ACRYLITE® Premium Physical Properties
ACRYLITE® premium is the highest quality continuously manufactured sheet on the market today. Using a proprietary, innovative process, our premium sheet products are economical, provide tight thickness tolerance, high optical characteristics, and low stress levels. Our premium sheet is readily available in a variety of standard sizes, thicknesses, and colors. Our colorless premium sheet carries an exclusive 30-year limited warranty on light transmission – your assurance of a quality product.
This is a lightweight, rigid, and weather-resistant thermoplastic that is dimensionally stable, resistant to breakage and can be easily fabricated and cemented.
Because of its virtually distortion-free clarity, it is well suited for use in a variety of applications:
- Window glazing
- Retail displays
- Optical displays
- Picture framing
ACRYLITE® premium sheet is available in thicknesses from .060” (1.5 mm) to .944” (24 mm) and actual sheet sizes from 48” x 96” to 100” x 150” . Custom sizes are also available. All sheets are protected with polyethylene film or paper masking.
It is more impact resistant than glass. If subjected to impact beyond the limit of its resistance, it does not shatter into small slivers, but breaks into comparatively large pieces. ACRYLITE® sheet meets the requirements of ANSI Z97.1 for use as a Safety Glazing Material in Buildings (for thicknesses .080” to .500” [2.0 mm - 12.0 mm]).
This sheet will withstand exposure to blazing sun, extreme cold, sudden temperature changes, salt water spray, etc. It will not deteriorate after many years of service because of the inherent stability of acrylic resins. ACRYLITE® has been widely accepted for use in school buildings, industrial plants, and outdoor signs.
Although ACRYLITE® will expand and contract due to changes in temperature and humidity; it will not shrink with age. Some shrinkage occurs when it is heated to forming temperature, but post-forming stability is excellent.
Its only half the weight of glass and 43% the weight of aluminum.
Our sheet is not as rigid as glass or metals. However, it is more rigid than many other plastics such as acetates, polycarbonates or vinyls. Under wind load an acrylic sheet will bow and foreshorten as a result of deflection.
For glazing installations the maximum wind load and the size of the window must be considered when the thickness of a panel is to be determined.
If the sheet is formed into corrugated or domed shapes, rigidity will be increased and deflection minimized.
Large, flat ACRYLITE® sheet, if insufficiently supported, may deform permanently due to continuous loads such as snow, or even their own weight. Increased rigidity obtained by forming will minimize cold flow.
Strength and Stresses
Although the tensile strength of ACRYLITE® premium is 10,000 psi (69 Mpa) at room temperature (ASTM D 638), stress crazing can be caused by continuous loads below this value. For glazing applications, continuously imposed design loads should not exceed 750 psi (5.2 Mpa) at 73°F (23°C). Temporary loads of up to 1,500 psi (10.4 Mpa) may be imposed for short duration's of time at 73°F (23°C).
Localized, concentrated stresses must be avoided. For this reason, and because of thermal expansion and contraction, large sheets should never be fastened with bolts, but should always be installed in frames.
All thermoplastic materials, including ACRYLITE® premium sheet, will gradually lose tensile strength as the temperature approaches the maximum recommended for continuous service–160°F (71°C).
Expansion and Contraction
Like most other plastics, our premium sheet will expand and contract from 3 to 8 times as much as glass or metals. The designer should be aware of its coefficient of expansion and make appropriate provisions. A 48” panel will expand and contract approximately .002” for each degree Fahrenheit change in temperature. In outdoor use, where summer and winter temperatures differ as much as 100°F, a 48” sheet will expand and contract approximately 3/16”. Sash rabbets must be of sufficient depth to allow for expansion as well as for contraction.
Premium also absorbs water when exposed to high relative humidity, resulting in expansion of the sheet. At relative humidity of 100%, 80%, and 60%, the dimensional changes are 0.6%, 0.3%, and 0.2%, respectively.
This sheet can be used at temperatures from -30°F (-34°C) up to +190°F (+88°C), depending on the application. It is recommended that temperatures not exceed 160°F (71°C) for continuous service, or 190°F (88°C) for short, intermittent use. Components made of ACRYLITE® should not be exposed to high heat sources such as high wattage incandescent lamps, unless the finished product is ventilated to permit the dissipation of heat.
Clear, colorless premium sheet has a light transmittance of 92%. It is warranted not to lose more than 3% of its light-transmitting ability in a 30-year period. Contact Roehm America LLC for the complete warranty.
ACRYLITE® UV filtering (OP3) sheet is formulated with ultraviolet absorbers designed to help protect pictures, photographs, and posters from the damaging effects of ultraviolet light. The OP-3 sheet absorbs more than 98% of the radiation in the ultraviolet range below 400 nanometers.
ACRYLITE® premium has excellent resistance to many chemicals including:
- Solutions of inorganic alkalies such as ammonia
- Dilute acids such as sulfuric acid up to a concentration of 30%
- Aliphatic hydrocarbons such as hexane and VM&P naphtha
ACRYLITE® premium sheet is not attacked by most foods and foods are not affected by it. It is attacked, in varying degrees, by:
- Aromatic solvents such as benzene and toluene
- Chlorinated hydrocarbons such as methylene chloride and carbon tetrachloride
- Ethyl and methyl alcohols
- Some organic acids such as acetic acid
- Lacquer thinners, esters, ketones, and ethers
For a listing of the resistance of ACRYLITE® sheet to more than 60 chemicals, refer to the table below.
ACRYLITE® premium sheet will soften as the temperature is increased above 195°F (91°C). As the temperature is increased the sheet passes through the thermo-elastic state to the thermoplastic state. The change is gradual rather than sharply defined. The forming temperature range is between 290°F and 320°F (143°C and 160°C). Because the sheet gradually becomes thermoplastic, certain procedures should be considered during thermoforming. If the sheet is to be hung in an oven, it is necessary to use a continuous clamp rather than several individual clamps. This will prevent the sheet from permanently deforming between clamps. If the sheet is to be heated by infrared heaters while clamped in a horizontal frame, it may be necessary to control the heaters above the center of the sheet. This will prevent the center from becoming too hot and sagging under its own weight.
The sheet will exhibit very little “memory” after forming and probably will not return to its original flat condition if reheated.
Our premium sheet will shrink in the machine direction when heated without a frame. Sheet thicknesses of .118” (3.0 mm) and greater will shrink no more than 3%. Thinner thicknesses could shrink more.
Cutting and Machining
It can be sawed with circular saws or band saws. It can be drilled, routed, filed, and machined much like wood or brass with a slight modification of tools. Because the sheet softens quickly, it is necessary to keep the cutting tool and machined edge of the sheet as cool as possible. Cooling of the cutting tool is recommended. Tool sharpness and “trueness” are essential to prevent gumming, heat buildup, and stresses in the part. Heat buildup at the machined edge could lead to subsequent stress crazing and therefore must be avoided.
Laser technology is ideal for quick and accurate cutting, welding, drilling, scribing, and engraving of plastics. CO2 lasers focus a large amount of light energy on a very small area which is extremely effective for cutting complex shapes in acrylic sheet. The laser beam produces a narrow kerf in the plastic allowing for close nesting of parts and minimal waste. CO2 lasers vaporize the acrylic as they advance resulting in a clean polished edge but with high stress levels; annealing acrylic sheet after laser cutting is recommended to minimize the chance of crazing during the service life of the part.
ACRYLITE® sheet can be cemented using common solvent cements or polymerizable cements such as ACRIFIX®. The most critical factor is good edge preparation of the part to be cemented. The edge of the sheet must be properly machined in order to have a square flat surface and no stresses. Annealing of the part prior to cementing is recommended. Cement and cement fumes should not contact formed or polished surfaces.
The sheet may be annealed at 180°F (82°C) with the heating and cooling times determined by the sheet thickness. An approximate guideline is annealing time in hours equals the sheet thickness in millimeters and the cool-down period is a minimum of 2 hours ending when sheet temperature falls below 140°F. For example, 1/8” (3mm) ACRYLITE® sheet would be heated for 3 hours at 180°F (82°C) and slowly cooled for 3 hours.
ACRYLITE® is a combustible thermoplastic. Precautions should be taken to protect this material from flames and high heat sources. This sheet usually burns rapidly to completion if not extinguished. The products of combustion, if sufficient air is present, are carbon dioxide and water. However, in many fires sufficient air will not be available and toxic carbon monoxide will be formed, as it will when other common combustible materials are burned. We urge good judgment in the use of this versatile material and recommend that building codes be followed carefully to assure it is used properly.
The combustibility test data for this sheet is: self-ignition temperature (ASTM D-1929) is 850°F (455°C), smoke density as measured by ASTM D-2843 is 6.4%, and the rate of burning as measured by ASTM D-635 is 1.0 in/min (25mm/min) for 1/8” (3mm) thick sheet. While this data is based on small scale laboratory tests frequently referenced in various building codes, these tests do not duplicate actual fire conditions.
The thermal conductivity of a material – its ability to conduct heat – is called k-Factor. The k-Factor is an inherent property of the material, and is independent of its thickness and of the surroundings to which it is exposed. The k-Factor of ACRYLITE® sheet is:
1.3 B.T.U. / (hour) (sq. ft.) (°F/inch) or 0.19 W /m. K
Whereas the k-Factor is a physical property of the material, the U-Factor — or overall coefficient of heat transfer — is the value used to calculate the total heat loss or gain through a window.
The U-Factor is the amount of heat per unit time and area which will pass through a specific thickness and configuration of material per degree of temperature difference on each of its two sides.
This value takes into account the thickness of the sheet, whether the sheet is in a horizontal or vertical position, as well as the wind velocity. U-Factors are based on specific conditions (e.g., single-glazed or double-glazed installations) and are different for summer and winter.
Listed below are U-Factors for several thicknesses of ACRYLITE® sheet for single-glazed, vertical installations, based on the standard ASHRAE* summer and winter design conditions.
U-Factors—BTU/hour sq. ft. F° (w/m² x K)
|ACRYLITE® premium Sheet Thickness||Summer Conditions||Winter Conditions|
|3.0||.118||0.98 (5.56)||1.06 (6.02)|
|4.5||.177||0.94 (5.34)||1.02 (5.79)|
|6.0||.236||0.90 (5.11)||0.97 (5.51)|
|9.5||.375||0.83 (4.71)||0.89 (5.05)|
*American Society of Heating, Refrigerating, and Air-Conditioning Engineers
The total heat loss or gain through a window (due to temperature difference only) can be calculated by multiplying the area of the window, times the difference between indoor and outdoor temperatures, times the appropriate U-Factor (from Table above). Heat intake through solar radiation must be added to arrive at the total heat gain. Our premium sheet is a better insulator than glass. Its U-Factor or overall coefficient of heat transfer is approximately 10% lower than that of glass of the same thickness. Conversely, its RT-Factor is about 10% greater.
Thermal Shock and Stresses
ACRYLITE® premium sheet is more resistant than glass to thermal shock and to stresses caused by substantial temperature differences between a sunlit and a shaded area of a window or by temperature differences between opposite surfaces of a window.
The surface of plastic is not as hard as that of glass. Therefore, reasonable care should be exercised in handling and cleaning the sheet.
It has many desirable electrical properties. It is a good insulator. Its surface resistivity is higher than that of most plastics. Continuous outdoor exposure has little effect on its electrical properties.
The table below gives an indication of the chemical resistance of ACRYLITE® premium sheet. The code used to describe chemical resistance is as follows:
It only withstands this substance for long periods and a temperature of 120°F (49°C).
LR= Limited Resistance
This premium sheet only resists the action of this substances for a short periods at room temperatures. The resistance for particular application must be determined.
N= Non Resistant
ACRYLITE® premium sheet is not resistance to this substance. It is swelled, attacked, dissolved, or damaged in some manner. Plastic materials can be attacked by chemicals in several ways. The methods of fabrication and/or conditions of exposure of ACRYLITE® sheet, as well as the manner, in which the chemical are supplied, can influence the final results even for “R” coded chemicals. Some of these factors are listed below:
Fabrication-Stress generated while sawing, sanding, machining, drilling, and/or forming.
Exposure- Length of exposure, stresses induced during the life of the product due to various loads, changes in temperatures, etc.
Application of Chemicals- by contact, rubbing, wiping, spraying, etc.
The table should therefore be used as only a general guide and, in case of doubt; it should be supplemented by tests made under actual working conditions.
Chemical Resistance of Clear ACRYLITE®
|Acetic Acid (5%)||LR||Ethyl Alcohol (30%)||LR||Nitric Acid (Conc.)||N|
|Acetic Acid (Glacial)||N||Ethyl Alcohol (95%)||N||Oleic Acid||R|
|Acetone||N||Ethylene Dichloride||N||Olive Oil||R|
|Ammonium Chloride||R||Ethylene Glycol||R||Phenol Solution (5%)||N|
|Ammonium Hydroxide (10%)||R||Gasoline||LR||Soap Solution (Mild dish soap)||R|
|Ammonium Hydroxide (Conc.)||R||Glycerine||R||Sodium Carbonate (2%)||R|
|Aniline||N||Heptane||R||Sodium Carbonate (20%)||R|
|Battery Acid||R||Hexane||R||Sodium Chloride (10%)||R|
|Benzene||N||Hydrochloric Acid||R||Sodium Hydroxide (1%)||R|
|Butyl Acetate||N||Hydrofluoric Acid (25%)||N||Sodium Hydroxide (10%)||R|
|Calcium Chloride (Sat.)||R||Hydrogen Peroxide (<40%)||R||Sodium Hydroxide (60%)||R|
|Calcium Hypochlorite||R||Hydrogen Peroxide (>40%)||LR||Sodium Hypochlorite (5%)||R|
|Carbon Tetrachloride||N||Isopropyl Alcohol||LR||Sulfuric Acid (3%)||R|
|Chloroform||N||Kerosene||R||Sulfuric Acid (30%)||R|
|Chromic Acid||LR||Lacquer Thinner||N||Sulfuric Acid (Conc.)||N|
|Citric Acid (20%)||R||Methyl Alcohol (30%)||LR||Toluene||N|
|Cottonseed Oil (Edible)||R||Methyl Alcohol (100%)||N||Transformer Oil||R|
|Detergent Solution (Heavy Duty)||R||Methyl Ethyl Ketone (MEK)||N||Trichloroethylene||N|
|Diesel Oil||R||Methylene Chloride||N||Turpentine||R|
|Dimethyl Formamide||N||Mineral Oil||R||Water||R|
|Dioctyl Phthalate||N||Nitric Acid (10%)||R||Xylene||N|
|Ethyl Acetate||N||Nitric Acid (40%)||LR|
Physical Characteristics of ACRYLITE®
|Property(a)||ASTM Method||Typical Value ( 0.250“ Thickness) (b)|
|Mechanical||Specific Gravity||D 792||1.19|
Tensile Strength Elongation,
Rupture Modulus of Elasticity
10,000 psi (69 MPa)
400,000 psi (2800 MPa)
Modulus of Elasticity
17,000 psi ( 117 MPa)
480,000 psi (3300 MPa)
|Compressive Strength ( Yield)||D 695||17,000 psi (117 MPa)|
|Impact Strength Izod Milled Notch||D 256||
0.4 ft. lbs/in. of notch
(21.6 J/m of notch)
|Rockwell Hardness||D 785||M-93|
|Barcol Hardness||D 2583||48|
|Optical||Refractive Index||D 542||1.49|
|Light Transmission, Total||D 1003||92%|
|Thermal||Forming Temperature||-||Approx. 300°F (149°C)|
|Deflection Temperature under load, 264 psi||D 648||195°F (91°C)|
|Vicat Softening Point||D 1525||220°F (105°C)|
Maximum recommended Continuous
|Coefficient of Linear Thermal Expansion||D 696||
0.000040 in/in - °F
(0.000072 m/m - °C)
|Coefficient of Thermal Conductivity||Cenco-Fitch||1.3 BTU/ (Hr) (Sq.Ft.) (°F / in.) (0.19 w/m•K)|
|Flammability, Burning Rate (0.125”thickness)||D 635||
|Self Ignition Temperature||D 1929||850°F(455°C)|
|Specific Heat @ 77°F||0.35 BTU/(Ib.) (°F)(1470J/Kg•K)|
|Smoke Density Rating||D 2843||4.8%|
|Electrical||Dielectric Strength Short Time ( 0.125”)||D 149||430 volts/mil (17 KV/mm)|
|Volume Resistivity||D 257||1016ohm-cm|
|Surface Resistivity||D 257||1016ohms|
24 hrs @ 73°F
- (a)Typical values; should not be used for specification purposes.
- (b)Values shown are for 0.250” thickness. Some values will change with thickness or pigmentation.
- (c)It is recommended that temperatures not exceed 160°F for continuous service, or 190°F for short intermittent use.