The Talalay process is a method of producing molded pieces of latex foam rubber. A liquid latex rubber base is introduced to a closed mold that has been vacuumed of air. The mold is then frozen to stabilize the cell structure. Carbon dioxide gas is introduced and the mold is heated to cure the rubber. Leon, Joseph and Anselm Talalay developed the “Talalay” process at various commercial entities. B.F. Goodrich in Shelton, Connecticut, Dunlopillo in Pannal, Harrogate, UK, and in Maastricht, Netherlands, made this process commercially practical in the late 1940s. The first Talalay production plants were built in England, Canada and the United States waterproof sack.
The Talalay process is an elaborate process that yields very controlled densities and product “feel”. The formulation uses many of the same base components as the Dunlop formulation, but without gellation reagents. The result is marketed as a healthier alternative to petroleum-based foams since petroleum-based foams give off volatile organic compounds as they age. In the marketing of products such as beds that include “natural” latex foams created with the Talalay process, these products are sometimes characterised as ‘organic’ or as completely natural. However this claim may not be completely true since unspecified curing agents are used in the Talalay process and ammonia is commonly used to stabilize liquid rubber.
The process utilizes a closed mold with pre-vacuum, followed by freezing to maintain uniform bubble geometry. Carbon dioxide (CO2) is flooded through the frozen, open foam matrix to form carbonic acid (CO2+H2O→ H2CO3). Much like the addition of sodium fluorosilicate (Na2SiF6) in the Dunlop process, the carbonic acid lowers the pH professional football jerseys, thereby causing gellation. In the next process step, vulcanization locks the foam into a uniform bubble distribution.
After the foamer aeration step, the compound is distributed into an opened mold in a precise volume and pattern. The Talalay type mold is designed to be closed and sealed with pressure provided by press hydraulics. After closing the mold, a vacuum is applied to the interior, thereby causing the air matrix bubbles to “inflate” and fill out the mold form.
While being supported by the vacuum, the mold and foam mass temperature is reduced to −20 °F (−28 °C) and frozen in place. Because the resultant foam matrix is open, carbon dioxide can be pushed through the structure, thereby forming carbonic acid that moves the pH from above 10 to 7. The reduction in alkalinity triggers the foam to gel in place and hold its shape.
The mold temperature can then be incrementally raised to the vulcanization temperature of 230 °F (115 °C) for a measured amount of time. At this point, the foam form can be de-molded and sent to a washing step. Typical molding cycles are 60 minutes unique football uniforms. After washing, the foam form is introduced into the vulcanizer stage to complete the cross-linking process. The final step is the drying process where residual moisture is driven off.