1 Scope
NOTE This specification covers the field-applied thermal insulation, jacketing, vapor retarders, and protective covers for plumbing piping installed within the building envelope. (1.1)
NOTE The work includes insulation of domestic hot water supply and recirculation piping for energy conservation; insulation of domestic cold water piping for condensation (sweat) control; insulation of horizontal storm and roof-drainage piping, roof-drain bodies and sumps, and overflow (secondary) drainage piping for condensation control on cold rainwater; and the molded or field-formed protective covers required on exposed water-supply and waste piping below accessible lavatories and sinks. (1.2)
NOTE The boundary of work under this standard is the insulation system on plumbing piping inside the building. (1.3)
1.4Insulation on heating-hot-water and chilled-water hydronic piping, on supply and return ductwork, and on mechanical equipment is covered by Mechanical Insulation and shall not be duplicated here; insulation on refrigerant lines is covered by Refrigerant Piping. NOTE Factory-insulated equipment is excluded. (1.6)
NOTE The reason plumbing piping is insulated differs by service, and the governing requirement is different for each: hot water for energy conservation, cold water and storm for condensation control, and ADA covers for accessibility. (1.7)
NOTE Hot water piping is insulated to conserve energy — an uninsulated hot main bleeds heat continuously, wastes the energy used to heat the water, and on a recirculation system forces the pump and water heater to run harder to hold the loop temperature — so the energy code sets a minimum thickness by pipe size and water temperature. (1.8)
NOTE Cold water and storm piping are insulated to stop condensation — a pipe below the surrounding air's dew point sweats, and the drip stains ceilings, corrodes hangers and the pipe, feeds mold, and damages finishes — so the controlling feature is a continuous, unbroken vapor retarder rather than thickness for heat loss. (1.9)
NOTE The ADA protective covers serve accessibility — they prevent a wheelchair user, who cannot see or feel the piping under a lavatory, from being burned by a hot supply or trap or abraded by a rough surface. (1.10)
NOTE Because these three drivers — energy, condensation, and accessibility — are independent, this standard keeps them separate, and a single project commonly applies all three. (1.11)
1.12Materials, thicknesses, and installation shall comply with the adopted energy code (the International Energy Conservation Code or ANSI/ASHRAE/IES Standard 90.1, whichever the jurisdiction enforces), the International Plumbing Code, and ICC A117.1 and the ADA Standards for Accessible Design.
2 Referenced Standards
2.1Materials and installation shall comply with the latest adopted editions of the standards and codes listed below.
| Standard |
Title |
| ASTM C547 |
Mineral Fiber Pipe Insulation |
| ASTM C534 |
Preformed Flexible Elastomeric Cellular Thermal Insulation in Sheet and Tubular Form |
| ASTM C1126 |
Faced or Unfaced Rigid Cellular Phenolic Thermal Insulation |
| ASTM C1136 |
Flexible, Low-Permeance Vapor Retarders for Thermal Insulation (all-service jacket / ASJ facing) |
| ASTM C795 |
Thermal Insulation for Use in Contact with Austenitic Stainless Steel |
| ASTM C871 |
Chemical Analysis of Thermal Insulation Materials for Leachable Chloride, Fluoride, Silicate, and Sodium Ions |
| ASTM C692 |
Evaluating the Influence of Thermal Insulations on External Stress-Corrosion-Cracking Tendency of Austenitic Stainless Steel |
| ASTM E84 |
Surface Burning Characteristics of Building Materials (flame-spread / smoke-developed) |
| ASTM C921 |
Properties of Jacketing Materials for Thermal Insulation |
| ANSI/ASHRAE/IES 90.1 |
Energy Standard for Buildings Except Low-Rise Residential Buildings (service-hot-water pipe insulation, Table 6.8.3-1) |
| IECC |
International Energy Conservation Code (service water heating piping insulation, Section C404) |
| IPC |
International Plumbing Code (storm-drainage condensation insulation, Chapter 11) |
| ICC A117.1 |
Accessible and Usable Buildings and Facilities (exposed pipes and surfaces, Section 606.5) |
| ADA |
ADA Standards for Accessible Design (lavatories and sinks) |
| MSS SP-58 |
Pipe Hangers and Supports — Materials, Design, Manufacture, Selection, Application, and Installation |
2.2Materials and installation shall comply with the latest adopted editions of the standards and codes listed above.
2.3Where the contract documents, the adopted energy or plumbing code, the accessibility standard, or a referenced standard conflict, the more stringent requirement shall govern unless the Engineer of Record directs otherwise in writing.
3 Submittals
3.1 Action Submittals
NOTE The action submittals required for this work are listed below. (3.1.1)
NOTE Each is reviewed and returned by the Engineer before procurement and installation. (3.1.2)
- Product data for each pipe insulation material, showing the governing ASTM specification (C547, C534, or C1126), the thermal conductivity at the applicable mean temperature, the maximum service temperature, the water-vapor permeability or permeance, and the ASTM E84 flame-spread and smoke-developed indices
- Product data for jacketing and vapor-retarder materials, showing the all-service jacket compliance with ASTM C1136, PVC fitting-cover material, and metal jacket gauge and finish per ASTM C921 where used
- A pipe insulation thickness schedule listing each system (domestic hot water, recirculation, domestic cold water, storm/roof drainage, overflow) with the insulation material, the thickness by pipe size, and the energy-code table and edition that governs the hot water thicknesses
- Product data for the ADA molded protective covers, showing the covered piping (hot supply, cold supply, waste/trap), the material, and that the assembly presents no sharp or abrasive surface
- ASTM E84 25/50 flame-spread and smoke-developed test reports for insulation and jacketing installed in plenums and other concealed combustible-restricted spaces
- Product data for hanger inserts, insulation protection shields, and saddles
- Where insulation contacts austenitic stainless steel piping, documentation of compliance with ASTM C795 (leachable-chloride limits per ASTM C871 and stress-corrosion testing per ASTM C692)
☐ Pipe insulation product data (ASTM C547 / C534 / C1126) with conductivity and E84 indices
☐ Jacketing and vapor-retarder product data (ASTM C1136 ASJ, PVC, metal)
☐ Pipe insulation thickness schedule by system and pipe size
☐ ADA protective cover product data (hot, cold, waste/trap)
☐ ASTM E84 25/50 flame/smoke test reports
☐ Hanger insert, shield, and saddle product data
☐ ASTM C795 stainless-steel-contact compliance (where applicable)
3.1.3The Contractor shall submit the action submittals listed above for the Engineer's review and return before procurement and installation.
3.1.4Submittals shall identify each insulation product against the service (hot water, cold water, storm, ADA) for which it is proposed.
3.2 Closeout Submittals
3.2.1At substantial completion, the Contractor shall provide manufacturer maintenance data for the installed insulation systems and a record of any locations where insulation was omitted by the contract documents (factory-insulated equipment, buried piping, and unions or valves left accessible for service).
4 Quality Assurance
4.1 Installer Qualifications
4.1.1Insulation shall be applied by workers experienced in the installation of pipe insulation, vapor-retarder systems, and jacketing, and familiar with the continuity requirements that make a cold-service vapor retarder perform.
4.2 Mockup
NOTE On projects with extensive exposed insulated piping or metal-jacketed runs, a sample length of each insulation type establishes the standard of workmanship before production work begins. (4.2.1)
○ Mockup of each insulation type, fitting, and hanger detail required before production work
○ No mockup required (limited scope)
4.2.2For projects with extensive exposed insulated piping or metal-jacketed runs, the Contractor shall install a sample length of each insulation type — including a fitting, a hanger with its insert and shield, a butt joint, and the jacket termination — for the Engineer's review before proceeding.
4.2.3The approved mockup establishes the standard of workmanship for the project and may remain as part of the work.
5 Environmental and Service Conditions
5.1 Service Temperatures
NOTE Domestic hot water is typically distributed at 120°F to 140°F, and recirculation return at a few degrees below the supply. (5.1.1)
105160
105120125140160
Default: 140 °F
5.1.2Insulation shall be selected and sized for the operating temperature of the service it covers.
NOTE Domestic cold water and storm/roof-drainage water track the incoming municipal and rainwater temperature and run cold enough through much of the year to drop below the indoor dew point. (5.1.3)
NOTE The hot water temperature determines which row of the energy-code thickness table applies, while the cold and storm services determine that a vapor retarder is mandatory. (5.1.4)
5.2 Installed Location and Exposure
NOTE The location of each insulated run governs the jacket and the protection it needs. (5.2.1)
Concealed — chases, above ceilings, in walls (all-service jacket)
Exposed in finished occupied spaces (all-service jacket with PVC fitting covers)
Mechanical rooms / exposed to mechanical damage (metal jacket)
Outdoor / weather-exposed (weatherproof metal jacket)
5.2.2Piping in mechanical rooms, in pipe galleries, and anywhere within reach of foot traffic, ladders, or material handling is exposed to mechanical damage and shall receive a metal jacket.
5.2.3Piping outdoors or in unconditioned space exposed to weather and ultraviolet light shall receive a weatherproof metal jacket with sealed, overlapped, downward-shedding seams.
NOTE Concealed piping in chases, above ceilings, and in walls takes the standard factory all-service jacket, while piping exposed to view in finished spaces takes a clean jacket and PVC fitting covers. (5.2.4)
6 Insulation Materials by Service
6.1The material is chosen by what the insulation must do for each service: shed heat on hot lines, and stop vapor on cold and storm lines.
6.2 Hot Water — Mineral or Glass Fiber with All-Service Jacket
○ Mineral or glass fiber, ASTM C547, with factory all-service jacket (standard)
○ Rigid cellular phenolic, ASTM C1126, with ASJ (where space is restricted)
6.2.1Domestic hot water supply and recirculation piping shall be insulated with mineral or glass fiber preformed pipe insulation conforming to ASTM C547, supplied with a factory-applied all-service jacket (ASJ) that complies with ASTM C1136.
NOTE Fiber is the standard for hot service because it carries the heat-loss performance the energy code is written around, it is inexpensive in the thicknesses the code requires, and it tolerates the service temperature without degrading. (6.2.2)
NOTE The factory ASJ provides a clean finish, a vapor retarder, and a self-sealing lap that closes the longitudinal seam. (6.2.3)
6.3 Cold Water and Storm — Closed-Cell Elastomeric
○ Closed-cell flexible elastomeric, ASTM C534 (standard — integral vapor retarder)
○ Mineral/glass fiber, ASTM C547, with continuous sealed ASJ vapor retarder
6.3.1Domestic cold water piping and horizontal storm/roof-drainage and overflow piping shall be insulated with preformed flexible elastomeric closed-cell insulation conforming to ASTM C534 (Type I tubular, or Type II sheet where pipe sizes or fittings require it).
6.3.2Fiber insulation may be used on cold and storm service only where it carries a continuous, sealed factory ASJ vapor retarder and every seam, joint, fitting, and hanger penetration is vapor-sealed.
NOTE Closed-cell elastomeric is the standard for condensation control because the insulation is itself a continuous vapor retarder — the closed cells do not absorb or pass water vapor, so a properly sealed system has no separate facing that can be punctured and no path for humid air to reach the cold pipe. (6.3.3)
NOTE Because the continuity of a fiber ASJ vapor retarder is difficult to achieve and easy to breach, closed-cell elastomeric is preferred for all condensation-control service. (6.3.4)
6.4 Phenolic Where Space Is Limited
NOTE Phenolic has a lower thermal conductivity than fiber, so it meets the same heat-loss or condensation performance in a thinner wall. (6.4.1)
6.4.2Where the available space will not accommodate the code-required fiber thickness, rigid cellular phenolic insulation conforming to ASTM C1126 may be used.
6.4.3Phenolic shall carry an ASJ vapor retarder on cold and storm service.
6.5 Fire and Smoke Rating
○ 25 flame-spread / 50 smoke-developed maximum per ASTM E84 (standard)
6.5.1All insulation and jacketing installed in air plenums, return-air ceiling cavities, and other concealed spaces where the code restricts combustible materials shall have a flame-spread index of 25 or less and a smoke-developed index of 50 or less when tested per ASTM E84, or shall otherwise be listed for the location.
6.5.2Insulation in contact with austenitic stainless steel piping shall comply with ASTM C795, meeting the leachable-ion limits analyzed per ASTM C871 and qualified per ASTM C692.
NOTE On austenitic (300-series) stainless steel, leachable chlorides wicked from wet insulation can concentrate on the warm pipe surface and cause external stress-corrosion cracking, which is why the leachable-ion limits apply. (6.5.3)
7 Insulation Thickness Schedule
7.1 Hot Water Thickness
NOTE The hot water schedule reflects ANSI/ASHRAE/IES 90.1 Table 6.8.3-1; where the jurisdiction enforces the IECC, the IECC Section C404 values apply and the more stringent governs. (7.1.1)
ANSI/ASHRAE/IES 90.1 (current adopted edition)
IECC Section C404 (current adopted edition)
As adopted and amended by the authority having jurisdiction
1.0 in. — hot water 105–140°F (energy-code minimum)
1.5 in. — hot water above 140°F (energy-code minimum)
1.5 in. — hot water 105–140°F (energy-code minimum)
2.0 in. — hot water above 140°F (energy-code minimum)
7.1.2Hot water insulation thickness shall be not less than the minimum required by the adopted energy code for the pipe size and the water temperature.
7.1.3For domestic hot water at 105°F to 140°F (conductivity 0.22–0.28 Btu·in/(h·ft²·°F) at a 100°F mean), the minimum thickness shall be 1.0 in. for pipe under 1-1/2 in. and 1.5 in. for pipe 1-1/2 in. and larger.
7.1.4For hot water above 140°F (to 200°F; conductivity 0.25–0.29 Btu·in/(h·ft²·°F) at a 125°F mean), the minimum thickness shall be 1.5 in. for pipe under 1-1/2 in. and 2.0 in. for pipe 1-1/2 in. and larger.
7.1.5Insulation of higher thermal conductivity than the table range shall be applied at a proportionally greater thickness, and lower-conductivity insulation such as phenolic may use the code's thickness-adjustment provision to reduce the wall.
NOTE The tabulated thickness values assume insulation with a thermal conductivity in the range stated by the energy-code table at the listed mean rating temperature. (7.1.6)
7.2 Cold Water and Storm Thickness
NOTE Cold water and storm insulation thickness is governed by condensation control rather than the energy table. (7.2.1)
1/2 in. — conditioned interior, normal humidity
3/4 in. — standard interior condensation control
1 in. — high-humidity spaces or where required by AHJ
1 in. — IPC minimum for condensation control (standard)
1-1/2 in. — high-humidity spaces or extended exposure
7.2.2Cold water and storm insulation thickness shall be governed by condensation control rather than the energy table.
7.2.3The thickness shall be sufficient to keep the outer surface above the design dew point of the surrounding space.
7.2.4In ordinary conditioned interiors a 1/2 in. to 1 in. wall shall be provided for cold water condensation control.
7.2.5Roof-drain bodies, sumps, and horizontal storm-drainage runs inside the building shall have not less than the International Plumbing Code minimum of 1 in. of insulation.
7.2.6High-humidity spaces such as natatoriums, kitchens, and laundries shall be sized for the actual design dew point and shall receive a thicker wall accordingly.
8 Jacketing and Vapor Retarders
NOTE The jacket is the outer protective and vapor-retarding skin of the insulation system, and the right jacket depends on where the pipe runs. (8.1)
NOTE The jacket choice matters because the wrong jacket either fails to protect the insulation from damage or fails to keep humid air out of a cold system. (8.2)
8.3 All-Service Jacket — Concealed and Finished Interior
NOTE The ASJ provides the vapor retarder on cold and storm service, a clean finish, and a self-sealing longitudinal lap. (8.3.1)
○ Factory all-service jacket (ASJ) per ASTM C1136 with self-sealing lap (standard)
8.3.2Concealed piping and exposed piping in ordinary finished spaces shall use insulation with a factory-applied all-service jacket (ASJ) conforming to ASTM C1136.
8.3.3Where the jacket is the vapor retarder, the lap and every butt-joint strip shall be sealed continuously.
8.4 PVC Fitting Covers — Exposed Finished Spaces
NOTE Preformed PVC fitting covers give a smooth, cleanable, uniform finish on exposed fittings that field-applied insulating cement and tape cannot match. (8.4.1)
8.4.2Fittings, valves, and strainers on exposed insulated piping in finished spaces shall be covered with preformed PVC fitting covers over insulation inserts.
NOTE Metal jacket protects the insulation from impact, abrasion, and — outdoors — from water entry and ultraviolet degradation. (8.5.1)
Aluminum jacket with moisture barrier, per ASTM C921 (standard)
Stainless steel jacket (corrosive or high-abuse environments)
Not required (no exposed-to-damage or outdoor runs)
8.5.2Piping in mechanical rooms, pipe galleries, and other locations exposed to mechanical damage, and all piping exposed to weather, shall receive a metal jacket (aluminum or stainless) per ASTM C921 over the insulation and its vapor retarder.
8.5.3On cold and storm service the metal jacket is the abuse layer over the vapor retarder, not the vapor retarder itself, and the vapor seal beneath it shall still be continuous.
8.5.4Outdoor metal-jacket seams shall be lapped to shed water downward and shall be sealed.
8.6 Vapor-Retarder Continuity
NOTE Vapor-retarder continuity is the single most important requirement for condensation-control insulation. (8.6.1)
○ Continuous, sealed vapor retarder over all pipe, fittings, valves, hangers, and terminations (standard)
8.6.2On all cold water and storm/roof-drainage insulation, the vapor retarder shall be continuous and unbroken over the entire system — straight runs, fittings, valves, hangers, and terminations.
NOTE A vapor retarder that is sealed on the straight pipe but left open at a fitting, sliced at a hanger, or stopped short at a valve is not a vapor retarder — humid air drives through the gap to the cold pipe, condenses inside the insulation, saturates it, and the system sweats and corrodes from within while appearing intact from outside. (8.6.3)
9 Insulation of Specific Systems
9.1 Domestic Hot Water and Recirculation
☐ All domestic hot water supply mains and branches
☐ Recirculation supply and return piping
☐ First length of outlet piping at non-recirculating water heaters (energy code)
☐ Heat-traced or impedance-heated piping
9.1.1Domestic hot water supply mains, branches, and the recirculation supply and return shall be insulated to the energy-code thickness for the operating temperature and pipe size.
9.1.2The energy code further requires that the heat-loss-prone connections at the water heater be insulated even on a non-recirculating system — the first length of outlet piping from the heater, the inlet piping between the tank and the heat trap, and any heat-traced or impedance-heated piping.
NOTE The recirculation return is insulated for the same reason as the supply — it is part of a continuously circulating hot loop, and any uninsulated segment dumps heat that the water heater must replace around the clock. (9.1.4)
9.2 Domestic Cold Water (Vapor Seal)
9.2.1Domestic cold water mains and branches shall be insulated with closed-cell elastomeric (or fiber with continuous sealed ASJ) sized for condensation control, with a continuous vapor retarder.
NOTE Cold water lines sweat whenever the pipe surface falls below the dew point of the surrounding air — common above ceilings, in unconditioned chases, and in humid rooms — and the drip damages finishes and corrodes the system. (9.2.2)
NOTE The vapor seal is the working part of the system: thickness only sets how cold the outer surface gets, but a breached vapor seal lets the pipe sweat regardless of thickness. (9.2.3)
9.3 Storm and Roof Drainage (Bodies and Horizontal)
☐ Roof-drain bodies and sumps
☐ Overflow (secondary) roof-drain bodies and sumps
☐ Horizontal storm and overflow drainage piping inside the building
☐ Vertical storm leaders in or exposed to humid spaces
9.3.1Roof-drain bodies, drain sumps, overflow (secondary) drain bodies, and the horizontal storm and overflow piping inside the building shall be insulated with closed-cell elastomeric (or fiber with sealed ASJ) at a minimum 1 in. thickness, with a continuous vapor retarder, in accordance with the International Plumbing Code.
9.3.2The roof-drain body and the underside of the roof-drain sump are the most-missed locations and shall be fully wrapped.
9.3.3Vertical storm leaders running cold through conditioned space shall be insulated where they pass through or are exposed to humid spaces.
NOTE During and after rain the piping fills with cold rainwater far below room dew point, and an uninsulated roof-drain body or horizontal leader sweats heavily onto the ceiling below. (9.3.5)
9.4 Omissions
☐ Factory-insulated water heaters and storage tanks
☐ Buried piping (excluded from this standard)
☐ Sanitary waste and vent piping (except ADA covers)
☐ Unions/flanges left accessible for service (vapor seal maintained at terminations)
9.4.1Insulation shall be omitted where it would defeat the purpose of the service or where the equipment is factory-insulated.
9.4.2Factory-insulated storage water heaters, indirect tanks, and pre-insulated assemblies shall not be field-wrapped.
9.4.3Buried piping is excluded from this standard.
9.4.4Unions, flanges, and valve bonnets that must be broken for service may be left accessible where shown, provided cold-service vapor sealing is maintained at the insulation termination.
9.4.5Sanitary waste and vent piping is not insulated except for the ADA protective covers below accessible fixtures and except where it carries condensing cold waste in a humid space.
10 ADA Fixture Protection
☐ Hot water supply stop and riser
☐ Cold water supply stop and riser
☐ P-trap and waste arm
○ Molded removable protective cover kit, smooth and non-abrasive (standard)
○ Field-formed insulated covering, smooth-finished and non-abrasive
All accessible lavatories and sinks per the accessibility schedule
As indicated on the drawings
10.1Water-supply and drain piping below an accessible lavatory or sink shall be insulated or otherwise covered so that a person using the fixture cannot contact a hot or sharp surface, in accordance with ICC A117.1 Section 606.5 and the ADA Standards.
10.2The hot supply, cold supply, and the trap and waste arm below an accessible lavatory or sink shall all be covered, and no sharp or abrasive surface shall remain.
10.3This protection is required regardless of whether the cold supply also needs condensation insulation.
NOTE A wheelchair user's knees and legs occupy the space directly beneath the lavatory, and that user cannot see the piping and might not feel a developing burn from a hot supply that can scald — which is the reason every exposed surface is covered and smoothed. (10.5)
NOTE The standard solution is a molded, removable protective cover kit on the hot supply, cold supply, and P-trap/waste arm, smooth and cleanable and removable for trap service. (10.6)
11 Installation
11.1 Surface Preparation
11.1.1Piping shall be insulated only after it has been pressure-tested, accepted, and is clean and dry.
11.1.2Insulation shall not be applied over wet, dirty, oily, or rusted pipe, and shall not be applied while the system is under test or while joints remain to be inspected.
NOTE Trapped moisture under insulation — especially under a cold-service vapor retarder — cannot escape and will corrode the pipe and ruin the insulation, which is why the pipe is wrapped only after it is clean, dry, and accepted. (11.1.3)
11.2 Joint and Lap Sealing
11.2.1Longitudinal laps and butt joints in jacketed fiber insulation shall be sealed with the self-sealing lap or with vapor-retarder butt-strip tape.
11.2.2On closed-cell elastomeric, all seams and butt joints shall be adhered continuously with the manufacturer's contact adhesive.
11.2.3Elastomeric insulation shall not be stretched at fittings or terminations.
NOTE Stretched elastomeric thins and pulls apart over time, opening the vapor seal. (11.2.4)
11.3 Vapor-Seal Continuity at Cold and Storm Service
11.3.1On cold water and storm/roof-drainage piping, the vapor retarder shall be carried continuously and sealed across every fitting, valve, hanger, and termination, and sealed to the bare pipe at the end of each insulated run so the cold pipe is fully enclosed.
11.3.2Where insulation terminates at an uninsulated component, the end shall be sealed off so humid air cannot track back along the pipe under the insulation.
11.4 Fitting Covers
11.4.1Fittings, valves, and flanges shall be insulated to the same thickness and with the same vapor retarder as the adjoining pipe.
11.4.2Exposed fittings in finished spaces shall receive preformed PVC fitting covers over inserts; concealed fittings may be covered with mitered insulation sections finished with a vapor-sealed jacket.
11.4.3Fittings on cold and storm service shall be vapor-sealed equal to the straight runs.
11.5 Inserts and Shields at Supports
○ Rigid load-bearing insert plus MSS SP-58 protection shield at every support, vapor retarder continuous (standard)
11.5.1At each pipe hanger, support, and guide, a rigid insulation insert (a load-bearing insert or calcium-silicate/wood saddle of the same thickness as the adjoining insulation) shall be provided so the support load does not crush the insulation.
11.5.2An MSS SP-58 insulation protection shield shall be installed at each support so the hanger bears on the shield rather than directly on the insulation.
11.5.3On cold and storm service the vapor retarder shall be continuous over the insert so the support is not a thermal short and condensation point.
NOTE Crushed insulation at a hanger is a permanent cold spot that sweats and a thermal-loss point on hot lines. (11.5.4)
11.6 Exposed-to-Damage Covering
11.6.1Insulated piping exposed to mechanical damage, in mechanical rooms, and outdoors shall be finished with a metal jacket installed over the completed insulation and vapor retarder, with seams lapped and sealed and — outdoors — arranged to shed water downward.
11.6.2Exposed elastomeric insulation that is not metal-jacketed shall receive the manufacturer's UV-resistant protective coating, because elastomeric degrades under sunlight.
12 Field Quality Control
12.1The Engineer may inspect the installed insulation before it is concealed.
12.2On cold water and storm/roof-drainage systems the inspection shall confirm vapor-retarder continuity at fittings, valves, hangers, and terminations — the locations where a sweating system originates.
12.3Insulation found wet, crushed at supports, stretched at fittings, or with an open vapor seal shall be removed and replaced; a breached cold-service vapor retarder cannot be reliably patched once the insulation has wetted.
13 Cleaning and Protection
13.1The Contractor shall keep insulation dry and clean during construction and shall protect installed insulation from damage by other trades, from water, and from weather until enclosed or jacketed.
13.2Insulation that becomes wet, soiled, or damaged before acceptance shall be replaced rather than dried in place, because wetted fiber loses thermal value and a wetted cold-service system has already begun to corrode.
14 Warranty
14.1The Contractor shall warrant the insulation installation against defects in materials and workmanship, including condensation (sweating) attributable to a breached or discontinuous vapor retarder on cold or storm service, for a period of not less than one year from substantial completion or for the period stated in the contract documents if longer.
14.2Sweating, dripping, corrosion, or finish damage traceable to a vapor-seal failure shall be corrected at the Contractor's expense.
15 Delivery, Storage, and Handling
15.1Insulation, jacketing, adhesives, and protective covers shall be delivered in the manufacturer's original packaging and stored indoors, off the floor, dry, and protected from weather and physical damage.
15.2Adhesives and sealants shall be stored within their rated temperature range and shall not be used past their shelf life.
15.3Insulation that has been wetted in storage shall not be installed.