Dale F Taylor

Title: Innovations of Dale F. Taylor in Zirconium Alloy Technology

Introduction

Dale F. Taylor is a prominent inventor based in Schenectady, NY. With an impressive portfolio of 20 patents, she has made significant contributions to the field of materials science, specifically focusing on enhancing the properties of zirconium alloys. Her work is pivotal in industries that rely on the resilience and performance of materials, particularly in extreme environments.

Latest Patents

One of Dale F. Taylor's latest patents, titled "Protective Coarsening Anneal for Zirconium Alloys," describes a method aimed at increasing the resistance of zirconium alloy tubing to nodular corrosion. This involves applying a protective anneal at a specific temperature range, which is crucial for maintaining the integrity of zirconium alloy tubing under harsh conditions. The patented method specifies the lower temperature limit (T) at approximately 840°C, which is necessary to achieve a critical concentration of solute in the alpha-matrices of the alloy. The upper limit is identified as approximately 855°C, beyond which precipitates may compromise the alloy’s structural integrity. This innovation is particularly relevant for Zircalloy-2, which is composed of zirconium and other metals such as tin, iron, chromium, and nickel.

Career Highlights

Dale F. Taylor's extensive career at the General Electric Company has been marked by her focus on advancing materials technology. Over the years, her inventive spirit and technical expertise have led to numerous innovations designed to solve specific challenges within the industry. Her contributions not only highlight her individual capabilities but also demonstrate her vital role within a company renowned for its commitment to technological advancement.

Collaborations

Throughout her career, Dale has collaborated with esteemed colleagues, including Louis S. Sammler and John S. Sicko. These partnerships reflect a collaborative approach to innovation, reinforcing the importance of teamwork in achieving sustainability and performance improvements in engineering applications. Working alongside such talented professionals has enabled her to enhance her designs and develop more robust solutions for complex material challenges.

Conclusion

Dale F. Taylor's work in the field of zirconium alloys is a testament to her innovative mindset and dedication to invention. Her latest advancements, particularly in the protective annealing methods for zirconimum alloy tubing, underscore her significant impact on materials science. As the industry continues to benefit from her discoveries, it becomes clear that Dale F. Taylor will remain a key figure in the evolution of engineering solutions.