J. Chen scite author profile

A novel patented process and several reactors have been developed for devulcanization of waste rubbers. The technology is based on the use of the high power ultrasonics. The ultrasonic waves of certain levels in the presence of pressure and heat rapidly break up the three-dimensional network in crosslinked rubbers. The devulcanized rubber can be reprocessed, shaped and revulcanized in much the same way as a virgin rubber. The first laboratory reactor has been scaled up to pilot-plant level by the National Feedscrew and Machining, Inc. Various devulcanization experiments were carried out with model styrene-butadiene rubber (SBR) and with ground rubber tire (GRT). Curing behavior, Theological properties, and structural characteristics of rubbers devulcanized at various processing conditions were studied, as well as mechanical properties of revulcanized rubber samples. A possible mechanism of the devulcanization is discussed. The performed measurements indicate that the rubbers are partially devulcanized, and the devulcanization process is accompanied by certain degradation of the macromolecular chains. In spite of these observations, the processing conditions are identified at which the retention of the mechanical properties is found to be good. A further work is in progress to find the optimal conditions of devulcanization and to improve the selectivity of the process towards breaking up the chemical network only.

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Ultrasonic devulcanization of rubber vulcanizates. II. Simulation and experiment

Isayev

Yushanov

Chen

1996

J. Appl. Polym. Sci.

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Ultrasonic devulcanization of rubber vulcanizates. I. Process model

Isayev

Yushanov

Chen

1996

J of Applied Polymer Sci

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Some evidence against the existence of the liquid‐liquid transition. III. The evaluation of the T_ll event by differential scanning calorimetry

Chen

Kow

Fetters

et al. 1982

J. Polym. Sci. Polym. Phys. Ed.

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A Convenient Synthesis of Dimethylphosphinyl Acetic Acid

Chen

Calvo

1991

Phosphorus, Sulfur, and Silicon and the Related Elements

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J. Chen

Novel Ultrasonic Technology for Devulcanization of Waste Rubbers

Ultrasonic devulcanization of rubber vulcanizates. II. Simulation and experiment

Ultrasonic devulcanization of rubber vulcanizates. I. Process model

Some evidence against the existence of the liquid‐liquid transition. III. The evaluation of the T_ll event by differential scanning calorimetry

A Convenient Synthesis of Dimethylphosphinyl Acetic Acid

Contact Info

Product

Resources

About

J. Chen

Novel Ultrasonic Technology for Devulcanization of Waste Rubbers

Ultrasonic devulcanization of rubber vulcanizates. II. Simulation and experiment

Ultrasonic devulcanization of rubber vulcanizates. I. Process model

Some evidence against the existence of the liquid‐liquid transition. III. The evaluation of the Tll event by differential scanning calorimetry

A Convenient Synthesis of Dimethylphosphinyl Acetic Acid

Contact Info

Product

Resources

About

Some evidence against the existence of the liquid‐liquid transition. III. The evaluation of the T_ll event by differential scanning calorimetry