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An inhibitor package which is silicate-, nitrate-, borate- and phosphate-free has been developed as the basis for a world-wide automotive coolant formulation. The formulation contains aliphatic mono- and dicarboxylic acids and tolyltriazole as the sole inhibitors. Formulations containing carboxylic acid inhibitors have been studied in ASTM bench tests and found to sufficiently protect all prevalent cooling system metals. In addition, fleet tests have shown that carboxylic acid inhibitors deplete much more slowly than conventional inhibitors, making possible a much longer life coolant. Results from laboratory tests which simulate extended usage indicated that carboxylic acid-containing coolants have a significantly longer life span for the protection of all cooling system metals. Finally, the carboxylic acid/tolyltriazole inhibitor package is completely adaptable to a propylene glycol base.

The effect of small amounts of silicate on coolant performance has been studied. The corrosion protection provided by different coolant technologies was evaluated for different silicate contents. This work includes results from electrochemical tests and static and dynamic heat-rejecting tests on aluminum surfaces. The results indicate that small amounts of silicate have a negative effect on the corrosion protection of aluminum. Depletion of silicates can therefor be expected to affect aluminum heat-rejecting surfaces. The use of carboxylic acid corrosion inhibitors can overcome this problem.

Automobile coolant pump failure rates have been observed to be influenced by the coolant inhibitor package. A fleet test consisting of 196 1991 Ford Crown Victoria taxi cabs was utilized to test six coolant formulations. Four of the test formulations were monobasic/dibasic organic acid technology coolants and two were traditional technology coolants containing nitrate, phosphate, and silicate. Coolant pump failure rates were monitored as a function of mileage. Results indicate that the service life of coolant pumps for those systems employing organic acid technology coolants was significantly greater than those systems utilizing traditional inhibitor technology coolants.

Field-test samples cut from radiator tubes in two 1990 Chevy Luminas (3.1L engine) after 100,000 miles were analyzed to determine corrosion layer differences. One car used a carboxylic acid-based inhibitor technology (C1). The other car used a conventional coolant (C2). X-ray photoelectron spectroscopy (XPS) analysis of the two samples was performed. Results indicate a significant difference between the two samples. The C1 sample had a thin (<60Å) organic coating bound to the aluminum alloy surface, while the C2 sample had a much thicker (>1000 Å) silicate-rich layer. This resulted in the C2 sample exhibiting “surface charging” behavior. These results relate directly to the metal/insulator (conductor/insulator) characteristics of the two samples, and imply that the heat transfer of the protective coating provided by the carboxylate technology (C1) is significantly better than that of traditional inhibitor technology (C2).