

<li>Starter shingles or rolls must be acceptable to the field shingle manufacturer.

<li>expressly manufactured and accepted for application on Low Slope roofs.

<li>manufactured to ''CSA A123.5'' for fibreglass felt shingles with a minimum mass of 10.50 kg per m² (215 lb per 100 sf).

<li>See Part '''3 SECURING the ROOF ASSEMBL'''Y for field shingle nailing requirements.

<li>Asphalt Shingles shall be installed to ''CSA-A123.51 Asphalt shingle application on roof slopes 1:6 and steeper''.   

<li>A starter strip or strip-type shingle is required at the eaves and rake (gable) edges, below the first course of shingles and must be installed  

<li>When roofing work is complete, the Contractor must remove all temporary fall protection fittings and equipment.   

<li>Shingles may not be installed on Low Slope roofs unless expressly permitted by the shingle manufacturer.

<li>Shingles on '''Low Slope''' roofs must be installed over a self-adhering membrane or multi-layered membrane.  See 8.3.2.2 Low Slope Roofs for application requirements.

<li>Underlayment for the lower roof area must be brought up onto the upper roof deck at least 200 mm (8”) but must extend past the top edge of the metal transition flashing by at least 50 mm (2”).

<li>installed over the underlayment.

<li>When the angle between slopes is less than 180° (when the lower roof plane slope is less than the slope of the upper roof plane), a self-adhering membrane strip is required to overlap the upper edge of the metal flashing by at least 50 mm (2”); the membrane must extend up-slope at least 50 mm (2”) past the bottom layer of underlayment and be sealed to the roof deck.

<li>Shingles installed on the upper slope must be started and installed as a new slope, in keeping with the Standards in this '''Manual'''.

:See the [http://rpm.rcabc.org/index.php?title=Glossary '''Glossary'''] for other terms used in this '''Manual'''.

<li>{{hilite | Linear metal flashings described in any Part of this Standard are considered necessary and integral to the scope of a Project designed and constructed to qualify for a '''''RoofStar Guarantee'''''.  Furthermore, only new linear metal flashings may be specified and installed; reuse of any existing linear metal flashings is prohibited and may void the Guarantee.  See also '''1.6 RoofStar Guarantee: Coverage and Limitations'''|| 2021-February-7}}.

<li>Metal flashings must be  

<li>be securely fastened to the deck with acceptable nails placed no more than 400 mm (16”) O.C.

<li>separated from a wood substrate with self-adhered eave protection membrane or mechanically fastened underlayment.

<li>Where a '''Steep Slope''' roof plane drains onto a '''Common Slope''' or '''Low Slope''' roof, the valley metal flashing must be fashioned with double inverted “V” dividers.  Refer to '''Figure 13.3''' for valley flashing requirements.

<li>Metal valleys must be used for laminate, interlocking and '''Low Slope''' shingle applications, and in any event are recommended for all roof designs.

<li>Starter shingles or rolls must be acceptable to the field shingle manufacturer.

<li>Membranes used to flash transitions with walls, parapets or curbs must meet the Standards found in 8.2.1 Eave Protection and Underlayment.

<li>Membranes used in built-in gutters or dead valleys must meet the Standards found in 12.2.2 Materials.

<li>The Standards in this Part may not include every possible detail the Contractor will encounter, but every installation must be executed in keeping with the following:

<li>Every transition in plane must be flashed (under-laid) with a non-adhering underlayment or a self-adhering membrane; the choice is slope-dependent and at the discretion of the ''Design Authority'', but in any event is subject to the Standards prescribed in '''Part 8'''.

<li>See Part '''3 SECURING the ROOF ASSEMBLY''' for shingle nailing requirements.

<li>Metal flashings must be  

<li>separated from all substrates with self-adhered eave protection membrane or mechanically fastened underlayment.

<li>A starter course is

<li><span class="recommended">In valleys and at eave and rake edges, extend the underlayment over the self-adhering membrane to keep shingles from bonding to the membrane</span>.

<li>fabricated with drip edges along all three sides and a flange extending onto the roof deck surface.

<li>Projects must follow proper sequencing. This means that materials must be installed so that they interface with other materials, systems or assemblies, including those installed by other trades, in “shingle fashion” by positively overlapping them below or above. Occasionally, the coordination with other trades requires some adaptation to this Standard. When that is the case, any variance to proper detail sequencing must be approved by the ''Design Authority'' in writing.

<li>Metal flashing is required on all Projects.

<li>Eave protection or metal flashing underlayment must overhang eave fascia at least 25 mm (1”), to direct water into gutters.  See also '''8.3.1 Eave Protection'''.

<li>below the eave protection layer.

<li>so that the flashing extends at least 12 mm (1/2”) past the edge of the supporting deck structure, to accommodate gutter hangars (for existing or specified gutters).

<li>All types of shingles installed on '''Common Slope''' and '''Steep Slope''' roofs must  

<li>be installed with a starter course along the eaves.

<li>overhang the fascia approximately 37 mm (1 ½”), <span class="principles">or with sufficient overhang to lead water into exposed eaves trough</span>.  <span class="recommended">Extend the overhang further for Low Slope roofs</span>.

<li>continuous metal flashings must be installed

<li>with nails driven through the flashing leg into the roof deck no more than 400 mm (16”) O.C.

<li>Shingles installed on low slopes must be sealed in a bed of compatible mastic at all rake edges.

<li>Step flashings connecting the roof to a wall must be constructed to the following Standards:

<li>125 mm (5") up vertical surfaces behind wall control layers (e.g. water, vapour, air) or a counterflashing (where used).

<li>fastened with nails located 50 mm (2") down from the top edge and 25 mm (1") in from the outside edge on the deck flange portion of each step flashing.

<li>When the fascia board extends above the finished roof surface, step flashings trimmed to the height of the fascia must be used.  Cap flashings that cover the top surface of the fascia board must be joined and secured in keeping with the Standards in '''13.3.2 Securement and Seams'''.

<li>must be installed under the first course of shingles at the junction of roof eaves and a wall and must be installed over roof material by at least 100 mm (4").

<li>'''Low Slope''' roofs.

<li>for '''Common Slope''' and '''Steep Slope''' roofs may be constructed with one layer of granule-faced SBS-modified bituminous membrane

<li>be installed before any shingle application.  The installation of shingle starter strips beneath the metal valley flashings is not acceptable.

<li>be secured to the deck  

<li>with cleats nailed to the roof deck no more than 450 mm (18”) O.C. and hooked onto the outside edges of the flashing.

<li>have two evenly spaced upstand diverters/dividers where a '''Steep Slope''' roof drains onto a '''Common''' or '''Low Slope''' roof.  See '''13.3.1 Fabrication''' for metal flashing requirements.

<li>Laminated shingles used as a valley starter must be  

<li>laid perpendicular to the roof slope and overlap the valley starter shingles installed on either side of the valley centreline.

<li>secured no closer than 150 mm (6") from the butt edge of valley starter shingles.

<li>completely cover the butt-end joints of valley starter shingles.

<li>ridge cap shingles and the continuing courses of shingles on the main roof slope must be installed using a Split Ridge Cap Shingle Transition.

<li>secured in keeping with Part 3; nails must penetrate through, or at least 19 mm (3/4”) into, the roof deck.

<li>up a slope onto an upper waterproofing assembly (Figures '''10.1''' and '''10.2'''),

<li>the transition may be made with a headwall flashing and a parapet or a metal edge termination (following the requirements for either in the '''''RoofStar Guarantee Standards''''' for Waterproofing Roof Assemblies).

<li>the waterproofing must be completed in accordance with the Standards found in '''10.3.5.4 Transitions with Water-shedding Systems''' (Waterproofing Standards for any membrane type).

<li>down a slope onto a lower waterproofing assembly (Figures '''10.3''' and '''10.4'''),  

<li>the waterproofing must be completed in accordance with the Standards found in '''10.3.5.4 Transitions with Water-shedding Systems''' (Waterproofing Standards for any membrane type).

<li>shingles must be started with a Starter Course.

<li>shingle underlayment must overlap the waterproofing flashing by no less than 100 mm (4”).

<li>the lowest course of shingles should terminate above the waterproofed roof no closer than 100 mm (4”).

=DRAINAGE and PENETRATIONS=

This Part contains standards and references to membrane work that may be atypical of asphalt shingle roof construction.  These are nevertheless included to address situations where multiple types of roof systems intersect or overlap, or where membrane gutters are employed (see also '''12.2 Built-in Membrane Gutters''').  The reader is advised to read this Part with consideration to the entire scope of the Project design and its construction.  Other Standards for Waterproofing Roof Systems may also apply.

<li>Drains and overflows used in membrane gutters may be found in any of the Waterproofing Roof Systems Standards.  The reader is advised to consult the relevant standard for design, material and application requirements.

<li>Type B or C ventilators manufactured to conform to or exceed the requirements set out in ''CAN3-A93-M82 (R2003'') for '''Natural Airflow Ventilator for Buildings'''.

<li>B-vent and plumbing vent flashings must be at least 200 mm (8") in height, measured vertically from the top of the finished roof surface to the opening or top of the flashing.

<li>The Standards in this Part may not include every possible detail the Contractor will encounter, but every installation must be executed in keeping with the following:

<li>Every transition in plane must be flashed (under-laid) with a non-adhering underlayment or a self-adhering membrane; the choice is slope-dependent and at the discretion of the ''Design Authority'', but in any event is subject to the Standards prescribed in '''Part 8'''.

<li>The underlayment below shingles, regardless of its type, serves as the final water barrier above the roof deck.

<li>All penetration and linear flashings must be separated from the underlying substrate with underlayment or a self-adhering eave protection membrane.  See '''8 EAVE PROTECTION and UNDERLAYMENTS'''.

<li>Linear flashings used at walls, curbs or other vertical surfaces must be installed behind (covered with) any control layers, finish materials and counterflashings.

<li>When installing heat-welded membranes, or where construction sequencing requires it, alternatives to conventional membrane flashing should be considered. Refer to '''11.3.3.2 Alternative Membrane Flashing Approaches''' in the '''SBS-Modified Bitumen Membrane Roof Systems''' standards.

<li>For the application of roof drains, refer to Part 11 in the applicable Waterproofing Roof System standards.

<li>The use of downspouts, installed by the Contractor or other trades and laid directly against the slope of the roof to connect an upper roof drainage to lower gutters, is acceptable under the RoofStar Guarantee Program, provided the material is strongly secured both at the top and the bottom.  The use of a spillway flashing is optional.

<li>flashed in with a self-adhering eave protection membrane ‘horseshoe’ as described in '''11.3.1 General'''.

<li>All curbs incorporated into the Water-shedding system must be

<li>no less than 150 mm (6”) in height above the roof deck.

<li>extend at least 75 mm (3") downslope from the corner of a vertical surface (wall or curb) and have a 75 mm (3") head-lap above the shingle exposure.

<li>fold around the top face of a curb and extended upslope, behind and beneath the backpan.

<li>Where step flashings are used, a drainage path of no less than 6 mm (1/4”) and no more than 12 mm (1/2”) must be provided between the edge of the shingle and the vertical face of the step flashing  

<li>into the curb through the flashing upstand.

<li>into the roof deck along the top edge of the backpan, and 300 mm (12”) down from the top of the backpan, on either side.

<li>Curbs with widths  

<li>is integrated with the curb or chimney flashings.

<li>extends up-slope from the back of the curb, beneath the shingles and underlayment to a point at least 150 mm (6”) (when measured vertically) from the base of the curb.