Studies On HTPB Based Copolyurethanes As Solid Propellant Binders : Characterization And Modeling Of Network Parameters

Sekkar, V

11 1900

No description available.

Solid Propellants

Copolyurethanes - Binders (Material)

Hydroxyl Terminated Polybutadiene

Rocket Propellants

Polymeric Binders

HTPB

Polyurethane Network

Astronautics

Raman Characterization of Elastomeric Materials

Drake, Shane Michael

11 December 2024

Raman spectroscopy is often used for material identification but may be used for characterization. This document focuses on using Raman measurements to characterize polymers, specifically the curing and aging mechanism for hydroxyl-terminated polybutadiene (HTPB). HTPB is a well-known elastomer used in sealants, non-slip surfaces, rocket repellants and plastic explosives. Raman spectroscopy was used to monitor urethane linkages that form from curing HTPB with a cyanate curing agent to suggest a curing mechanism for HTPB. Since this polymer is highly susceptible to oxidation, the methods used to characterize curing were also used for the aging process to see if urethane breakages could be observed. Raman measurements were compared to elongation-at-break measurements to assess the short-term aging process. Results showed that oxidation of the urethane linkage seemed to be the primary source of degradation during early thermal aging. Patterns seen in Raman data may be studied to suggest an oxidation mechanism at the urethane site as a starting point to unravel the network of aging mechanisms for HTPB. Additionally, a recently published mount design is discussed for sustained tensile strain. The mount setup was used to mechanically extend samples while taking real-time spectroscopic data. Testing for the mount was done on HTPB and high-density polyethylene, but the design may accommodate a large variety of materials and is compatible with many spectroscopic methods including Raman spectroscopy.

Raman spectroscopy

hydroxyl-terminated polybutadiene

HTPB

cyanate

polymer

oxidation

elastomer

solid-state fuel

Physical Sciences and Mathematics

IMPACT BEHAVIOR OF AMMONIUM PERCHLORATE (AP) - HYDROXYL-TERMINATED POLYBUTADIENE (HTPB) COMPOSITE MATERIAL

Saranya Ravva (15353902)

25 April 2023

<p>This work investigated the effects of varying the crystal sizes of ammonium perchlorate (AP) when embedded with a polymeric binder, hydroxyl-terminated polybutadiene (HTPB) on impact-induced temperature behavior.  AP and HTPB are the most used oxidizers and fuel binders in the aerospace solid rocket design industry. In this study, samples of 200 µm and 400µm coarse AP crystals in HTPB were constructed using a conventional hand-mixing method. Using a parametric optimization technique such as the Taguchi method, direct-ink-writing as the additive manufacturing process was used for achieving the required shape fidelity in printing HTPB and by introducing ultraviolet polymers to decrease the curing time.</p> <p>A drop hammer experiment in conjunction with an infrared camera was used to study the impact-induced behavior in the conventionally made AP-HTPB samples. The thermal images obtained from the camera at millisecond resolution are invaluable and provide information about distribution across the sample surface, and the evolution of temperature rise observed in the samples which are complex and not easily understood otherwise and therefore help in improving and attaining desired propellant performance. A two-sample t-Test has been utilized to infer the results and statistical nonsignificance has been observed in the highest temperature rises among 200 µm and 400 µm AP-HTPB sample conditions but a difference in temperature distribution has been observed. A much uniform distribution of temperature over the sample surface on impact is observed in thermal images of 200 µm AP-HTPB sample condition compared to 400 µm AP-HTPB sample condition.</p>

Aerospace materials

Aerospace structures

Additive manufacturing

Composite and hybrid materials

Ammonium Perchlorate (AP)

Hydroxyl-Terminated Polybutadiene (HTPB)

Impact Testing

Aerospace Engineering

Additive Manufacturing

Direct Ink Writing

Parametric Optimization

Taguchi Method

Drop Hammer Impact

IR camera

Solid Rocket Propellant

APCP

T-test p-value

Aerospace Materials