Patents by Inventor Eric B. HOSTETLER

Eric B. HOSTETLER has filed for patents to protect the following inventions. This listing includes patent applications that are pending as well as patents that have already been granted by the United States Patent and Trademark Office (USPTO).

  • Patent number: 12155036
    Abstract: Methods of reducing acid stratification with an acid-soluble and acid-stable polymer with a high molecular weight are disclosed herein. Electrolytes and separators for an energy storage device are disclosed herein. The separator includes a coating containing an acid-soluble and acid-stable polymer with a high molecular weight. The electrolyte includes sulfuric acid and an acid-soluble and acid-stable polymer with a high molecular weight. Methods of making the separators disclosed herein and methods of making batteries are also disclosed herein.
    Type: Grant
    Filed: December 12, 2023
    Date of Patent: November 26, 2024
    Assignee: Amtek Research International LLC
    Inventors: Daniel Wandera, Robert Waterhouse, Wyatt Self, Eric B. Hostetler, Richard W. Pekala
  • Publication number: 20240222702
    Abstract: Methods of reducing acid stratification with an acid-soluble and acid-stable polymer with a high molecular weight are disclosed herein. Electrolytes and separators for an energy storage device are disclosed herein. The separator includes a coating containing an acid-soluble and acid-stable polymer with a high molecular weight. The electrolyte includes sulfuric acid and an acid-soluble and acid-stable polymer with a high molecular weight. Methods of making the separators disclosed herein and methods of making batteries are also disclosed herein.
    Type: Application
    Filed: December 12, 2023
    Publication date: July 4, 2024
    Inventors: Daniel Wandera, Robert Waterhouse, Wyatt Self, Eric B. Hostetler, Richard W. Pekala
  • Publication number: 20240207790
    Abstract: An environmentally friendly closed loop manufacturing process (101, 102) produces microporous membranes (32) by cast or extrusion of polymer-plasticizer mixtures followed by non-porous film formation (20), extraction (22) of the plasticizer using an azeotrope solvent and thereby forming a solvent-laden sheet and a mixture of plasticizer and azeotrope solvent, distillation (28) of the mixture to separate the plasticizer and azeotrope solvent for reuse, evaporation (30) of the azeotrope solvent from the solvent-laden sheet to form the micropores, and capture of the resultant solvent vapor for subsequent adsorption-desorption of the azeotrope solvent from activated carbon (34) or by vapor condensation (36) for reuse in the manufacturing process. The azeotrope solvent is at least a two-component mixture of solvents, one of which is designed for efficient removal of the plasticizer, while the other component(s) render(s) the azeotrope solvent non-flammable.
    Type: Application
    Filed: June 10, 2022
    Publication date: June 27, 2024
    Inventors: Robert Waterhouse, Cory S. Rogers, Eric B. Hostetler, Richard W. Pekala
  • Patent number: 11894517
    Abstract: Methods of reducing acid stratification with an acid-soluble and acid-stable polymer with a high molecular weight are disclosed herein. Electrolytes and separators for an energy storage device are disclosed herein. The separator includes a coating containing an acid-soluble and acid-stable polymer with a high molecular weight. The electrolyte includes sulfuric acid and an acid-soluble and acid-stable polymer with a high molecular weight. Methods of making the separators disclosed herein and methods of making batteries are also disclosed herein.
    Type: Grant
    Filed: November 9, 2020
    Date of Patent: February 6, 2024
    Assignee: Amtek Research International LLC
    Inventors: Daniel Wandera, Robert Waterhouse, Wyatt Self, Eric B. Hostetler, Richard W. Pekala
  • Publication number: 20210265660
    Abstract: Methods of reducing acid stratification with an acid-soluble and acid-stable polymer with a high molecular weight are disclosed herein. Electrolytes and separators for an energy storage device are disclosed herein. The separator includes a coating containing an acid-soluble and acid-stable polymer with a high molecular weight. The electrolyte includes sulfuric acid and an acid-soluble and acid-stable polymer with a high molecular weight. Methods of making the separators disclosed herein and methods of making batteries are also disclosed herein.
    Type: Application
    Filed: November 9, 2020
    Publication date: August 26, 2021
    Inventors: Daniel Wandera, Robert Waterhouse, Wyatt Self, Eric B. Hostetler, Richard W. Pekala
  • Patent number: 10199692
    Abstract: Proton-conducting gel electrolytes with acid immobilized within a covalently cross-linked polymer network and composites containing the gel electrolytes provide low ionic resistance, minimize acid stratification, and prevent dendrite growth. The gel electrolytes can be formed from monomers dissolved in concentrated sulfuric acid and subsequently covalently cross-linked between the battery electrodes, or the covalently cross-linked gel electrolytes can be formed in water and subsequently exchanged into sulfuric acid. The mechanical properties of these gels can often be enhanced with the addition of silica powder, silica fiber, or other additives. In some cases, the covalently cross-linked gel electrolytes are formed in the presence of a conventional silica-filled polyethylene separator or within a low density fiber mat to provide mechanical reinforcement and controlled spacing between the battery electrodes.
    Type: Grant
    Filed: November 15, 2016
    Date of Patent: February 5, 2019
    Assignee: AMTEK RESEARCH INTERNATIONAL LLC
    Inventors: Jungseung Kim, Robert R. Waterhouse, Richard W. Pekala, Eric B. Hostetler
  • Publication number: 20170133720
    Abstract: Proton-conducting gel electrolytes with acid immobilized within a covalently cross-linked polymer network and composites containing the gel electrolytes provide low ionic resistance, minimize acid stratification, and prevent dendrite growth. The gel electrolytes can be formed from monomers dissolved in concentrated sulfuric acid and subsequently covalently cross-linked between the battery electrodes, or the covalently cross-linked gel electrolytes can be formed in water and subsequently exchanged into sulfuric acid. The mechanical properties of these gels can often be enhanced with the addition of silica powder, silica fiber, or other additives. In some cases, the covalently cross-linked gel electrolytes are formed in the presence of a conventional silica-filled polyethylene separator or within a low density fiber mat to provide mechanical reinforcement and controlled spacing between the battery electrodes.
    Type: Application
    Filed: November 15, 2016
    Publication date: May 11, 2017
    Inventors: Jungseung KIM, Robert R. WATERHOUSE, Richard W. PEKALA, Eric B. HOSTETLER