Pt. 63, Subpt. HHHH, App. A
Appendix A to Subpart HHHH of Part 63
—Method for Determining Free-Formaldehyde in Urea-Formaldehyde Resins by Sodium Sulfite (Iced & Cooled)
This procedure corresponds to the Housing and Urban Development method of determining free-formaldehyde in urea-formaldehyde resins. This method applies to samples that decompose to yield formaldehyde under the conditions of other free-formaldehyde methods. The primary use is for urea-formaldehyde resins.
2.0Part A—Testing Resins
Formaldehyde will react with sodium sulfite to form the sulfite addition products and liberate sodium hydroxide (NaOH); however, at room temperature, the methanol groups present will also react to liberate NaOH. Titrate at 0 degrees Celsius (( °deg;C) to minimize the reaction of the methanol groups.
2.1.2One 100-milliliter (mL) graduated cylinder.
2.1.3Three 400-mL beakers.
2.1.4One 50-mL burette.
2.1.5Analytical balance accurate to 0.1 milligrams (mg).
2.1.7Magnetic stirring bars.
2.1.9Several 5-ounce (oz.) plastic cups.
2.1.10Ice cube trays (small cubes).
2.2.1Ice cubes (made with distilled water).
2.2.2A solution of 1 molar (M) sodium sulfite (Na2SO3) (63 grams (g) Na2SO3/500 mL water (H2O) neutralized to thymolphthalein endpoint).
2.2.3Standardized 0.1 normal (N) hydrochloric acid (HCl).
2.2.4Thymolphthalein indicator (1.0 g thymolphthalein/199 g methanol).
2.2.5Sodium chloride (NaCl) (reagent grade).
2.2.6Sodium hydroxide (NaOH).
2.3.1Prepare sufficient quantity of crushed ice for three determinations (two trays of cubes).
2.3.2Put 70 cubic centimeters (cc) of 1 M Na2SO3 solution into a 400-mL beaker. Begin stirring and add approximately 100 g of crushed ice and 2 g of NaCl. Maintain 0 °C during test, adding ice as necessary.
2.3.3Add 10-15 drops of thymolphthalein indicator to the chilled solution. If the solution remains clear, add 0.1 N NaOH until the solution turns blue; then add 0.1 N HCl back to the colorless endpoint. If the solution turns blue upon adding the indicator, add 0.1 N HCl to the colorless endpoint.
2.3.4On the analytical balance, accurately weigh the amount of resin indicated under the “Resin Sample Size” chart (see below) as follows.
Resin Sample Size
|Approximate free HCHO(percent)
220.127.116.11Pour about 1 inch of resin into a 5 oz. plastic cup.
18.104.22.168Determine the gross weight of the cup, resin, and disposable pipette (with the narrow tip broken off) fitted with a small rubber bulb.
22.214.171.124Pipette out the desired amount of resin into the stirring, chilled solution (approximately 1.5 to 2 g per pipette-full).
126.96.36.199Quickly reweigh the cup, resin, and pipette with the bulb.
188.8.131.52The resultant weight loss equals the grams of resin being tested.
2.3.5Rapidly titrate the solution with 0.1 N HCl to the colorless endpoint described in Step 3 (2.3.3).
2.3.6Repeat the test in triplicate.
2.4.1The percent free-formaldehyde (%HCHO) is calculated as follows:
2.4.2Compute the average percent free-formaldehyde of the three tests.
(Note: If the results of the three tests are not within a range of ±0.5 percent or if the average of the three tests does not meet expected limits, carry out Part B and then repeat Part A.)
3.0Part B—Standard Check
Part B ensures that test reagents used in determining percent free-formaldehyde in urea-formaldehyde resins are of proper concentration and that operator technique is correct. Should any doubts arise in either of these areas, the formaldehyde standard solution test should be carried out.
3.1Preparation and Standardization of a 1 Percent Formalin Solution.
Prepare a solution containing approximately 1 percent formaldehyde from a stock 37 percent formalin solution. Standardize the prepared solution by titrating the hydroxyl ions resulting from the formation of the formaldehyde bisulfite complex.
All reagents must be American Chemical Society analytical reagent grade or better.
3.2.1One 1-liter (L) volumetric flask (class A).
3.2.2One 250-mL volumetric flask (class A).
3.2.3One 250-mL beaker.
3.2.4One 100-mL pipette (class A).
3.2.5One 10-mL pipette (class A).
3.2.6One 50-mL graduated cylinder (class A).
3.2.7A pH meter, standardized using pH 7 and pH 10 buffers.
3.2.9Magnetic stirring bars.
3.2.10Several 5-oz. plastic cups.
3.2.12Ice cube trays (small cubes).
3.3.1A solution of 37 percent formalin.
3.3.4Standardized 0.100 N HCl.
3.3.5Thymolphthalein indicator (1.0 g thymolphthalein/199 g methanol).
3.4Preparation of Solutions and Reagents.
3.4.1Formaldehyde Standard Solution (approximately 1 percent). Measure, using a graduated cylinder, 27.0 mL of analytical reagent 37 percent formalin solution into a 1-L volumetric flask. Fill the flask to volume with distilled water.
You must standardize this solution as described in section 3.5
. This solution is stable for 3 months.)
3.4.2Sodium Sulfite Solution 1.0 M (used for standardization of Formaldehyde Standard Solution). Quantitatively transfer, using distilled water as the transfer solvent, 31.50 g of anhydrous Na2SO3 into a 250-mL volumetric flask. Dissolve in approximately 100 mL of distilled water and fill to volume.
(Note: You must prepare this solution daily, but the calibration of the Formaldehyde Standard Solution needs to be done only once.)
3.4.3Hydrochloric Acid Standard Solution 0.100 M. This reagent should be readily available as a primary standard that only needs to be diluted.
3.5.1Standardization of Formaldehyde Standard Solution.
184.108.40.206Pipette 100.0 mL of 1 M sodium sulfite into a stirred 250-mL beaker.
220.127.116.11Using a standardized pH meter, measure and record the pH. The pH should be around 10. It is not essential the pH be 10; however, it is essential that the value be accurately recorded.
18.104.22.168To the stirring Na2SO3 solution, pipette in 10.0 mL of Formaldehyde Standard Solution. The pH should rise sharply to about 12.
22.214.171.124Using the pH meter as a continuous monitor, titrate the solution back to the original exact pH using 0.100 N HCl. Record the milliliters of HCl used as titrant. (Note: Approximately 30 to 35 mL of HCl will be required.)
126.96.36.199Calculate the concentration of the Formaldehyde Standard Solution using the equation as follows:
3.6.1Prepare a sufficient quantity of crushed ice for three determinations (two trays of cubes).
3.6.2Put 70 cc of 1 M Na2SO3 solution into a 400-mL beaker. Begin stirring and add approximately 100 g of crushed ice and 2 g NaCl. Maintain 0 °C during the test, adding ice as necessary.
3.6.3Add 10-15 drops of thymolphthalein indicator to the chilled solution. If the solution remains clear, add 0.1 N NaOH until the solution turns blue; then add 0.1 N HCl back to the colorless endpoint. If the solution turns blue upon adding the indicator, add 0.1 N HCl to the colorless endpoint.
3.6.4On the analytical balance, accurately weigh a sample of Formaldehyde Standard Solution as follows.
188.8.131.52Pour about 0.5 inches of Formaldehyde Standard Solution into a 5-oz. plastic cup.
184.108.40.206Determine the gross weight of the cup, Formaldehyde Standard Solution, and a disposable pipette fitted with a small rubber bulb.
220.127.116.11Pipette approximately 5 g of the Formaldehyde Standard Solution into the stirring, chilled Na2SO3 solution.
18.104.22.168Quickly reweigh the cup, Formaldehyde Standard Solution, and pipette with the bulb.
22.214.171.124The resultant weight loss equals the grams of Formaldehyde Standard Solution being tested.
3.6.5Rapidly titrate the solution with 0.1 N HCl to the colorless endpoint in Step 3 (3.6.3).
3.6.6Repeat the test in triplicate.
3.7Calculation for Formaldehyde Standard Solution.
3.7.1The percent free-formaldehyde (% HCHO) is calculated as follows:
3.7.2The range of the results of three tests should be no more than ±5 percent of the actual Formaldehyde Standard Solution concentration. Report results to two decimal places.
West Coast Adhesive Manufacturers Trade Association Test 10.1.