Use and Installation Considerations... W-PP-5 Sound Transmission Class and Outdoor-Indoor Transmission Class... W-PP-7

PRODUCT PERFORMANCE

Introduction

... W-PP-2

General Application Guidelines

Use and Installation Considerations ... W-PP-5

Sound Transmission Class and Outdoor-Indoor Transmission Class ... W-PP-7

Product Performance

Elements of Product Performance ... W-PP-7

Product Performance Considerations ... W-PP-8

HurricaneShield

_{Impact-Resistant Glazing ... W-PP-9}

Elements of Glazing Performance ...W-PP-10

Glazing Performance

Glazing Performance for Between-Glass Window Fashions ...W-PP-11

High Altitude Glass ...W-PP-12

Argon Filling of Insulating Glass ...W-PP-13

Glazing Types ...W-PP-14

Energy Star Performance ...W-PP-15

Glass Design Pressure Performance Charts...W-PP-17

Industry Performance Standards—Air / Water / Design / Structural ...W-PP-19

Industry Certification and Test Standards

Industry Certification...W-PP-22

Compliance Information ...W-PP-23

Industry Testing Methods ...W-PP-24

PRODUCT PERFORMANCE

INTRODUCTION

In this manual we refer to two types of performance criteria for the selection of windows and doors: • Product performance

• Glazing performance

PRODUCT PERFORMANCE relates to the performance of the entire window or door assembly. Types of this product performance include:

• Performance grade • Performance class • Water penetration • Air infiltration • Thermal performance • Forced entry resistance

• Operating force (ease of operation) • Acoustic performance

GLAZING PERFORMANCEpertains to the light transmission and thermal transmission characteristics of the center glazing only. Glazing performance criteria include:

• U-Factor

• Visible light transmission • Solar heat gain coefficient

This section is an in-depth review of window and door performance criteria, limitations and standards.

Pella Corporation reserves the right to change details, specifications, sizes or any other information in this manual without notice.

The material in this manual is not intended to create any warranty of fitness for a particular purpose. Contact your local Pella representative for specific application recommendations.

Pella Corporation shall not be liable for errors contained herein or for incidental or consequential damages arising out of the furnishing or use of this material. See Pella Corporation’s product warranties for details on warranty coverage and limitations.

PRODUCT PERFORMANCE

GENERAL APPLICATION GUIDELINES

A. GENERAL PERFORMANCE CONSIDERATIONS

Pella® _{windows and doors, are designed and manufactured to established engineering and industry standards which maximize satisfactory performance}

within the limitations of the specifications, conditions and tests listed.

Pella products are subjected to testing during development and manufacturing. During manufacturing Pella® _{Proline, Designer Series}® _{and Architect Series}®

standard rectangular vent windows are tested for air infiltration. The stated performance levels for air infiltration represent Pella’s minimum acceptable performance level for tested units.

Published air infiltration performance of other products, and design pressure, structural test pressure and water penetration performance numbers for all products are representative of test performance of product samples. Testing is performed on randomly selected production samples, and conducted in Pella’s test lab as well as in independent testing laboratories. Products which are Hallmark Certified are noted on the product labels and in the Size and Performance Data charts in each product section of the Architectural Design Manual.

Many products will exceed published specifications; however, performance of installed products may be affected by factors beyond Pella’s control, such as shipping, handling, installation, construction practices, excessive environmental conditions, normal wear and tear and ongoing care and maintenance. Although efforts are made to minimize the effects of such factors, it is not possible to guarantee that any particular unit will meet or exceed published specifications.

B. SEVERE CONDITIONS

Projects that will be subject to severe climatic and atmospheric conditions may require that architects and specifiers address higher product performance requirements and more stringent maintenance schedules.

Severe conditions that should be taken into account when selecting, specifying and designing to accommodate windows and doors may include:

Sand and Salt

Exposure Any windows and doors installed near salt water — regardless of material or manufacturer — are subjected, with other building materials, to more severe weathering than in other typical locations. Along with other building products, they should receive the additional protection which is standard and customary practice in such coastal locations at time of installation, and periodic inspection and maintenance as necessary thereafter.

Chemical Exposure Severe chemical exposure in locations near chemical plants and some types of industrial complexes may adversely affect satisfactory performance of Pella products and substantially increase maintenance requirements. Judgements regarding the use of Pella products in such areas should be based upon local experience and customer awareness. Pella products should not be used in indoor swimming pool or hot tub enclosures or other high humidity and corrosive environments. Climatic Exposure Pella products are designed to perform in cold climate applications, however condensation or ice can form, mainly on

interior glass surfaces, at low temperatures. Condensation or icy conditions will primarily depend upon the amount of room side humidity to which the products are exposed and generally does not indicate a product defect.

Areas of Severe

Wind and Rain Areas subject to severe wind and rain may produce temporary conditions which exceed product performance standards. No claims are made beyond compliance with the product performance levels published for each product at the time of manufacture. Special design considerations may be required, such as subsills, built-up curbs, overhang protection, or unit set back from exterior face of wall.

PRODUCT PERFORMANCE

GENERAL APPLICATION GUIDELINES

SAFETY GLASS Glass installation in areas subject to human impact must be safety-glazed according to the Safety Standard for Architectural Glazing Materials (16 CFR 1201), issued by the U.S. Consumer Product Safety Commission (or as prescribed by local codes).

INTERIOR TRIM Pella wood and aluminum-clad wood products are intended to be installed with interior wood trim or other trim that will cover the frame edge.

E. SPECIAL REQUIREMENTS

C. PRODUCT PERFORMANCE LIMITATIONS

Design Criteria and Performance Requirements

Selection of design criteria and performance requirements is the responsibility of the building owner, architect, contractor, installer and/or consumer responsible for the building system in which Pella products are to be installed. The information herein is presented only as an aid to proper design considerations.

Product

Limitations Pella windows and doors must not be installed in conditions beyond published product limitations. Performance Class

and Grade Window and door design pressures published herein represent the windload pressure that a single unit is designed to withstand from a structural standpoint when glazed with the appropriate glass thickness. Air infiltration and water resistance performance are as indicated in this section or in each product section.

Glazing Pella products are standard-glazed to withstand a minimum of 20 psf (0.957 kPa) design pressure. Compliance with code requirements, windloading and/or design specifications may require special glazing. See glazing options in each product section.

Replacements Any glass or hardware replacements must be of equal specifications.

Modifications Product modifications that are not approved by Pella Corporation will void the Limited Warranty.

Mullion

Construction Mullions should be designed not to exceed L / 180 deflection under design wind load pressures. Some conditions may require less deflection. In addition, all installations, where there is a combination of vertical and horizontal mullions, will require reinforcement in either the horizontal or vertical direction. Some conditions may require additional horizontal mullion reinforcement to carry dead loads. Refer to the information in the Combination Recommendations section.

Vertical Stacking See the Combination Recommendations section for stacking considerations.

Expansion Joints For continuous horizontal rows of windows, a vertical expansion joint must be provided at least every 20' (6 096mm). Refer to the Combination Recommendation section.

Window Walls Pella units are not intended to provide the entire exterior surface or large expanses of a structure. Combination assemblies are limited by horizontal and vertical structural mullion design and other installation factors. Installation applications beyond the criteria established in the Combination Recommendation section must be designed and considered on a job-by-job basis and require factory shop drawings.

Buildings with Positive Interior Air Pressure

Because of special ventilating requirements or through natural stack action in some high-rise buildings, positive

interior air pressures may cause between-glass condensation in winter (for Designer Series® _{products with an interior}

hinged glass panel). Units Set at

an Angle No Pella window or door products are to be installed at any angle from vertical, unless specifically approved by Pella Corporation.

PRODUCT PERFORMANCE

USE AND INSTALLATION CONSIDERATIONS

REQUIREMENTS FOR COMPLYING WITH APPLICABLE BUILDING CODES

Regulations governing the design and use of glazed windows and doors vary widely. The building owner, architect,

contractor, installer and / or consumer are responsible for selecting products which conform to all applicable laws, regulations and building codes. Pella Corporation accepts no responsibility whatsoever for failure of building owner, architect, contractor, installer, and / or consumer to comply with all applicable laws, ordinances, safety and building codes. Pella Corporation shall not be responsible for windows, doors, and skylights not installed in compliance with applicable laws, codes, or other regulations.

GLAZING AND SAFETY GLASS

Pella products are standard-glazed to withstand a minimum of 20 psf design pressure. Specific code requirements, wind loading and / or design specifications may require special glazing.

Unless specifically noted or ordered, Pella products are not provided with safety glass. Glass installed in areas subject to human impact must be safety-glazed according to the Safety Standard for Architectural Glazing Materials (16CFR 1201), issued by the US. Consumer Product Safety Commission or as prescribed by other building codes.

REQUIREMENTS FOR PROPER INSTALLATION

All detail representations in this manual only pertain to the use of Pella products manufactured by Pella Corporation and are strictly limited to the published specifications and to the use of Pella products. Details shown herein illustrate typical general methods of installing Pella products manufactured by Pella Corporation and are to be used as guidelines only.

The performance of any building is dependent upon the design, installation, and workmanship of the entire building system. Pella Corporation strongly recommends consulting an experienced architect, contractor, or structural engineer prior to installation of Pella products.

The individual (building owner, architect, contractor, installer and / or consumer) responsible for the project must take into account local conditions, building codes, inherent component limitations, the effects of aging and weathering on building components, and other design issues relevant to each project.

Over time, all window and door systems may have some water infiltration; it is important that the wall system be designed and constructed to properly manage moisture. Pella Corporation is not responsible for claims or damages caused by unanticipated water infiltration; deficiencies in building design, construction and maintenance; failure to install Pella products in accordance with Pella approved methods; or the use of Pella products in systems which do not allow for proper management of moisture within the wall systems. The determination of the suitability of all building components, including the use of Pella products, as well as the design and installation of flashing and sealing systems are the responsibility of the building owner, architect, contractor, installer and / or consumer.

Consult with your local Pella representative on large and / or complex installations.

The following notes are important considerations regarding the use and installation of Pella products. Should you have any questions regarding the use and installation of any Pella products, contact your local Pella representative.

Pella Corporation reserves the right to change details, specifications, sizes or any other information in this manual without notice.

The material in this manual is not intended to create any warranty of fitness for a particular purpose. Contact your local Pella representative for specific application recommendations.

Pella Corporation shall not be liable for errors contained herein or for incidental or consequential damages arising out of the furnishing or use of this material. See Pella Corporation’s product warranties for details on warranty coverage and limitations.

PRODUCT PERFORMANCE

USE AND INSTALLATION CONSIDERATIONS

NOTE ON BARRIER WALL SYSTEMS

Exterior Insulation and Finish Systems (EIFS) and Other Non-Water Managed Wall Systems

Significant concerns have been raised regarding moisture problems including unacceptable water infiltration associated with the use of barrier wall systems which do not allow for the proper management of moisture within the wall system, such as EIFS (also known as synthetic stucco) and other stucco-like systems (sometimes referred to as “hard coat” or “one-coat” stucco) that use EIFS stucco-like coating systems, but omit the foam board. Specifically, a large number of EIFS installations, as well as other barrier type wall systems, have been found to have problems with excessive moisture in the wall cavity. The basic problem is that barrier systems do not account for the fact that moisture can—and will—penetrate the exterior wall surface. Once moisture penetrates a barrier wall, it remains trapped inside the wall cavity, where it may damage and even rot sheathing, framing and other moisture-sensitive building elements. In a large number of cases, the moisture problems have caused deterioration serious enough to require extensive repairs.

These problems often show up where there are penetrations in the building’s exterior, such as at windows and doors, however, moisture problems are not limited to these areas. It is generally agreed that the root cause of barrier-system moisture problems is the inability of such systems to allow moisture that should be expected in any building exterior system to weep or evaporate to the building exterior, and that the problems are not caused by the penetrating components themselves, whether they are windows, doors, decks, or other features. As a result of these problems, except in extremely arid climates, barrier-type systems are not recommended over wood frame construction or over any other substrate that could be adversely affected

by moisture.

Pella Corporation will not be responsible for claims or damages caused by anticipated or unanticipated water infiltration, deficiencies in building design, construction, and maintenance, failure to install Pella products in accordance with approved methods, or the use of Pella products in systems, such as barrier wall systems, which do not allow for the proper management of moisture within the wall system. Pella products should not be used in barrier Exterior Insulation and Finish Systems, (EIFS) (also known as synthetic stucco) or other non-water managed systems. Except in the states of California, New Mexico, Arizona, Nevada, Utah and Colorado, Pella makes no warranty of any kind on and assumes no responsibility for Pella windows and doors installed in barrier EIFS. In the states listed above, the installation of Pella Products in EIFS or similar systems must be in accordance with Pella’s instructions for that type of construction. Contact your local Pella representative for considerations with non-water managed wall systems and on large or complex installations. Moisture infiltration problems in any type of building can be reduced by proper flashing and / or sealing around all building penetrations, including windows and doors. Proper flashing under and around window and door openings can reduce moisture problems in barrier systems, however, the performance of any building system is also dependent upon the design and workmanship of the entire building system, which must take into account local conditions, climate, building codes, inherent component limitations, and the effects of aging and weathering on building components. Even when general installation recommendations are made by Pella Corporation, the determination of the suitability of all building components for each project, as well as the design and installation of flashing and sealing systems, are the responsibility of the architect, contractor, installer, and / or the manufacturer of the exterior finish system specified for the project.

PRODUCT PERFORMANCE

ELEMENTS OF PRODUCT PERFORMANCE

SOUND TRANSMISSION CLASS AND OUTDOOR-INDOOR TRANSMISSION CLASS

The ability of a window or door to reduce outside noise is an important consideration in product selection. The individual product sections display the actual performance ratings of Pella products including the Sound Transmission Class (STC) and Outdoor–Indoor Transmission Class (OITC). Both measure the amount of noise reduction that can be achieved with a given product.

A noise reduction of 10 decibels represents cutting the noise level in half, as interpreted by the human ear. So a rating of 25 means that the product reduces the outside noise by approximately 25 decibels, cutting the noise in half 2-1/2 times, or cutting it by over 80 percent.

STC ratings give an indication of noise reduction that can be achieved with typical indoor (high frequency) noises such as human speech, computers, FAX machines, etc. However, some specifiers and other manufacturers use STC ratings for exterior products because until recently, that is all that was available. OITC ratings are relatively new, but are a much better indicator of exterior noise reduction. That is because OITC ratings include lower frequency noises such as traffic, construction equipment, and lawn and garden equipment, therefore, OITC ratings are usually a few points lower than STC ratings, because the lower frequency sounds are more difficult to attenuate.

Pella will continue to show both OITC and STC ratings until the entire industry begins to use OITC. In the meantime, when comparing to other manufacturers, be sure to compare apples-to-apples (e.g. STC vs. STC, not STC vs. OITC).

PRODUCT PERFORMANCE TERMS

Performance

Grade Numerical designator based on the lesser of Design Pressure and Water Penetration performance. In order to qualify for a given Performance Grade, one or more representative samples of the product must pass all required performance tests for the products type, including operating force (if applicable), air infiltration, water penetration, design pressure, structural test pressure, forced entry resistance, and all product specific auxiliary tests. Performance

Class The industry standards define requirements for four classes of windows and doors. The classes are designated: (R), (LC), (CW) and (AW). This classification system provides for several levels of performance so that the purchaser or specifier may select the appropriate level of performance depending on: climatic conditions; height of installation; type of building; window size; durability; etc. Product selection should always be based on the performance requirements of the particular project. For example, many residential buildings are built in locations subject to severe weather that may require higher performance fenestration products than those that meet only the Class (R) requirements. On the other hand, many hospitals, schools, institutions, etc. may successfully use products meeting class (R), (LC), or (W) requirements. The older version of the industry standard defined five classes: (R), (LC), (C), (HC) and (AW). Compared to the new version, (C) and (HC) have been combined into a single new class, (CW). Design

Pressure (DP) A rating that identifies the load, induced by wind and/or static snow, that a product is rated to withstand in its end-use application. Note: Design pressure (DP) is not to be confused with Performance Grade (PG) or structural test pressure (STP). Loads induced by static snow are applicable only to TDDs, roof windows, and unit skylights.

Structural Test

Pressure (STP) A minimum of 1.5 times Performance Grade. In order for a product to be rated at a given design pressure, it must be able to withstand both positive and negative pressures of at least 1.5 times that of design pressure. For example, to receive a design pressure rating of 40 psf, the product must be able to withstand test loads of at least + / – 60 psf.

Water

Penetration The ability of a window or door to withstand water leakage under specified conditions. It is a minimum of 15% of the design pressure. For example, a product with a design pressure of 40 psf must pass a water test at a minimum of 6 psf. All products except side-hinged doors must never be tested at less than 2.86 psf.

Air

Infiltration The amount of air leaking through windows and doors. It is calculated in cfm per square foot of frame at 1.57 psf (25 mph) or 6.24 psf (50 mph) wind pressure for all products. Forced Entry

Resistance The ability of a window or door in the locked position to resist entry under conditions of stress and load. Products are given a forced entry resistance grade; the higher the grade, the greater the ability to resist entry under specified conditions.

ELEMENTS OF PRODUCT PERFORMANCE

Performance is an important criterion in the selection of windows and doors. In this manual, we refer to two types of performance: product performance and glazing performance. Product performance includes the following elements: performance grade (design pressure), performance class, water penetration, air infiltration and forced entry resistance. A definition of each of these terms is below. Glazing performance includes elements such as U-Factor, visible light transmission, and solar heat gain coefficient.

PRODUCT PERFORMANCE

PRODUCT PERFORMANCE CONSIDERATIONS

(1) ASCE 7—Minimum Design Loads for Buildings and other Structures. Published by the American Society of Civil Engineers, 345 East 47th Street, New York, NY 10017-2398. PRODUCT PERFORMANCE CONSIDERATIONS

Window or door specific performance requirements are determined from building code requirements, building location, topography, nearby structures, building design, placement of windows or doors, and other factors.

To evaluate whether Pella® products with non-impact or impact-resistant glazing meet specific project requirements, consider the first three criteria below, then determine joining mullion limitations for combination assemblies.

1. DESIGN WINDLOAD PRESSURE

Determine the design windload pressure for the application as specified by the architect, design professional and / or local building codes.

If no Design Pressure requirement was given, refer to ASCE 71 for an in-depth analysis of design pressure requirements for

windloads on buildings. Contact your local Pella representative on projects over three stories. Performance Grade of Windows or Doors:

Use the Design Windload Pressure to select the desired Product Performance Class and Grade per AAMA / WDMA / CSA 101 / I.S.2 / A440-08 -OR- AAMA/WDMA/CSA 101/I.S.2/A440-11.

Use the Design Data charts in each product section to ensure that the products and sizes you have selected meet or exceed the design windload pressure and performance class and grade requirements determined in this first consideration.

Glazing of Units

Once you have verified that the products / sizes selected meet or exceed the design pressure requirement, you must verify that the glass will also satisfy the design pressure requirement. If the glass will not be adequate, a stronger glass (for example, thicker and / or tempered) or impact-resistant glass can be requested in most cases. Go to the

PellaADM.com Product Performance section for detailed instructions on how to determine glass thickness and / or type to meet project design pressure requirements.

2. WIND-BORNE DEBRIS REGION

If the project is in a hurricane wind-borne debris region, protection from flying debris may be required (i.e., impact-resistant glass, storm shutters, plywood coverings, etc.). Check the local building codes for more information.

Pella products with HurricaneShield® _{impact-resistant glass are available for these conditions. Check within each Architect Series}®

product section for specific products offering the HurricaneShield impact-resistant glass option. Code approvals are listed on the Design Data pages within those same sections or at PellaADM.com.

3. CODE APPROVALS

Some construction products need to be approved by the state, county, or other authority having jurisdiction. Consult local building officials and / or building design professionals for details.

If the construction product does need to have approvals from local building codes, some examples are: FPAS — Florida Product Approval System

TDI — Texas Department of Insurance

NOA — Notice of Acceptance for Miami-Dade County, Florida

The approvals for select products are available from your local Pella sales representative.

DETERMINE JOINING MULLION LIMITATIONS (COMBINATION ASSEMBLIES ONLY)

When combining two or more units together to form a combination assembly, the mullion(s) must be analyzed for structural integrity. Use the project’s required design pressure to calculate when and what type of mullion reinforcement may be required for each combination. See the Combination Recommendations section.

When stacking units, weight limitations of the mullions must also be reviewed. See the Combination Recommendations section for more information.

PRODUCT PERFORMANCE

The impact-resistant glazing incorporated into HurricaneShield impact-resistant windows and doors is a high-performance, laminated glass with either SentryGlas® Plus (SGP) technology from DuPont® or PVB technology, also from DuPont. This laminated glass is designed to offer outstanding protection to keep the glazing intact after the glass is impacted by hurricane wind-driven flying debris, as tested per industry standards listed below.

SGP has a laminate interlayer made from an advanced material called ionoplast. SGP is much stronger than PVB. PVB is a DuPont Butacite® polyvinyl butyral laminate traditionally used in automotive windshields since 1938.

Pella’s HurricaneShield impact-resistant products are designed and tested to meet or exceed many but not all Gulf Coast and Atlantic Coast hurricane building code requirements. Pella has HurricaneShield impact-resistant windows and doors approved for use in Miami-Dade County, Florida as well as other areas along the Gulf and Atlantic Coasts.

HurricaneShield impact-resistant windows and doors are tested to numerous industry standards consistent with the intended application. These standards include: ASTM E 1886-02 ASTM E 1886-04 ASTM E 1886-05 ASTM E 1996-99 ASTM E 1996-01 ASTM E 1996-02 ASTM E 1996-03 ASTM E 1996-04 ASTM E1996-05 E1996-06

Miami-Dade County Florida TAS 201-94 Miami-Dade County Florida TAS 202-94 Miami-Dade County Florida TAS 203-94

ARCHITECT SERIES

HURRICANESHIELD

_{IMPACT-RESISTANT GLAZING}

WINDOWS AND DOORS

PRODUCT PERFORMANCE

Pella center-glass glazing performance for each of the above elements can be found on pages 14 through 17. Total-unit values can be found in the individual product sections.

ELEMENTS OF GLAZING PERFORMANCE

There are several elements of glazing performance, including U-Factor, Visible Light Transmission and Solar Heat Gain Coefficient. Definitions of the glazing performance elements discussed in this manual are below.

Glazing performance data is based on the WINDOW 5.2 and THERM 5.2 computer programs for analyzing energy performance. WINDOW and THERM software are the latest technology in simulating energy performance. When comparing performance with other manufacturers, it is important to verify how the values were determined.

GLAZING PERFORMANCE TERMS INSIDE GLASS SURFACE

TEMPERATURE The temperature on the inside surface of the glass at the center of the glass. It is based on an outside temperature of 0° F, inside temperature of 70° F, and an approximate 15 mph outside wind. Room side barriers to interior air flow (blinds, shades, drapes, screens) tend to lower inside glass surface temperature and humidity levels at which condensation occurs. Outside screens tend to raise inside glass surface temperature and level of humidity at which condensation occurs.

RELATIVE HEAT GAIN The actual amount of heat energy (BTU per hour-sq.ft.) that enters a room through a glazing system (Assumes typical daytime summer conditions of 89° F outside and 75° F inside). The lower the value, the better the unit keeps out heat energy.

SHADING COEFFICIENT The amount of solar heat that passes through a particular glazing system divided by the amount that passes through a single piece of 1/8" thick clear glass (Assumes 89° F outside and 75° F. inside). The lower the value, the better the glass keeps out solar heat.

SOLAR HEAT GAIN

COEFFICIENT The amount of solar heat that enters a room through a window or door (total unit) or glazing system (center-glass), divided by the amount that is actually contacting the exterior of the unit (Assumes 89° F outside and 75° F inside). The lower the value, the better the unit or glazing keeps out solar heat.

U-FACTOR The rate of heat transfer (BTU per hour-sq. ft.) through a window or door (total-unit) or glazing system (center-glass) (Assumes 0° F outside at night with an approximate 15 mph wind and 70° F inside). The lower the U-Factor, the better the insulating properties of the unit or glazing system.

UV TRANSMISSION The percentage of ultra violet rays that enter a room through the glazing system. It is a predictor of potential fading damage. Lower percentages indicate less fading potential (UV rays are those with a wavelength ranging from 0.30 to 0.38 microns).

LBL DAMAGE FUNCTION This function, developed by Lawrence Berkeley Laboratories, is another way of expressing UV Transmission. It is a better predictor of potential fading damage than UV Transmission. Lower values indicate less fading potential.

The LBL Damage Function is a weighted value, which takes into account that as the wavelength of the UV rays gets shorter, the fading damage potential increases. Therefore, two glazing systems with the same UV Transmission may have different LBL Damage Function values because one allows more shorter wavelength rays to pass through than the other.

VISIBLE LIGHT

TRANSMISSION The percentage of visible light that is transmitted through the window or door (total-unit) or glazing system (center-glass).

CONDENSATION

RESISTANCE A relative indicator of a fenestration product’s ability to resist the formation of condensation at a specific set of environmental conditions. The higher the Condensation Resistance value the greater the resistance to the formation of condensation. Actual condensation performance is a function of temperature, humidity and air movement. For more information see NFRC 501-2010, “User Guide to the Procedure for Determining Fenestration Product Condensation Resistance Rating Values”

PRODUCT PERFORMANCE

BETWEEN-GLASS WINDOW FASHIONS

(—) = Test data not available.

(1) U-Factor and SHGC for the Slimshade blinds and cellular fabric shades were reported by Architectural Testing Inc. (ATI), based on solar calorimeter tests. These results are not certified by NFRC.

Glazing System Total-Unit Winter U-Factor 1

Solar Heat Gain Coefficient 1 (SHGC) %Visible Light Transmittance %UV Light Transmittance TRIPLE-PANE SYSTEM

with Low-E IG with Argon and clear HGP 0.29 0.25 — —

with white raise & lower Slimshade blinds closed 0.28 0.13 — —

with golden raise & lower Slimshade blinds closed 0.26 0.16 — —

with alabaster cellular fabric shades closed 0.26 0.16 — —

with bamboo room darkening cellular fabric shades closed 0.26 0.10 — —

TRIPLE-PANE SYSTEM

with Low-E IG with Argon and Low-E HGP 0.27 0.24 — —

with white raise & lower Slimshade blinds closed 0.26 0.10 — —

with golden raise & lower Slimshade blinds closed 0.25 0.15 — —

with alabaster cellular fabric shades closed 0.24 0.14 — —

with bamboo room darkening cellular fabric shades closed 0.24 0.09 — —

Pella’s unique between-glass Slimshade® blinds and cellular fabric shades improve window performance. In addition to reducing fading damage to interior furnishings, between-glass accessories enhance thermal performance of the window or door. When the Slimshade blind or cellular fabric shade is in the closed position, the U-Factor and shading coefficient are significantly improved (reduced).

Although operation of Slimshade blinds and cellular fabric shades is simple, the analysis of the heat transfer through a window or door with a between-glass accessory is very complex. There is currently no industry-endorsed simulation tool that can be used to analyze the performance of Slimshade blinds or cellular fabric shades.

PRODUCT PERFORMANCE

Insulating Glass Shortest Glass Dimension (inches)

Altitude Limit for Standard Glass (feet above sea level)

5/8" or 3/4" ≤ 10 3,000 ≥10 and <15 5,000 ≥15 and <20 6,000 ≥20 and <25 7,000 ≥25 and <30 9,000 ≥30 10,000 1" Dual-pane or Triple-pane Glazing ≤ 15 3,000 ≥15 and <20 3,500 ≥20 and <30 4,500 ≥30 and <40 6,000 ≥40 and <50 8,000 ≥50 10,000

The average barometric pressure decreases as the elevation above sea level rises. When standard insulating glass manufactured at one altitude is shipped to a higher altitude, the decreased air pressure will cause the glass to deflect. The amount of glass deflection depends upon many factors, such as glass thickness, air space width, air space temperature, difference in altitude, and size of the piece of glass.

The best way to avoid insulating glass deflection in high altitudes is to specify Pella’s optional high altitude glass when needed. High altitude glass has a hidden capillary tube installed that serves as a “breather”, allowing the air between the two pieces of glass to equalize with outside air in high altitudes. High altitude insulating glass does not contain argon. Therefore, use the following guidelines to determine when high altitude glass is required.

Example: A residential home is 7,000 feet above sea level. The product to be used in the home is Architect Series® casement windows with 5/8" insulating glass. Frame sizes of the units are as follows:

17" x 17" and 29" x 47"

To determine if high altitude glass is needed, you must first convert the frame sizes to glass sizes. The glass-to-frame difference for casements is 5". So the glass size of the units listed above are:

12" x 12" and 24" x 42"

The shortest glass dimension of the first size is 12". According to the chart below for 5/8" glass, the altitude limit for this size is 5,000 feet. Since the home is at 7,000 feet, you must order high altitude glass for this size of unit. The second size has 24" as its shortest glass dimension. According to the chart, it has an altitude limit of 7,000 feet, which is the same altitude of the home, so you do not need high altitude glass for this size of unit.

HIGH ALTITUDE GLASS

PRODUCT PERFORMANCE

ARGON FILLING OF INSULATING GLASS

Certain Pella products with insulating glass use argon gas in the sealed air space to improve the insulating value of the glazing. The following paragraphs explain argon filling and how argon dissipates over time.

Using available argon filling equipment, it is not possible to achieve 100% argon filling. Insulating glass size, geometry, addition of internal grilles, etc. also influence the effectiveness of the argon filling process. For example, grilles inside the airspace contain air, and the air in the grille, if not completely removed, will reduce the overall initial argon percent fill level.

Since argon makes up approximately one percent of the normal atmosphere, the higher concentration of argon in the sealed unit is a driving force that causes the argon to slowly permeate through insulating glass edge seals to the ambient atmosphere. This driving force is present in all insulating glass with argon units regardless of which manufacturer produced them. Likewise, there is a similar driving force causing air (O 2 and N 2) to permeate into the insulating glass unit.

When argon permeates through the seal system of insulating glass units, the U-Factor will slightly increase (a reduction in thermal performance). The following are total unit U-Factor (as determined by the LBL WINDOW and THERM Computer Programs) for a typical casement unit at various argon levels: As can be seen by this data, the increase in U-Factor is minimal when argon levels are decreasing by one percent per year. For instance, for an initial argon level of 90%, the total unit U-Factor would be 0.37. If there were an argon-air exchange of one percent per year, in 20 years the argon level would be 70%, giving a total unit U-Factor of 0.38.

% Argon _{Total Unit U-Factor} Winter

100 0.36 90 0.37 80 0.37 70 0.38 60 0.38 50 0.39

Pella’s insulating glass with argon is available in most standard Pella products. See your local Pella representative for more information on this energy-efficient glazing option.

Pella Corporation warrants that its insulating glass with argon is NFRC compliant only at the time of manufacture. Pella Corporation makes no warranty regarding the rate of dissipation of argon or the amount of argon remaining in the window over time.

PRODUCT PERFORMANCE

GLAZING

GLAZING TYPE Dual-Pane

Insulating Glass Standard insulated glass consisting of two panes of glass creating an insulating sealed gas space. Triple-Pane

Insulating Glass Insulated glass consisting of three panes of glass that create two sealed insulated gas spaces. Designer Series®

Triple-Pane Glazing This product combines a Dual IG with an extra hinged glass panel to achieve thermal performance comparable to triple IG. The interior air space is not sealed to allow for Designer Series® accessories to be installed or removed.

INSULATED GLASS OPTIONS / LOW-E TYPES

Advanced Low-E Pella's standard Low-E coating that is commonly used in locations with hot and cold weather extremes. Features insulating glass with a Low-E coating to increase comfort year-round while blocking up to 86% of the sun's ultraviolet rays protecting your home from fade damage. Advanced Low-E has SHGC significantly lower than clear glass or NaturalSun Low-E. It is a good general purpose coating.

SunDefense™

Low-E Commonly used in locations needing superior solar protection, high levels of energy efficiency and year-round comfort. Features insulating glass with a special SunDefense™ Low-E coating that reflects more of the sun's heat to keep your home cooler in the summer. SunDefense™ is recommended in southern climates and in more northern regions where there is a significant amount of direct sunlight. This may be on un-shaded east or west exposures, especially if the windows are looking over a body of water and there is no shade or overhang. SunDefense™ Low-E blocks 96% of the sun's ultraviolet rays has a very low SHGC while maintaining a clear unfiltered view.

AdvancedComfort

Low-E Commonly used in locations in need of superior solar protection, and minimal winter heat loss. Includes all the advantages of Advanced Low-E plus further improvement in insulating performance (lower U-value) through an additional Low-E coating on the insulating glass. This low-E glass has the lowest U-value of all Pella’s dual glazed offering and is a good selection for customers wanting to meet the more stringent requirements of some local energy codes.

NaturalSun Low-E Commonly used in locations where maximum solar heat gain is desired. This would be intended for Canada and the far Northern regions of the US. It may also be used in regions further south if the home or landscape is designed to provide summer shading on the windows. This coating would be considered the best choice for “Passive Solar” homes. You may consider putting NaturalSun on the southern exposed windows while using Advanced Low-E on the other sides of the home. There is a slight visual difference with the different coatings, but if one is looking out at different directions in the room this should not be noticeable.

ADDITIONAL GLASS OPTIONS

Obscure Glass Commonly used in intimate spaces such as the bathroom and bedroom. Creates privacy while allowing natural light to enter. Available in a variety of textured surfaces, will let sunshine in to increase comfort. Thermal and SHGC of obscure IG is equal to clear glass when combined in IG with the same Low-E coatings. Tinted Glass

(Bronze, Gray and Green)

Commonly used in rooms that receive a lot of sun exposure. Like sunglasses, windows with tinted glass block the sun's rays, so they're useful in controlling glare; plus, they keep rooms that get direct sun cooler. The tint also helps block the view into a home.

Spandrel Glass Commonly used between sections of a building including the area between floors, columns, ceilings, and other small or large spaces. The main aesthetic purpose of spandrel glass is to create an overall uniform appearance.

Spandrel is created using fired-on frit methods. This process includes a ceramic frit that is fused to the glass using high-heat fusing methods. This technique creates a glass that will not fade over time. In addition, spandrel is up to five times stronger than annealed glass.

Laminated Glass Commonly used in locations in need of added security, ultraviolet (UV) protection and noise reduction. A polymer layer sandwiched between two layers of glass that cuts outside noise and harmful UV rays and offers added protection against intruders and forced entry. The interlayer holds the glass together if it's shattered. Impact Resistant

Glass 1

Available in Hurricaneshield® impact products, commonly used in locations that endure hurricane-force winds or where additional security or noise reduction is desired. An advanced polymer layer is sandwiched between two layers of glass, offering strong protection from flying debris - while increasing the safety, security, ultraviolet protection and energy efficiency of a home. Available as insulated glass or single pane.

GAS FILL / HIGH ALTITUDE

Argon Argon gas is commonly added to insulated glass assemblies to improve the insulating performance. High altitude For locations at high altitude the air filled insulated glass assembly is typically vented to prevent over

pressurization of the system. High altitude

PRODUCT PERFORMANCE

ENERGY STAR GLAZING

ENERGY STAR® PERFORMANCE

The U.S. Environmental Protection Agency and the Department of Energy's ENERGY STAR program uses "whole unit" (glass and frame) SHGC ratings and U-Factors to measure window and door energy efficiency. To ensure your product will deliver ENERGY STAR performance, refer to the chart and map below to help determine ENERGY STAR guidelines for your area of the country. Then compare these numbers with the "whole unit" SHGC ratings and U-Factors printed on the NFRC label found on every window and door. Pella has some of the lowest U-Factors in the industry and offers the energy-efficient options that will meet or exceed ENERGY STAR guidelines in all 50 states.

ENERGY STAR “WHOLE UNIT” RESIDENTIAL

PERFORMANCE GUIDELINES: 2015 (VERSION 6) CRITERIA

Windows U-FACTOR SHGC

Northern

0.30 or lower Any

0.31 0.35 or higher

0.32 0.40 or higher

North-Central 0.30 or lower 0.40 or lower

South-Central 0.30 or lower 0.25 or lower

Southern 0.40 or lower 0.25 or lower

Doors U-FACTOR SHGC

Solid panel (all regions) 0.17 or lower No rating

1/2-light or less (all regions) 0.25 or lower 0.25 or lower

More than 1/2-light Northern 0.30 or lower 0.40 or lower North-Central South-Central 0.30 or lower 0.25 or lower Southern

GLAZING OPTIONS Architect _Series® Designer _Series®

Pella® Proline 450 Series Fixed Frame Direct Set Pella® Impervia Pella® 350 Series Pella® 250 Series Encompass by Pella®

Clear Insulating Glass       

Advanced Low-E Insulating glass with argon 1        

SunDefense™ Low-E Insulating glass with argon 1        

AdvancedComfort Low-E     

NaturalSun Low-E Insulating glass        

Triple-Pane glazing with

between-the-glass options  Triple-Insulating Glass     Laminated glass    Impact-resistant glass    Tinted glass     Reflective glass  

Spandrel glass or panels  2 

(1) Optional high-altitude Advanced Low-E insulating glass does not contain argon glass in most products. (2) Not available on hinged or sliding patio doors.

PRODUCT PERFORMANCE

GLAZING

CENTER OF GLASS PERFORMANCE COMPARISON GUIDE

This chart is an overview of the typical glass types that are available from Pella. The types of glass and the glass thickness vary by brand. For complete

Glazing Performance data, including Obscure and High Altitude 2 glazing, please go to the appropriate product section of PellaADM.com.

Dual Insulating Glass

Exterior 1— —2 —4 3— Exterior Designer Series® Triple-Glazing System 1— —2 —4 3— —6 5—

Triple Insulating Glass

Exterior 1— —2 —4 3— 5— TYPE OF GLAZING Glass T hickness U-F actor Solar He at Gain C oef ficient (SHGC) Shading C oef ficient (SC) _Rela tive He at Gain % V isible Light Tr ansmission Inside Glass Surface T emp (˚F) % R ela tive Humidity @70°F when condensa tion appe ars on room side % UV Tr ansmission LBL Damage Function Low-E C oa ting on Surfaces #

Triple Pane Glazing, 5/8" Argon filled IG with HGP - Designer Series

Clear (air filled) 3mm 1 0.32 0.70 0.80 166 75 52 53 48 0.52

SunDefense™ 3mm 1 0.19 0.25 0.29 61 59 59 68 4 0.19 2 Advanced 3mm 1 0.20 0.34 0.39 81 64 59 68 12 0.28 2 AdvancedComfort 3mm 1 0.16 0.33 0.38 78 63 61 73 12 0.27 2, 4 NaturalSun 3mm 1 0.20 0.62 0.72 147 73 58 66 24 0.37 3 Bronze Advanced 5mm/3mm 0.21 0.29 0.34 71 41 58 66 6 0.17 3 Gray Advanced 5mm/3mm 0.21 0.27 0.31 65 36 58 66 6 0.17 3 Green Advanced 5mm/3mm 0.21 0.29 0.33 69 50 58 66 5 0.18 3

Dual Pane Insulating Glass, Argon filled 11/16" overall thickness

Clear (air filled) 3mm 2 0.48 0.78 0.89 186 82 44 39 58 0.61

SunDefense™ 3mm 2 0.24 0.27 0.31 66 65 56 61 5 0.21 2 Advanced 3mm 2 0.25 0.37 0.42 88 70 56 61 14 0.31 2 AdvancedComfort 3mm 2 0.20 0.36 0.42 86 69 47 44 14 0.31 2, 4 NaturalSun 3mm 2 0.26 0.68 0.79 161 79 55 59 29 0.42 3 or 2* Bronze Advanced 5mm/3mm 0.25 0.33 0.38 79 45 56 61 7 0.19 3 Gray Advanced 5mm/3mm 0.25 0.30 0.34 73 39 56 61 7 0.18 3 Green Advanced 5mm/3mm 0.25 0.32 0.37 77 55 56 61 5 0.19 3 Advanced Laminated 3mm/6mm 0.31 0.37 0.42 89 68 53 55 0 0.20 2 or 3** SunDefense™ Laminated 3mm/6mm 0.31 0.28 0.32 68 63 53 55 0 0.16 2 or 3**

Dual Pane Insulating Glass, Argon filled 1" overall thickness

Clear (air filled) 6mm 0.49 0.75 0.87 181 82 46 41 54 0.58

SunDefense™ 6mm 0.25 0.27 0.31 65 63 56 61 4 0.20 2 Advanced 6mm 0.25 0.35 0.41 84 68 56 61 13 0.30 2 AdvancedComfort 6mm 0.20 0.35 0.40 82 66 47 44 12 0.29 2,4 NaturalSun 6mm 0.26 0.64 0.74 150 77 55 59 24 0.38 3 or 2* Bronze Advanced 6mm 0.25 0.30 0.34 71 40 56 61 6 0.16 3 Gray Advanced 6mm 0.25 0.27 0.31 64 34 56 61 6 0.16 3 Green Advanced 6mm 0.25 0.29 0.33 69 51 56 61 4 0.17 3 Advanced Laminated 5mm/10mm 0.25 0.36 0.41 85 67 56 61 0 0.17 2 or 3** SunDefense™ Laminated 5mm/10mm 0.24 0.27 0.31 66 62 56 61 0 0.14 2 or 3** 1" Triple Insulating Glass—Vinyl 250 Series

Advanced Low-E 3 mm 0.16 0.31 0.36 74 55 60 71 4 0.19 2, 5

NaturalSun Low-E 3 mm 0.17 0.56 0.64 131 70 60 71 13 0.29 2, 5

Advanced Low-E 4 mm 0.19 0.31 0.35 73 53 59 68 4 0.19 2, 5

NaturalSun Low-E 4 mm 0.20 0.54 0.62 127 69 59 68 12 0.28 2, 5

1-1/4" Triple Insulating Glass—Vinyl 350 Series

Advanced Low-E 3 mm 3 0.13 0.31 0.36 73 55 62 76 4 0.19 2, 5

PRODUCT PERFORMANCE

Use the glass charts on the following pages to verify that the glass thickness of a unit will meet the specified design pressure. These charts show required nominal thickness of rectangular plate, float and sheet glass, based on minimum thickness allowed in ASTM E 1300-04 (Contact your local Pella representative for performance of glass types and thicknesses not shown).

The charts are set up for single-pane annealed glass, so there is a multiplying factor for heat-strengthened and tempered glass, as well as sealed insulating glass. These factors are listed below:

2.5 mm (3/32 in.) Glass Nonfactored Load (kPa) Four Sides Simply Supported Pb = 0.008

1 kPa = 20.9 psf 3-Second Duration

Longest Side (inches)

Example intersection point

Shor

test Side (inches

)

Shor

test Side (mm)

2.5 mm (3/32 inches)

Example interpolate line

Longest Side (mm)

Heat-strengthened single-pane glass 2.0 Tempered single-pane glass 4.0 Annealed insulating glass 1 1.8

Heat-strengthened insulating glass 1 3.6

Tempered insulating glass 1 7.2 (1) Interior hinged glass panels must be glazed to the appropriate single-pane requirement. Factors only apply if both panes of the insulating glass are equal in thickness and tempered.

Example: Determine if 2.5mm annealed insulating glass will work for a 41" x 53" (frame size) clad casement with an established design pressure of 28 psf (1.34 kPa).

1. Determine the glass area of the unit. If the frame size is 41" x 53", and the frame to glass difference for clad casements is 5", then the glass area of the unit is 36" x 48". (Frame to glass formulas can be found in each product section in Volume 2.) 2. Use the 2.5mm chart—intersect the short glass side value (36")

with the long glass side value (48"). Draw a diagonal line from 0.0 through that intersection point. Use the diagonal line to interpolate between the load contours. In this case, the interpolated non-factored load is 1.13 kPa.

3. Convert results to lbs / ft 2 _{(1kPa = 20.9 psf)—}

(1.13 kPa x 20.9 psf) / 1 kPa = 23.6 psf.

4. Since this example uses annealed insulating glass, multiply 23.6 psf by the factor listed above for annealed insulating glass— 23.6 psf x 1.8 = 42.5 psf (2.03 kPa).

The calculated number of 42.5 psf is greater than the design pressure requirement of 28 psf. So this unit passes the ASTM standard for glazing design.

GLASS DESIGN PRESSURE PERFORMANCE CHARTS

ALL PRODUCTS

PRODUCT PERFORMANCE

GLASS DESIGN PRESSURE PERFORMANCE CHARTS

ALL PRODUCTS

5.0 mm (3/16 in.) Glass Nonfactored Load (kPa) Four Sides Simply Supported Pb = 0.008

1 kPa = 20.9 psf 3-Second Duration

Longest Side (inches)

Longest Side (mm)

Shor

test Side (inches

)

Shor

test Side (mm)

5.0 mm (3/16 inches)

6.0 mm (1/4 in.) Glass Nonfactored Load (kPa) Four Sides Simply Supported Pb = 0.008

1 kPa = 20.9 psf 3-Second Duration

Longest Side (inches)

Shor

test Side (inches

)

Shor

test Side (mm)

6.0 mm (1/4 inches)

Nonfactored Load (kPa) Four Sides Simply Supported Pb = 0.008

1 kPa = 20.9 psf 3-Second Duration

Longest Side (inches)

4.0 mm (5/32 inches)

Longest Side (mm)

Shor

test Side (inches

)

Shor

test Side (mm)

3.0 mm (1/8 in.) Glass Nonfactored Load (kPa) Four Sides Simply Supported Pb = 0.008

1 kPa = 20.9 psf 3-Second Duration

Longest Side (inches)

3.0 mm (1/8 inches)

Longest Side (mm)

Shor

test Side (mm)

Shor

test Side (inches

PRODUCT PERFORMANCE

CURRENT STANDARDS

Standard Class / Rating / Grade

Performance Requirement Maximum Air

Infiltration1

Minimum Water

Test Pressure (psf) Minimum Design Pressure (psf) AAMA / WDMA / CSA 101 / I.S.2 /

A440-08 _LCR 0.3 cfm / sq.ft._{0.3 cfm / sq.ft.} 2.93_3.76 15.1_25.1

CW 0.3 cfm / sq.ft. 4.60 30.1

AW 0.3 cfm / sq.ft. 8.15 40.1

(1) cfm per linear foot of sash crack.

Voluntary industry standards for window, door and skylight performance are established by three national trade associations: AAMA (American Architectural Manufacturers Association), WDMA (Window and Door Manufacturers Association) and CSA (Canadian Standards Association).

These standards are continually being updated and changed. While Pella Corporation strives to use the most current standards available, some

manufacturers continue to publish information using previous standards (such as Grade 20, Grade 40, etc.). To help in comparisons with other manufacturers, the chart below includes the latest standards, as well as some of the previous ones. See the following page for a more detailed summary of the current 101/ I.S.2 standard.

INDUSTRY PERFORMANCE STANDARDS

AIR / WATER / DESIGN / STRUCTURAL

PREVIOUS STANDARDS

Standard Class / Rating / Grade

Performance Requirement Maximum Air

Infiltration₁ Test Pressure (psf)Minimum Water Minimum Design Pressure (psf) AAMA / WDMA / CSA 101 / I.S.2 /

A440-05 _LCR 0.3 cfm / sq.ft._{0.3 cfm / sq.ft.} 2.93_3.76 15.1_25.1

C 0.3 cfm / sq.ft. 4.60 30.1

HC 0.3 cfm / sq.ft. 6.06 40.1

AW 0.3 cfm / sq.ft. 8.15 40.1

101 / I.S.2 / NAFS-02 WINDOWS, SKYLIGHTS AND GLASS DOORS AAMA / WDMA / CSA 101 / I.S.2 /

A440-05 Residential (R) 0.3 cfm / sq.ft. 2.93 15.1 Light Commercial (LC) 0.3 cfm / sq.ft. 3.76 25.1 Commercial (C) 0.3 cfm / sq.ft. 4.60 30.1 Heavy Commercial (HC) 0.3 cfm / sq.ft. 6.06 40.1 Architectural (AW) 0.3 cfm / sq.ft. 8.15 40.1

101 / I.S. 2-97 WINDOWS AND

GLASS DOORS _{Light Commercial (LC)}Residential (R) 0.3 cfm / sq.ft._{0.3 cfm / sq.ft.} 2.86_3.75 15.0_25.0

Commercial (C) 0.3 cfm / sq.ft. 4.50 30.0

Heavy Commercial (HC) 0.3 cfm / sq.ft. 6.00 40.0

PRODUCT PERFORMANCE Pr oduct T ype Performance Class Minimum Performance Gr

ade Minimum Frame Gateway Test Size Minimum Design Pr essur e (lb/f t 2) Minimum Structur al Pr essur e (lb/f t 2) Minimum W ater Pr essur e (lb/f t 2) Air Leakage Resistance Maximum Operating Force (lb) Max L ock For ce (lb) Max Deflection a t Design P ressur e Max P

ermanent Set After S

TP

Minimum AS

TM

Security Gr

ade

Width _(inches) Height (inches) Pressur

e (lb/f t 2) Allowable (cfm/f t 2) Star t Ru n AP A wning R 15 48 16 15 22.5 2.86 + 1.57 0.3 15 6 22 — 0.4% L 10 LC 25 48 29 25 37.5 3.75 + 1.57 0.3 15 6 22 — 0.4% L 10 CW 30 48 29 30 45.0 4.50 + 1.57 0.3 15 6 22 L / 175 0.3% L 10 AW 40 60 36 40 60.0 8.00 + 6.24 0.1 20 10 — L / 175 0.2% L 10 C C asement R 15 17 48 15 22.5 2.86 + 1.57 0.3 15 6 22 — 0.4% L 10 LC 25 24 48 25 37.5 3.75 + 1.57 0.3 15 6 22 — 0.4% L 10 CW 30 24 48 30 45.0 4.50 + 1.57 0.3 15 6 22 L / 175 0.3% L 10 AW 40 36 60 40 60.0 8.00 + 6.24 0.1 20 10 — L / 175 0.2% L 10 FW _Fixed Window R 15 48 48 15 22.5 2.86 + 1.57 0.3 — — — — 0.4% L 10 LC 25 54 54 25 37.5 3.75 + 1.57 0.3 — — — — 0.4% L 10 CW 30 60 60 30 45.0 4.50 + 1.57 0.3 — — — L / 175 0.3% L 10 AW 40 60 96 40 60.0 8.00 + 6.24 0.1 — — — L / 175 0.2% L 10 H Hung R 15 44 60 15 22.5 2.86 + 1.57 0.3 45 30 22 — 0.4% L 10 LC 25 44 77 25 37.5 3.75 + 1.57 0.3 51 34 22 — 0.4% L 10 CW 30 54 90 30 45.0 4.50 + 1.57 0.3 51 45 22 L / 175 0.3% L 10 AW 40 60 96 40 60.0 8.00 + 6.24 0.3 51 45 — L / 175 0.2% L 10

SHD _{Side Hinged Doors}

R 15 32 (panel) 78 15 22.5 2.86 + 1.57 0.3 — — 22 — 0.4% L 10 LC 25 34 (panel) 80 25 37.5 3.75 + 1.57 0.3 — — 22 — 0.4% L 10 CW 30 36 (panel) 82 30 45.0 4.50 + 1.57 0.3 — — 22 L / 175 0.3% L 10 SD Sliding Doors R 15 34 (panel) 78 15 22.5 2.86 + 1.57 0.3 30 20 22 — 0.4% L 10 LC 25 42 (panel) 80 25 37.5 3.75 + 1.57 0.3 30 20 22 — 0.4% L 10 CW 30 46 (panel) 82 30 45.0 4.50 + 1.57 0.3 30 20 22 L / 175 0.3% L 10 AW 40 58 (panel) 94 40 60.0 8.00 + 6.24 0.3 40 25 — L / 175 0.2% L 10

Under AAMA / WDMA / CSA 101 / I.S.2 / A440-08, window and door performance is classified using three primary designators: Product Type, Performance Class and Performance Grade. In order for a product to meet a given performance class and/or grade, a number of requirements must be met. The following tables are intended to provide an overview of those requirements.

For example, to achieve a C-R50 (Performance Class R, Performance Grade 50) rating, a casement with a minimum frame size of 24" x 60" must surpass all of the air, water, structural and hardware sub-requirements pertaining to that

class and grade.

To assist in selecting Pella products that meet project requirements, each product section in Volume 2 contains a product selection guide and design data tables which gives an overview of the class and grade ratings achieved as well as the rating achieved for each standard size.

Refer to AAMA / WDMA / CSA 101 / I.S.2 / A440-08, for a complete understanding of all performance requirements.

(—) = Not Applicable STP = Structural Test Pressure

INDUSTRY PERFORMANCE STANDARDS

AIR / WATER / DESIGN / STRUCTURAL

PRODUCT PERFORMANCE

INDUSTRY PERFORMANCE STANDARDS

AIR / WATER / DESIGN / STRUCTURAL

A higher than minimum performance grade may be specified using the Optional Performance Grade chart below.

OPTIONAL PERFORMANCE GRADES REQUIREMENTS Optional Performance Grade Product Performance Class Design

Pressure (psf) Structural Test Pressure (psf)

Water Resistance Test Pressure R, LC, C, HC AW (psf) (psf) 20 R 20 30.0 3.00 — 25 R 25 37.5 3.75 — 30 R, LC 30 45.0 4.50 — 35 R, LC, CW 35 52.5 5.25 — 40 R, LC, CW 40 60.0 6.00 — 45 R, LC, CW, AW 45 67.5 6.75 9.00 50 R, LC, CW, AW 50 75.0 7.50 10.00 55 R, LC, CW, AW 55 82.5 8.25 11.00 60 R, LC, CW, AW 60 90.0 9.00 12.00 65 R, LC, CW, AW 65 97.5 9.75 12.00 70 R, LC, CW, AW 70 105.0 10.50 12.00 75 R, LC, CW, AW 75 112.5 11.25 12.00 80 LC, CW, AW 80 120.0 12.00 12.00 85 LC, CW, AW 85 127.5 12.00 12.00 90 CW, AW 90 135.0 12.00 12.00 95 CW, AW 95 142.5 12.00 12.00 100 CW, AW 100 150.0 12.00 12.00 105 AW 105 157.5 12.00 12.00 Product Type

I.S. 2-97 101/ I.S.2 / A440-05 and 08Product Type Performance Class Sample Product Designation AP = Awning Windows

C = Casement Windows F = Fixed Windows H = Hung Windows (single, double)

HGD = Hinged Glass Doors SGD = Sliding Glass Doors

AP = Awning Windows C = Casement Windows FW = Fixed Windows H = Hung Windows (single, double) SHD = Side-Hinged Doors SD = Sliding Doors R LC CW AW C-R 50 50 = Performance Grade (Design Pressure, psf) R = Performance Class C = Product Type (—) = Not Applicable

PRODUCT PERFORMANCE

HALLMARK CERTIFICATION

The WDMA Hallmark Certification Program provides specifiers a method of identifying windows, doors and skylights that are manufactured in accordance with WDMA standards. The WDMA Hallmark is considered a mark of excellence among architects, contractors and other specifiers and is accepted industry-wide. WDMA Standards are referenced by HUD / FHA in their Minimum Property Standards and by many other government agencies in their construction specifications.

Hallmark Certification verifies conformance with AAMA / NWWDMA 101/ I.S.2-97, and AAMA / WDMA / CSA 101 / I.S.2 / A440-05, and is determined by in-plant inspection of the manufacturing facilities and by sampling and testing

of product.

Many Pella products are Hallmark Certified and are clearly labeled with performance class and grade information. Refer to pages C-20 through C-22 for more information about performance class and grade. General performance class and grade information is found in Volume 2 under each product section titled Product Selection Guide—Size and Performance Data. Individual unit class and grade ratings are found on the Design Data pages in each section. For additional information about the Window and Door Manufacturers Association, contact:

WINDOW AND DOOR MANUFACTURERS ASSOCIATION

401 North Michigan Avenue, Suite 2200 Chicago, IL 60611

Telephone: 312-321-6802 Fax: 312-673-6922

Web site: www.wdma.com

NFRC RATING

The National Fenestration Rating Council (NFRC) develops and administers energy-related rating and certification programs and their goal is to serve the public by providing fair, accurate, and credible information on fenestration performance. Pella products labeled with the NFRC Energy Performance label are rated in accordance with NFRC standards. This allows for direct comparisons with other NFRC labeled products. NFRC ratings are based on a combination of computer simulations and physical testing of product samples. For details go to www.NFRC.org.

NFRC

6305 Ivy Lane, Suite 140 Greenbelt, MD 20770

Telephone: 301-589-1776

Fax: 301-588-3884

Web site: www.nfrc.org

MIAMI-DADE COUNTY, FLORIDA PRODUCT APPROVAL

Most Pella HurricaneShield® _{impact-resistant single-laminated products have been tested in accordance with stringent Miami-Dade County, Florida}

test protocols. Most Pella HurricaneShield impact-resistant products have passed the Large Missile D impact test, withstanding the force of a 9 lb. 2 x 4 piece of lumber hurled at 34 mph (50 ft / sec.).

Insulating glass units and double-hung units are not approved in Miami-Dade County.

For information regarding HurricaneShield impact-resistant products, refer to applicable sections in Volume 2. For more information about Miami-Dade County, Florida, product approval contact:

BUILDING CODE COMPLIANCE OFFICE

140 W. Flagler Street, Suite 1603 Miami, Florida 33130-1563

Telephone: 305-375-2901

Fax: 305-375-2908

Web site: www.buildingcodeonline.com

PRODUCT PERFORMANCE

PELLA WINDOW AND DOOR COMPLIANCE INFORMATION

Pella windows and doors meet or exceed the following industry and federal performance standards:

WDMA—WINDOW AND DOOR MANUFACTURERS ASSOCIATION

ƒ101/I.S.2-97 Windows and Glass Doors

ƒ101/I.S.2/NAFS-02 Windows, Skylights and Glass Doors

ƒ1600/I.S.7 Skylights

ƒI.S. 4 Water Repellent Preservative

ƒI.S. 6 Wood Stile and Rail Doors

ƒ101/I.S.2/A440-05

AAMA—AMERICAN ARCHITECTURAL MANUFACTURERS ASSOCIATION

ƒ101/I.S.2-97 Windows and Glass Doors

ƒ101/I.S.2/NAFS-02 Windows, Skylights and Glass Doors

ƒ1600/I.S.7 Skylights

ƒ101/I.S.2/A440-05

ƒAAMA 1600

FHA—FEDERAL HOUSING ADMINISTRATION FMHA—FARMERS HOME ADMINISTRATION

ƒFmHA endorses WDMA industry standards for windows and doors. Pella products meeting WDMA requirements will meet the requirements of FmHA.

CSA—CANADIAN STANDARDS ASSOCIATION

ƒMany Pella products meet Canadian standard CSA-A440. Contact your Pella representative for specific product performance ratings.

MDC—MIAMI-DADE COUNTY, FLORIDA

ƒProtocol TAS 201 – Impact Test Procedures1

ƒProtocol TAS 202 – Criteria for Testing Impact and Non-Impact Resistant Building Envelope Components Using Uniform Static Air Pressure

ƒProtocol TAS 203 – Criteria for Testing Products Subject to Cyclic Wind Pressure Loading

SBCCI1—SOUTHERN BUILDING CODE CONGRESS INTERNATIONAL, INC.

PRODUCT PERFORMANCE

ASTM—AMERICAN SOCIETY FOR TESTING AND MATERIALS

ASTM B 117 Method of Salt Spray (Fog) Testing

ASTM C 236 Test Method for Steady-State Thermal Performance of Building Assemblies by Means of a Guarded Hot Box

ASTM C 1036 Standard Specification for Flat Glass

ASTM C 1048 Specification for Heat-Treated Flat Glass—Kind HS, Kind FT Coated and Uncoated Glass

ASTM C 1199 Standard Test Method for Measuring the Steady-State Thermal Transmittance of Fenestration Systems Using Hot Box _Methods

ASTM D 648 Test Method for Deflection Temperature of Plastics Under Flexural Load

ASTM D 5572 Specification for Adhesives Used for Finger-Joints in Non-structural Lumber Products

ASTM D 5751 Standard Specification for Adhesives Used for Laminate Joints in Non-structural Lumber Products

ASTM E 90 Test Method for Laboratory Measurement of Airborne Sound Transmission Loss of Building Partitions

ASTM E 283 Standard Test Method for Rate of Air Leakage Through Exterior Windows, Curtain Walls, and Doors Under Specified _{Pressure Differences Across the Specimen}

ASTM E 330 Standard Test Method for Structural Performance of Exterior Windows, Curtain Walls, and Doors by Uniform Static Air _{Pressure Differences}

ASTM E 331 Standard Test Method for Water Penetration of Exterior Windows, Curtain Walls, and Doors by Uniform Static Air Pressure _Differences

ASTM E 405 Standard Test Methods for Wear Testing Rotary Operators for Windows

ASTM E 547 Standard Test Method for Water Penetration of Exterior Windows, Curtain Walls, and Doors by Cyclic Static Air Pressure

Differential

ASTM E 2188 Standard Test Method for Insulating Glass Performance

ASTM E 2189 Standard Test Method for Testing Resistance to Fogging in Insulating Glass Units

ASTM E 2190 Standard Specification for Insulating Glass Unit Performance and Evaluation

ASTM E 783 Method for Field Measurement of Air Leakage Through Installed Exterior Windows and Doors

ASTM E 1105 Standard Test Method for Field Determination of Water Penetration of Installed Exterior Windows, Curtain Walls, and Doors _{by uniform or Cyclic Static Air Pressure Differences}

ASTM E 1300 Standard Practice for Determining Minimum Thickness of Annealed Glass Required to Resist a Specified Load

ASTM E 1423 Standard Practice for Determining the Steady State Thermal Transmittance of Fenestration Systems

ASTM E 1425 Standard Practice for Determining the Acoustical Performance of Exterior Windows and Doors

ASTM E 1886 Standard Test Method for Performance of Exterior Windows, Curtain Walls, Doors and Storm Shutters Impacted by _{Missile(s) and Exposed to Cyclic Pressure Differentials}

ASTM E 1996 Standard Specifications for Performance of Exterior Windows, Glazed Curtain Walls, Doors and Storm Shutters Impacted by _{Wind Borne Debris in Hurricanes}

ASTM F 476 Test Methods for Security of Swinging Door Assemblies

ASTM F 588 Standard Test Methods for Resistance of Window Assemblies to Forced-Entry Excluding Glazing

ASTM F 842 Standard Test Methods for Measurement of Forced-Entry Resistance of Horizontal Sliding Door Assemblies

ASTM G 53 Recommended Practice for Operating Light and Water Exposure Apparatus (Fluorescent UV-condensation type) for _{Exposure of Non-Metallic Materials}

ASTM G 85 Practice for Modified Salt Spray (Fog) Testing

Federal Specification

DD-G Glazing Thickness

Federal Specifications

FS L S 125B Screening, Insect Non-Metallic

Pella products have been tested under the applicable procedures listed below:

PRODUCT PERFORMANCE

INDUSTRY TESTING METHODS

NFRC—NATIONAL FENESTRATION RATING COUNCIL, INC.

NFRC 100 Procedure for Determining Fenestration Product U-Factors.

NFRC 200 Procedures for Determining Fenestration Product Solar Heat Gain Coefficient and Visible Transmittance at Normal Incidence

AAMA—AMERICAN ARCHITECTURAL MANUFACTURERS ASSOCIATION

AAMA 2603 Pigmented Organic Coatings on Aluminum Extrusions and Panels

AAMA 2604 High Performance Organic Coatings on Aluminum Extrusions and Panels

AAMA 2605 Superior Performing Organic Coatings on Aluminum Extrusions and Panels

AAMA 906.3 Voluntary Specification for Sliding Glass Door Roller Assemblies

AAMA 1304 Voluntary Specification for Forced Entry Resistance of Side-Hinged Door Systems

AAMA 920 Specification for Operating Cycle Performance of Side-Hinged Exterior Door Systems