00822767

Component

https://doi.org/10.3141/1775-02

http://scholar.google.com...ston&publication_year=2001

Fracture surface scanning electron microscopy (SEM), X-ray microcomputed tomography (X-ray CT), microhardness testing, contact angle goniometry, and foam drainage testing were used to investigate the cause of low compressive strength concrete in South Dakota. SEM indicated that air voids were collecting in the vicinity of aggregate surfaces. These voids reduced the area over which stress could be transferred from the paste to the aggregate. Also, SEM showed that paste between the air voids was of poor quality. X-ray CT corroborated the SEM findings concerning the air void distribution, whereas microhardness testing indicated that the paste in higher-strength samples was three times as hard as the paste in low-strength samples. Air bubbles may attach to the aggregate surfaces due to the aggregate becoming hydrophobic when air-entraining admixtures were used in the concrete. Contact angle goniometry confirmed this phenomenon as model aggregate surfaces had contact angles between 10 and 40 deg for all admixtures tested, and model aggregate treated with vinsol resin-based air-entraining agents exhibited significantly lower (by 5 to 20 deg) contact angles. Finally, examination of three-phase foams produced by mixing cement, air-entraining admixture, and water showed that vinsol resin-based foams had larger bubble sizes and kept more water within the foam than did nonvinsol resin-based admixtures.

This paper appears in Transportation Research Record No. 1775, Concrete 2001.

English

p. 10-16

2001

Transportation Research Record

0309072395

Figures (7) ; Photos (1) ; References (11) ; Tables (3)

Admixtures; Air entrained concrete; Air entraining agents; Air voids; Bubbles; Compressive strength; Concrete; Concrete hardening; Electron microscopy; Foams; Hardness tests; Tomography; Water in concrete; X rays

Contact angle goniometry; Foam drainage tests; Scanning electron microscopy; X-ray computed tomography

South Dakota

Highways; Materials; I32: Concrete

TRIS, TRB, ATRI

Jan 31 2002 12:00AM

• APPLICATION OF THE DEFORMATION MAPPING TECHNIQUE TO ASSESS DETERIORATION IN CEMENT-BASED MATERIALS
• BACKSCATTERED ELECTRON IMAGING TO DETERMINE WATER-TO-CEMENT RATIO OF HARDENED CONCRETE
• CONCRETE MATURITY PROGRESS: SURVEY OF DEPARTMENTS OF TRANSPORTATION
• CONCRETE PLASTIC SHRINKAGE-REDUCTION POTENTIAL OF SYNERGY FIBERS
• CONCRETE ROUGHNESS CHARACTERIZATION USING LASER PROFILOMETRY FOR FIBER-REINFORCED POLYMER SHEET APPLICATION
• EVALUATION OF HIGH-PERFORMANCE CONCRETE PAVEMENT IN NEWPORT NEWS, VIRGINIA
• HARDENED CONCRETE AIR VOID ANALYSIS WITH A FLATBED SCANNER
• INFLUENCE OF CHLORIDE PERMEABILITY TEST PARAMETERS ON RESULTS FOR SILICA FUME AND NONSILICA FUME CONCRETE
• LABORATORY TESTING, DATA ANALYSIS, AND INTERPRETATION PROCEDURES FOR DISTRESSED CONCRETE PAVEMENTS
• LIGHTWEIGHT FLY ASH-PLASTIC AGGREGATES IN CONCRETE
• MICHIGAN'S APPROACH TO A STATEWIDE INVESTIGATION OF MATERIALS-RELATED DISTRESS IN CONCRETE PAVEMENTS
• PERFORMANCE CHARACTERISTICS OF SYNERGY FIBER-REINFORCED CONCRETES: STRENGTH AND TOUGHNESS PROPERTIES
• PERMEABILITY PERFORMANCE OF HIGH-PERFORMANCE CONCRETE SUBJECTED TO VARIOUS CURING REGIMES
• PETROGRAPHIC ANALYSIS OF CONCRETE DETERIORATION BY FEATURE RELOCATION
• ROLLER-COMPACTED FIBER CONCRETE PAVEMENT FOUNDATION WITH RECYCLED AGGREGATE AND WASTE PLASTICS