Sintering of HUST-1 lunar regolith simulant

W. Han, L. Ding, L. Cai, J. Zhu, H. Luo, T. Tang | 2022 | Construction and Building Materials

DOI 10.1016/j.conbuildmat.2022.126655

Review state

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Last reviewed

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Last approved reanalysis

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Summary

This paper investigates the sintering of HUST-1 lunar regolith simulant under atmospheric and vacuum conditions. It reports compressive strength, apparent density, and compactness values for sintered samples. The study explores the effects of temperature and pressure on the material's properties. The paper discusses the sintering behavior of lunar regolith simulant HANX2022X126655 under different heating conditions. It focuses on the effects of temperature and pressure on the densification and phase transformation of the simulant. The study aims to understand the sintering mechanisms and optimize the processing conditions for the production of structural materials from lunar regolith. The provided text contains a series of URLs pointing to image files (JPEG and GIF formats) hosted on an Amazon S3 bucket. These URLs are likely associated with figures or images from an academic or technical paper, as they include identifiers like 'gr1', 'gr2', etc., which may correspond to figure numbers. The URLs suggest that the content is related to research or documentation involving visual data, possibly in fields such as engineering, science, or technology. The provided text contains a mix of t

Connected extracted records

These are the records this paper contributes to the simulant, returned sample, method, and property browsers.

Used simulants

HUST-1

lunar regolith simulant

Needs review

100% confidencepage 1

HUST-1

Lunar Regolith Simulant

Needs review

95% confidencepage 8

MLS-1

sintering

Needs review

90% confidencepage 11

Returned samples

No returned samples extracted yet.

Experiments and measurements

PFUS Method

Compaction Technique

Needs review

Fig. 15 PFUS method, briquetting with 50kN force and sintering without mould.80% confidencepage 8

PFHS Method

Compaction Technique

Needs review

Fig. 18 PFHS method, compacting rough body with 20kN and sintering pressure with80% confidencepage 8

sintering of MLS-1

sintering

Needs review

electric furnace90% confidencepage 11

sintering of JSC-1AC

sintering

Needs review

microwave sintering90% confidencepage 12

microwave sintering of JSC-1AC

microwave sintering

Needs review

microwave sintering90% confidencepage 12

vacuum sintering

sintering

Needs review

vacuum furnace, 65 M-S-H-L, FESEM, temperature variation, compressive strength measurement100% confidencepage 2

Sintering of HUST-1 lunar regolith simulant

sintering

Needs review

XRF testing, high-temperature calcination, vacuum sintering, atmospheric sintering100% confidencepage 17

Mineralogical analysis

mineralogical analysis

Needs review

XRD, diffraction peak area, integral intensity100% confidencepage 17

Measured properties

Data Type

Image Data

Needs review

Content95% confidencepage 6

Hosting Service

Amazon S3

Needs review

Infrastructure90% confidencepage 5

SiO2

48.10%

Needs review

Oxide90% confidencepage 8

Al2O3

17.40%

Needs review

Oxide90% confidencepage 8

Fe2O3

Unknown

Needs review

Oxide80% confidencepage 8

CaO

Unknown

Needs review

Oxide80% confidencepage 8

MgO

Unknown

Needs review

Oxide80% confidencepage 8

Na2O

Unknown

Needs review

Oxide80% confidencepage 8

Methods and applications

Methods

sinteringtemperature controlpressure controldensity measurementstrength testingmicrostructure analysiscompaction analysismaterial characterizationHeating at different temperaturesApplication of pressureAnalysis of densification and phase transformationOptimization of processing conditionsURL ParsingPattern RecognitionData ClassificationAtmospheric SinteringVacuum SinteringPFUS MethodMFUS MethodMFHS MethodPFHS MethodRough Body FormingHot-Press Sinteringelectric furnaceatmospheric and vacuum sinteringmicrowave sinteringX-ray fluorescence (XRF)X-ray diffraction (XRD)field-emission scanning electron microscope (FESEM)differential scanning calorimetry (DSC)compression testingpycnometer methodXRFXRDXRF testinghigh-temperature calcinationdiffraction peak areaintegral intensityFESEM microscopic morphologiesEDX datavolume deformationpressure formingmould formingunconstrained sinteringdimensional analysismechanical testingdensity analysismicrostructural analysisHigh-temperature dielectric property analysisPorosity calculation using PRC National Standard methodsRietveld-RIR method for crystallinity analysisReaction kinetics studies for mineral synthesisPhysical and mechanical property analysis of lunar and martian regolith

Applications

space explorationlunar base constructionregolith utilizationmaterial science researchProduction of structural materials from lunar regolithDevelopment of processing techniques for lunar regolith simulantAcademic ResearchData AnalysisImage RetrievalLunar Regolith SimulantThermal ProcessingCompaction TechniquesMaterial ScienceIn Situ Resource Utilization (ISRU)Space Habitat Developmentlunar construction materialsin situ sintering technologysintering processlunar surface building materialsin-situ resource utilizationlunar surface manufacturingindustrial applicationscomplex shape moduleslunar regolith in situ construction materialsSpace exploration and in situ resource utilizationMaterial processing for lunar and martian constructionDevelopment of lunar soil simulants for researchAnalysis of physical and chemical properties of extraterrestrial materialsStudy of mineral synthesis and reaction kinetics