Celvol polyvinyl alcohols have many characteristics which make them useful in a wide range of applications. By choosing among the many Celvol polyvinyl alcohol grades available, it is possible to obtain the performance properties required for your specific applications-properties such as water solubility, abrasion resistance, tensile strength, adhesive and bonding properties, grease or oil resistance and film forming qualities. Our highly skilled technical service group can help you with Celvol polyvinyl alcohol grade selection.
Changes
Occurring in the Properties of Polyvinyl Alcohol
as the Degree
of Hydrolysis and Molecular Weight Change
Physical
Properties
Celvol polyvinyl alcohol combines high tensile strength with ease of
film formation. Additionally, Celvol resins show excellent adhesive and bonding characteristics. Partially
hydrolyzed grades have better adhesion to hydrophobic surfaces.
The degree
of hydrolysis affects the water sensitivity of both the resin and film. Water resistance increases with
increasing hydrolysis. The super hydrolyzed grades should be used when maximum water resistance and
humidity resistance are desired.
Celvol polyvinyl alcohol resins are
generally unaffected by greases, petroleum hydrocarbons and animal or vegetable oils. Resistance to
organic solvents increases with the degree of hydrolysis. Celvol polyvinyl alcohol film can be plasticized
with glycerol or the lower molecular weight glycols. These materials generally act as humectants, holding
water in the film.
Physical Properties of Polyvinyl Alcohol
| Appearance | White-to-cream granular powder |
| Bulk Density | 40 lbs/cu ft |
| Specific Gravity | |
| — of solid | 1.27 - 1.31 |
| — of 10 wt % solid at 25°C | 1.02 |
| Thermal Stability | Gradual discoloration about 100°C; darkens rapidly above 150°C; rapid decomposition above 200°C |
| Thermal Conductivity, W/(m•K)3 | 0.2 |
| Electrical Resistivity, ohm•cm | (3.1 - 3.8) x 107 |
| Specific Heat, | |
| J/(g•K)b | 1.5 |
| Melting Point | |
| (unplasticized), °C | 230 for fully hydrolyzed grades; 180-190 for partially hydrolyzed grades |
| Tg, °C (dry film) | 75-85 |
| Storage Stability (solid) | Indefinite when protected from moisture |
| Flammability | Burns similarly to paper |
| Stability to Sunlight | Excellent |
Notes
a. To convert W/(m•K) to (Btu•in)/(h•ft2•F), divide by 0.1441.
b. To convert J to cal, divide by 4.184.
Chemical Reactions
Polyvinyl alcohol resins react in a manner similar to other secondary polyhydric alcohols. Esterification reactions of polyvinyl alcohol can be carried out with a number of compounds. A commercially important reaction is the formation of tackified PVOH using boric acid or borax to form cyclicesters. This reaction is very sensitive to pH, and an insoluble gel is formed above 4.5-5.0.
Other esterification reactions include those with chloroformate esters to yield polyvinyl carbonate, with urea to yield a polymeric carbamate ester, and with isocyanates to form substituted carbamate esters.
Another commercially important reaction is acetalization with aldehydes. Polyvinyl butyral is produced by the reaction of polyvinyl alcohol with butyraldehyde and is used in the production of the inner adhesive film for safety glass. Reaction with dialdehydes such as glyoxal or gluteraldehyde can be used to crosslink polyvinyl alcohol. Other reactions include ethoxylation, propoxylation and cyanoethylation.
Crosslinking
All
polyvinyl alcohol grades are crosslinkable through their secondary hydroxyl functionality. Even lower
hydrolysis grades—which are so exceptional on paper surfaces for oil, grease and organic solvent resistance
and Gurley porosity—can be made water resistant. Degrees of water resistance vary from grade to grade.
The table below shows the effect of glyoxal, a commonly used and favored crosslinker for polyvinyl alcohol.
When glyoxal was added to Celvol grades 540, 350 and 165 polyvinyl alcohol at 20% dry-on-dry, significant
water resistance improvements resulted. Note that the wet tensile of Celvol 540 polyvinyl alcohol increased
from no measurable wet strength uncrosslinked to 6.1 pli when crosslinked. Also, the wet tensile of
crosslinked Celvol 350 polyvinyl alcohol was more than double that of uncrosslinked Celvol 350, and
crosslinked Celvol 165 polyvinyl alcohol was 28% higher than uncrosslinked Celvol 165.
A
vast array of crosslinkers or insolubilizers are available. They include several classes: (1) aldehydes,
of which glyoxal, a simple dialdehyde, is the most common, along with higher aldehydes, such as gluteraldehyde
and hydroxyadipaldehyde; (2) thermosetting resins, such as urea-formaldehyde and melamineformaldehyde;
and (3) salts of multivalent anions, such as zirconium ammonium carbonates.
More
recently, there has emerged a growing interest in zero-formaldehyde, or low-formaldehyde-type crosslinkers.
Two such products are Polycup 172, a water soluble, polyamide-epichlorohydrin-type resin, and Bacote-20,
a zirconium ammonium carbonate salt. The results in the table below indicate that the addition of Polycup
172 to Celvol 165 polyvinyl alcohol at 5% dry/dry parts was as effective as glyoxal added at 20%, both
resulting in a 26% wet tensile improvement. The addition of 5% Bacote-20 resulted in an 11% wet tensile
improvement.
Effect of Glyoxal on Polyvinyl Alcohol Wet
Tensile Strength Chromatography Base Paper*
| Celvol Grade | % Hydrolysis Spec. Range | % Glyoxal Dry/Dry | Wet Tensiles, pli (3 Min in 1% Aerosol OT Solution) |
| 540 | 87-89 | None | 0.0 |
| 540 | 87-89 | 20 | 6.1 |
| 350 | 98-98.8 | None | 3.2 |
| 350 | 98.98.8 | 20 | 6.6 |
| 165 | 99.3+ | None | 6.7 |
| 165 | 99.3+ | 20 | 8.6 |
Note:
* 9 add-on level based on fiber; cure 5 min @ 149°C.
Effect of Crosslinker Type on Wet Tensile of Celvol 165 Polyvinyl Alcohol-Saturated Paper*
| Crosslinker | % Dry/Dry | Instron Wet Tensile (CMD) pli |
| None | — | 6.4 |
| Glyoxal | 20 | 8.0 |
| Bacote-20 | 5 | 7.1 |
| polycup 172 | 5 | 8.1 |
Note:
* Whatman No. 4 chromatography paper
10% Celvol 65 add-on
Drying Conditions were 5 min @ 149°C.
