Lauren E Cantley

20230020829, Jan 19, 2023

Jul 14, 2021

17/375182

- Cambridge MA, US
Kyle J. THOMPSON - Lynnfield MA, US
John CUMMINGS - Stoneham MA, US
Jacob Lazer ADAMS - McLean VA, US
Lauren CANTLEY - Cambridge MA, US

F28F 1/02
B29C 55/22

Drawn polymer fibers have internal channels running, at least partially, through the length of the fibers. These fibers may be configured to for use as thermal isolators that can thermally isolate material at the central core of the fiber from the outside environment. In such instances, the channels may be used as insulating channels and/or a heating or cooling fluid can be pumped through the channels to maintain the temperature of the material at the inner core. As another application, the fibers may be used as recuperative, regenerative, parallel-flow, counter-flow, cross-flow or condenser/evaporator heat exchangers. In this case, the channels may be used to direct fluid flow. The fiber may allow for the exchange of heat between fluids in the channels.

20210362396, Nov 25, 2021

Apr 21, 2021

17/236351

- Cambridge MA, US
Kristina McCarthy - Oxford MA, US
Kristen Mulherin - Newton MA, US
Jimmy Nguyen - Lowell MA, US
Michael Rein - Boston MA, US
Matthew Bernasconi - Concord MA, US
Lauren Cantley - Cambridge MA, US
Lalitha Parameswaran - Billerica MA, US
Michael Rickley - Reading MA, US
Alexander Stolyarov - Belmont MA, US

B29C 51/00
D01D 5/00
B29D 11/00
B29D 99/00
B29C 51/12

Methods of manufacturing multi-material fibers having one or more electrically-connectable devices disposed therein are described. In certain instances, the methods include the steps of: positioning the electrically-connectable device(s) within a corresponding pocket provided in a preform material; positioning a first electrical conductor longitudinally within a first conduit provided in the preform material; and drawing the multi-material fiber by causing the preform material to flow, such that the first electrical conductor extends within the multi-material fiber along a longitudinal axis thereof and makes an electrical contact with a first electrode located on each electrically-connectable device. A metallurgical bond may be formed between the first electrical conductor and the first electrode while drawing the multi-material fiber and/or, after drawing the multi-material fiber, the first electrical conductor may be located substantially along a neutral axis of the multi-material fiber.

20210055228, Feb 25, 2021

Aug 21, 2020

16/999667

- Cambridge MA, US
Alexander Stolyarov - Belmont MA, US
Shane Tysk - Arlington MA, US
Lauren Cantley - Cambridge MA, US

G01N 21/78
G01N 21/31

Techniques are disclosed for a chemical sensor architecture based on a fabric-based spectrometer. An example apparatus implementing the techniques includes a portable spectrometer device including a first fabric layer and a second fabric layer coupled to the first fabric layer to form a pouch. The second fabric layer includes a fiber fabric spectrometer substrate comprising a fiber material including one or more electronic devices, wherein the pouch is configured to receive a colorimetric substrate and the fiber fabric spectrometer substrate is configured to measure reflectance of a colorimetric substrate disposed in the pouch.