The substances listed in this section may be safely used in surface lubricants employed in the manufacture of metallic articles that contact food, subject to the provisions of this section.
List of substances | Limitations |
[ALPHA]-Butyl-©--hydroxypoly (oxyethylene)-poly (oxypropylene) (CAS Reg. No. 9038-95-3) produced by random condensation of a 1:1 mixture by weight of ethylene oxide and propylene oxide with butanol and having a minimum molecular weight of 1,000 | |
[ALPHA]-Butyl-©-hydroxypoly(oxypropylene) (CAS Reg. No. 9003-13-8) having a minimum molecular weight of 1000 | |
[ALPHA]-Lauroyl-©-hydroxpoly(oxyethylene) (CAS Reg. No. 9004-81-3) having a minimum molecular weight of 200 | |
Acetate esters derived from synthetic straight chain alcohols (complying with § 172.864 of this chapter) that have even numbers of carbon atoms in the range C8-C18 | |
alpha-Alkyl-omega-hydroxypoly(oxyethylene) produced by the condensation of 1 mole of C12-C15 straight chain primary alcohols with an average of 3 moles of ethylene oxide (CAS Reg. No. 68002-97-1) | |
Benzotriazole (CAS Reg. No. 95-14-7) | |
Bis(hydrogenated tallow alkyl)amine (CAS Reg. No. 61789-79-5) | Not to be used in combination with sodium nitrite. |
Bis(hydrogenated tallow alkyl)aminoethanol (CAS Reg. No. 116438-56-3) | |
N,N-Bis(2-hydroxyethyl)butylamine (CAS Reg. No. 102-79-4) | |
Tert-Butyl alcohol | |
Di(2-ethylhexyl)phthalate | |
Diethylene glycol monobutylether (CAS Reg. No. 112-34-5) | |
Dimers, trimers, and/or their partial methyl esters; such dimers and trimers are of unsaturated C18 fatty acids derived from animal and vegetable fats and oils and/or tall oil, and such partial methyl esters meet the following specifications: Saponification value 180-200, acid value 70-130, and maximum iodine value 120 | For use only at a level not to exceed 10 percent by weight of finished lubricant formulation. |
Di-n-octyl sebacate | |
Ethylenediaminetetraacetic acid, sodium salts | |
Isopropyl alcohol | |
Isopropyl laurate (CAS Reg. No. 10233-13-3) | For use at a level not to exceed 10 percent by weight of the finished lubricant formulation. |
Isopropyl oleate | |
Isotridecyl alcohol, ethoxylated (CAS Reg. No. 9043-30-5) | |
Methyl esters of coconut oil fatty acids | |
Methyl esters of fatty acids (C16-C18) derived from animal and vegetable fats and oils | |
Polybutene, hydrogenated: complying with the identity prescribed under § 178.3740(b) | |
Polyethylene glycol (400) monostearate | |
Polyisobutylene (minimum molecular weight 300) | |
Polyoxyethylated (5 moles) tallow amine (CAS Reg. No. 61791-26-2) | |
Polyvinyl alcohol | |
Sodium nitrite | For use only as a rust inhibitor in lubricant formulations provided the total residual sodium nitrite on the metallic article in the form in which it contacts food does not exceed 0.007 milligram per square inch of metallic food-contact surface. |
Sodium petroleum sulfonate, MW 440-450 (CAS Reg. No. 68608-26-4) derived from naphthenic oil having a Saybolt viscosity range of 500-600 Saybolt Universal Seconds (SUS at 37-8 °C (100 °F) as determined by ASTM method D88-81, "Standard Test Method for Saybolt Viscosity," which is incorporated by reference. Copies are available from the American Society for Testing Materials, 1961 Race St., Philadelphia, PA 19103, or available for inspection at the National Archives and Records Administration (NARA). For information on the availability of this material at NARA, call 202-741-6030, or go to: http://www.archives.gov/federal_register/code_of_federal_regulations/ibr_locations.html. | |
Synthetic alcohol mixture of straight-and branched-chain alcohols that have even numbers of carbon atoms in the range C4C18 and that are prepared from ethylene, aluminum, and hydrogen such that the finished synthetic alcohol mixture contains not less than 75 pct of straight-chain primary alcohols and contains not less than 85 pct total C10 and C12 alcohols | |
Synthetic primary alcohol mixture of straight- and branched-chain alcohols that contain at least 99 pct primary alcohols consisting of the following: not less than 70 pct normal alcohols; not less than 96.5 pct C12-C15 alcohols; and not more than 2.5 pct alpha, omega C13-C16 diols. The alcohols are prepared from linear olefins from a purified kerosene fraction, carbon monoxide and hydrogen using a modified oxo process, such that the finished primary alcohol mixture meets the following specifications: Molecular weight, 207±4; hydroxyl number, 266-276 | For use at a level not to exceed 8 pct by weight of the finished lubricant formulation. |
Synthetic primary alcohol mixture of straight- and branched-chain alcohols that contain at least 99 pct primary alcohols consisting of the following: not less than 70 percent normal alcohols; not less than 93 pct C12-C13 alcohols; not more than 5 pct C14-C15 alcohols; and not more than 2.5 pct alpha, omega, C13-C16 diols. The alcohols are prepared from linear olefins from a purified kerosene fraction, carbon monoxide and hydrogen using a modified oxo process, such that the finished primary alcohol mixture meets the following specifications: | For use only at a level not to exceed 8 pct by weight of the finished lubricant formulation. |
Molecular weight 194±5; hydroxyl number, 283-296 | |
Tallow, sulfonated | |
Triethanolamine |
Wavelength (m[MICRO]) | Maximum absorbance per 5 centimeters optical pathlength |
280-289 | 0.7 |
290-299 | .6 |
300-359 | .4 |
360-400 | .09 |
general instructions
Because of the sensitivity of the test, the possibility of errors arising from contamination is great. It is of the greatest importance that all glassware be scrupulously cleaned to remove all organic matter such as oil, grease, detergent, residues, etc. Examine all glassware including stoppers and stopcocks, under ultraviolet light to detect any residual fluorescent contamination. As a precautionary measure it is recommended practice to rinse all glassware with purified isooctane immediately before use. No grease is to be used on stopcocks or joints. Great care to avoid contamination of oil samples in handling and to assure absence of any extraneous material arising from inadequate packaging is essential. Because some of the polynuclear hydrocarbons sought in this test are very susceptible to photo-oxidation, the entire procedure is to be carried out under subdued light.
apparatus
Separatory funnels. 250-milliliter, 500-milliliter, 1,000-milliliter, and preferably 2,000-milliliter capacity, equipped with tetrafluoroethylene polymer stopcocks.
Evaporation flask (optional). 250-milliliter or 500-milliliter capacity all-glass flask equipped with standard-taper stopper having inlet and outlet tubes to permit passage of nitrogen across the surface of contained liquid to be evaporated.
Spectrophotometric cells. Fused quartz cells, optical path length in the range of 5,000 centimeters ±0.005 centimeter; also for checking spectrophotometer performance only, optical path length in the range 1.000 centimeter ±0.005 centimeter. With distilled water in the cells, determine any absorbance differences.
Spectrophotometer. Special range 250 millicrons-400 millimicrons with spectral slit width of 2 millimicrons or less; under instrument operating conditions for these absorbance measurements, the spectrophotometer shall also meet the following performance requirements:
Absorbance repeatability, ±0.01 at 0.4 absorbance.
Absorbance accuracy,±0.05 at 0.4 absorbance.
Wavelength repeatability, ±0.2 millimicron.
Wavelength accuracy, ±1.0 millimicron.
Soxhlet apparatus. 60-millimeter diameter body tubes fitted with condenser and 500-milliliter round-bottom boiling flask. A supply of paper thimbles to fit is required.
Nitrogen cylinder. Water-pumped or equivalent purity nitrogen in cylinder equipped with regulator and valve to control flow at 5 p.s.i.g.
reagents and materials
Organic solvents. All solvents used throughout the procedure shall meet the specifications and tests described in this specification. The isooctane (2,2,4-trimethylpentane) shall pass the following test:
Place 180 milliliters of solvent in a 250-milliliter Erlenmeyer flask, add 1 milliliter of purified n-hexadecane and evaporate on the steam bath under a stream of nitrogen (a loose aluminum foil jacket around the flask will speed evaporation). Discontinue evaporation when not over 1 milliliter of residue remains.
Alternatively, the evaporation time can be reduced by using the optional evaporation flask. In this case the solvent and n-hexadecane are placed in the flask on the steam bath, the tube assembly is inserted, and a stream of nitrogen is fed through the inlet tube while the outlet tube is connected to a solvent trap and vacuum line in such a way as to prevent any flow-back of condensate into the flask.
Dissolve the 1 milliliter of hexadecane residue in isooctane and make to 25 milliliters volume. Determine the absorbance in the 5-centimeter path length cells compared to isooctane as reference. The absorbance of the solution of the solvent residue shall not exceed 0.01 per centimeter path length between 280 and 400 m[MICRO]. Purify, if necessary, by passage through a column of activated silica gel (Grade 12, Davison Chemical Co., Baltimore, Maryland, or equivalent) about 90 centimeters in length and 5 centimeters to 8 centimeters in diameter.
n-Hexadecane, 99-percent olefin-free. Dilute 1.0 milliliter of n-hexadecane to 25 milliliters with isooctane and determine the absorbance in a 5-centimeter cell compared to isooctane as reference point between 280 m[MICRO]-400 m[MICRO]. The absorbance per centimeter path length shall not exceed 0.00 in this range. Purify, if necessary, by percolation through activated silica gel or by distillation.
Dimethyl sulfoxide. Spectrophotometric grade (Crown Zellerbach Corp., Camas, Washington, or equivalent). Absorbance (1-centimeter cell, distilled water reference, sample completely saturated with nitrogen).
Wavelength | Absorbance (maximum) |
261.5 | 1.00 |
270 | .20 |
275 | .09 |
280 | .06 |
300 | .015 |
There shall be no irregularities in the absorbance curve within these wavelengths.
Phosphoric acid. 85 percent A.C.S. reagent grade.
Sodium sulfate, anhydrous, A.C.S. reagent grade, preferably in granular form. For each bottle of sodium sulfate reagent used, establish as follows the necessary sodium sulfate prewash to provide such filters required in the method: Place approximately 35 grams of anhydrous sodium sulfate in a 30-milliliter coarse, fritted-glass funnel or in a 65-milliliter filter funnel with glass wool plug; wash with successive 15-milliliter portions of the indicated solvent until a 15-milliliter portion of the wash shows 0.00 absorbance per centimeter path length between 280 m[MICRO] and 400 m[MICRO] when tested as prescribed under "Organic solvents." Usually three portions of wash solvent are sufficient.
Before proceeding with analysis of a sample, determine the absorbance in a 5-centimeter path cell between 250 millimicrons and 400 millimicrons for the reagent blank by carrying out the procedure, without a metal sample. The absorbance per centimeter path length should not exceed 0.02 in the wavelength range from 280 m[MICRO] to 400 m[MICRO].
Place 300 milliliters of dimethyl sulfoxide in a 1-liter separatory funnel and add 75 milliliters of phosphoric acid. Mix the contents of the funnel and allow to stand for 10 minutes. (The reaction between the sulfoxide and the acid is exothermic. Release pressure after mixing, then keep funnel stoppered.) Add 150 milliliters of isooctane and shake to pre-equilibrate the solvents. Draw off the individual layers and store in glass-stoppered flasks.
procedure
Sample. Select metal foil or sheet stock for the test which has not been previously contaminated by careless handling or exposure to atmospheric dust and fumes. A commercial coil in the form supplied for spindle mounting in a packaging line or wrapping machine is most suitable. Strip off the outside turn of metal and discard. Carefully avoid contamination or damage from handling the metal (wear gloves). Remove a 16-18-foot length from the coil and place it on a flat surface protected by a length of new kraft paper. Cut four 15-foot strips from the sample, each 3 inches wide (avoid tearing the edges of the strips). Using a piece of suitable glass rod, roll the strips of metal into loose coils and insert each into a Soxhlet thimble. Each turn of coil should be visibly separated from the adjacent turn.
Extraction. Fill each of the four Soxhlet tubes with purified isooctane (see under heading "Reagents and Materials," above) until siphon action occurs and then refill the tube body. Supply heat to the boiling flask and allow extraction to continue for at least 8 hours or until repeated weighings of the dried and cooled coil show no further weight loss.
Combine the isooctane extracts from the four Soxhlet units in a suitable beaker, rinsing each tube and flask into the beaker with fresh purified solvent. Evaporate the solvent under an atmosphere of inert gas (nitrogen) to residual volume of 50-60 milliliters and transfer this solution to a 500-milliliter separatory funnel containing 100 milliliters of pre-equilibrated sulfoxide-phosphoric acid mixture. Complete the transfer of the sample with small portions of pre-equilibrated isooctane to give a total volume of the residue and solvent of 75 milliliters. Shake the funnel vigorously for 2 minutes. Set up three 250-milliliter separatory funnels with each containing 30 milliliters of pre-equilibrated isooctane. After separation of liquid phases, carefully draw off lower layer into the first 250-milliliter separatory funnel and wash in tandem with the 30-milliliter portion of isooctane contained in the 250-milliliter separatory funnels. Shaking time for each wash is 1 minute. Repeat the extraction operation with two additional portions of the sulfoxide-acid mixture and wash each extractive in tandem through the same three portions of isooctane.
Collect the successive extractives (300 milliliters total) in a separatory funnel (preferably 2-liter) containing 480 milliliters of distilled water; mix, and allow to cool for a few minutes after the last extractive has been added. Add 80 milliliters of isooctane to the solution and extract by shaking the funnel vigorously for 2 minutes. Draw off the lower aqueous layer into a second separatory funnel (preferably 2-liter) and repeat the extraction with 80 milliliter of isooctane. Draw off and discard the aqueous layer. Wash each of the 80 milliliter extractives three times with 100-milliliter portions distilled water. Shaking time for each wash is 1 minute. Discard the aqueous layers. Filter the first extractive through anhydrous sodium sulfate pre-washed with isooctane (see sodium sulfate under "Reagents and Materials" for preparation of filter) into a 250-milliliter Erlenmeyer flask (or optionally into the evaporation flask). Wash the first separatory funnel with the second 80-milliliter isooctane extractive and pass through the sodium sulfate. Then wash the second and first separatory funnels successively with a 20-milliliter portion of isooctane and pass the solvent through the sodium sulfate into the flask. Add 1 milliliter of n-hexadecane and evaporate the isooctane on the steam bath under nitrogen. Discontinue evaporation when not over 1 milliliter of residue remains. To the residue, add a 10-milliliter portion of isooctane, reevaporate to 1 milliliter of hexadecane, and repeat this operation once.
Quantitatively transfer the residue with isooctane to a 25-milliliter volumetric flask, make to volume, and mix. Determine the absorbance of the solution in 5-centimeter pathlength cells compared to isooctane as reference between 280m[MICRO]-400m[MICRO] (take care to lose none of the solution in filling the sample cell). Correct the absorbance values for any absorbance derived from reagents as determined by carrying out the procedure without a metal sample. If the corrected absorbance does not exceed the limits prescribed in this paragraph, the residue meets the ultraviolet absorbance specifications.
List of substances | Limitations |
Acetyl tributyl citrate | |
Acetyl triethyl citrate | |
Butyl stearate | |
Castor oil | |
Dibutyl sebacate | |
Di(2-ethylhexyl) azelate | |
Di(2-ethylhexyl) sebacate | |
Diisodecyl phthalate | |
Dimethylpolysiloxane | Conforming to the identity prescribed in § 181.28 of this chapter. |
Dipropylene glycol | |
Epoxidized soybean oil | Conforming to the identity prescribed in § 181.27 of this chapter. |
Fatty acids derived from animal and vegetable fats and oils, and salts of such acids, single or mixed, as follows: | |
Aluminum | |
Magnesium | |
Potassium | |
Sodium | |
Zinc | |
Fatty alcohols, straight-chain with even number carbon atoms (C10 or greater) | |
Isobutyl stearate | |
Lanolin | |
Linoleic acid amide | |
Mineral oil | Conforming to the identity prescribed in § 178.3620 (a) or (b) . |
Mono-, di-, and tristearyl citrate | |
Oleic acid amide | |
Palmitic acid amide | |
Petrolatum | Conforming to the identity prescribed in § 178.3700 . |
Phosphoric acid, mono- and dihexyl esters, compounds with tetramethylnonylamines and C11-14-alkylamines (CAS Reg. No. 80939-62-4) | For use only at levels not to exceed 0.5 percent by weight of the finished surface lubricant formulation. |
Polyethylene glycol (molecular weight 300 or greater) | Mono- and diethylene glycol content not to exceed a total of 0.2 pct. |
Stannous stearate | |
Stearic acid amide | |
Stearyl stearate | |
Tetrakis[methylene (3,5-di-tert-butyl-4-hydroxyhydrocinnamate)] methane (CAS Registry No. 6683-19-8) | For use at a level not to exceed 0.5 percent by weight of the finished surface lubricant formulation. |
Triethylene glycol | Diethylene glycol content not to exceed 0.1 pct. |
Wax, petroleum | Complying with § 178.3710 . |
21 C.F.R. §178.3910