Effect of Additives on Liner Properties of Case-bonded Composite Propellants

Navale, S. B.; Sriraman, S.; Wani, Vilas; Manohar, Murli; Kakade, S. D.

doi:10.14429/dsj.54.2049

Cited by 15 publications

(7 citation statements)

References 2 publications

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“…However, the interaction between various factors is yet to be studied. Experimental results indicate that the failure is either the cohesive within the propellant near the interface or the adhesive fracture [13,15,19]. The former type is exactly what we expect since it indicates a strong adhesive bonding.…”

Section: Measurement Of Adhesive Propertiesmentioning

confidence: 66%

“…Later, Yin and Wang [17] reviewed the influence factors, in terms of insulation, liner, propellant, and manufacturing process. Since then, more in-depth investigations still focus on the mechanical and adhesive characteristics of the liner due to the effect of particle size of ammonium perchlorate (AP) [18], additives [19], ingredient migration [20], humidity [21] and curing state of liner [22]. By now, the impact of an individual factor has been investigated comprehensively.…”

Section: Measurement Of Adhesive Propertiesmentioning

confidence: 99%

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Review of the Adhesively Bonded Interface in a Solid Rocket Motor

Zhou

Chen

et al. 2015

The Journal of Adhesion

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One of the most challenging requirements in a solid rocket motor (SRM) is the integrity of the charge structure which is a multilayer adhesive joint involving the propellant, liner, and insulation. The propellant/liner/insulation interface is considered to be the weakest part of the whole structure. This interface has some of the usual features of an adhesively bonded interface, as well as its own special characteristics: the co-cured process, ingredient migration between interfaces, and complicated damage mechanisms. We give a technical and critical review of the past fifty years of existing research on many aspects of the propellant/liner/insulation interface in terms of the adhesive properties and adhesive mechanisms, ingredients migration, damage determination, and fracture analysis.To present a comprehensive outline of this interface we also clarify some remaining problems which should be addressed in the future. With significant improvements in the theoretical and experimental studies of the propellant/liner/insulation interface, the problem of integrity failure of the charge structure in SRM will be well resolved. Downloaded by [Cambridge University Library] at 07:15 14 August 2015 2

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Section: Measurement Of Adhesive Propertiesmentioning

confidence: 66%

Section: Measurement Of Adhesive Propertiesmentioning

confidence: 99%

Review of the Adhesively Bonded Interface in a Solid Rocket Motor

Zhou

Chen

et al. 2015

The Journal of Adhesion

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“…The safety of hydroxyl‐terminated polyether (HTPE) propellant with nitroglycerin (NG) replaced by N‐butyl‐N‐nitratoethyl nitramine (NENA) has been greatly improved, but the problems of interfacial adhesion in such charge structure still remain, because of the large polarity difference between the propellant/liner. Maintaining the structural integrity of charge is one of the most challenging issue in SRMs 3–5 . Currently, about one‐third of solid rocket launch accidents are caused by the debonding of the charge structure interfaces, and the integrity of the charge structure has become the main technical bottleneck restricting the development of SRM technology.…”

Section: Introductionmentioning

confidence: 99%

“…Previously, scholars have proposed several strategies to improve the interfacial adhesion properties and inhibit the migration of plasticizers, and have set up related theoretical models 18 . For example, some scholars 4 improved the bonding performance by using the same binder as the propellant as the lining material, but at the same time this led to enhanced migration of plasticizer. Others 19,20 tried to reduce the diffusion coefficient by modifying the molecular structure of plasticizer, but it also decreased the plasticization efficiency and adversely affected other properties of the propellant.…”

Section: Introductionmentioning

confidence: 99%

Preparation of anti‐migration transition layer and its application in cast‐in‐case solid rocket motors

Zhang

et al. 2021

J of Applied Polymer Sci

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The polyester‐based transition layers were first synthesized with poly (diethylene glycol adipate), glycerin, and toluene diisocyanate. Then they were coated between the propellant and the liner to improve the bonding performance of the charge and inhibit the migration of the energetic plasticizer in the propellant. The effects of R value (the ratio of the quantity of isocyanate functions NCO with respect to the quantity of hydroxyl functions OH) on migration resistance and bonding performance were also studied. The overall performance was optimized at R = 1.5: after the transition layer was applied, the binding strength was greatly increased from 0.14 to 0.64 MPa, which had good application prospects. Meanwhile, due to the strong interactions between the polar ester groups and N‐butyl‐N‐nitratoethyl nitramine (NENA) in the transition layers, the portion of NENA migrating into liners were reduced from 7.6% to 6.0% (reduced by 21%), indicating that the introduction of polyester transition layers could significantly improve the anti‐migration effect. The activation energies of migration for NENA in the transition layers were about 66.3 ~ 94.3 kJ/mol, which were equivalent to the value of strong hydrogen bonding.

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“…It was found that, many factors affect the interfacial bonding property between liner and propellant [5]. Among those factors, heat insulation layer is the major factor effecting the bonding property [6]. The insulation layer contains active groups, such as hydroxyl groups that can adsorb water molecules and at the same time can absorb isocyanate compounds [7,8].…”

Section: Introductionmentioning

confidence: 99%

Effect of Insulation Layer Composite and Water Adsorption on Bonding Performance in Heat Barriers

Awad

Nasser

2020

Adv. J. Chem. A

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Thermal insulation layer in solid rocket motors is a vital component during the rocket flight. Many factors can affect the performance of this insulation layer. Bonding property between rocket propellant and the thermal insulation layer are examined in this study. Hydroxyl terminated polybutadiene (HTPB) and isophorone diisocyanate (IPDI) as a curative was chosen as the most common type of rocket propellant. The effect of two types of polymeric insulation layer such as nitrile butadiene rubber (NBR) and ethylene-propylene-diene monomer (EPDM), on the bonding performance at the interface between (HTPB/IPDI) propellant and the respective insulation layer has been investigated. Results revealed that both types of insulation layer considerably decreased the interfacial bonding performance of the (HTPB/IPDI) propellant. NBR was proven to be more severe on weakening the adhesion strength than that of the EPDM. We further investigated the effects of the thickness and water content of NBR on the bonding performance, and proved that bonding strength was inversely proportional to the thickness and the water content.

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Effect of Additives on Liner Properties of Case-bonded Composite Propellants

Cited by 15 publications

References 2 publications

Review of the Adhesively Bonded Interface in a Solid Rocket Motor

Review of the Adhesively Bonded Interface in a Solid Rocket Motor

Preparation of anti‐migration transition layer and its application in cast‐in‐case solid rocket motors

Effect of Insulation Layer Composite and Water Adsorption on Bonding Performance in Heat Barriers

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