Developing Large Slab Airport Runways for the Next Century

2019 ◽  
Vol 2673 (6) ◽  
pp. 524-535
Author(s):  
Stephen J. Roswurm ◽  
Chris Ramseyer
Keyword(s):  
Drying Shrinkage ◽  
Early Age ◽  
Strain Gages ◽  
Vibrating Wire ◽  
Type K ◽  
Wire Strain ◽  
Load Cells ◽  
Mineral Additive ◽  
Shrinkage Compensation ◽  
Airport Runway

The purpose of this research was to determine whether shrinkage-compensating concrete (SCC) made with Type K cement can create durable airport runways with fewer joints and reduced maintenance costs. The primary criterion examined was the ability of SCC to offset the effects of early-age drying shrinkage when the concrete is acted upon by external restraint. The interaction of restraint with SCC is important because restraint resists the expansive behavior that provides shrinkage compensation. Four sets of experiments were conducted, with increasing levels of Type K expansive mineral additive in each set. A set of test specimens consisted of four-inch diameter restrained columns. Each set consisted of three columns with varying degrees of stiffness in the restraint frame, including low, medium, and high-restraint stiffness. The medium-restraint column provides the theoretical response of new pavement cast against a mature slab, whereas the other two bracket the problem. The column specimens were instrumented using vibrating wire strain gages, which were embedded in the concrete, and load cells, which were affixed to the top of the columns. This research concludes that SCC can be effective even with a stiff boundary condition, and that SCC provides the potential for much longer-lasting airport runway slabs, as a result of reduced shrinkage and therefore fewer cracks.

Early Age Behavior of Thin Porous Concrete Pavement for Bicycle Road due to Environmental Loading

2014 ◽  
Vol 1065-1069 ◽  
pp. 1981-1984
Author(s):  
Yoo Seok Jung ◽  
So Young Shin ◽  
Wu Guang Lin ◽  
Christopher Jabonero ◽  
Yoon Ho Cho
Keyword(s):  
Road Construction ◽  
Concrete Pavement ◽  
Standard Of Living ◽  
Early Age ◽  
Slab Thickness ◽  
Vibrating Wire ◽  
Joint Spacing ◽  
Porous Concrete ◽  
Wire Strain ◽  
Negative Effect

Due to the growing the standard of living, bicycle interest has increased which concerns a negative effect in transportation. Although, bicycle road construction is increasing continuously, distress problem is occurred by empirical design which is conventionally used. To determine the optimum joint spacing, thin porous concrete pavement was constructed and measured with vibrating wire strain gauges. Joint spacing is varied in 1.5m, 3.0m, 6.0m intervals, with slab thickness 7cm. Early age behavior of thin porous concrete pavement is measured. As expected, more restraint occurred at the longer slabs.

scholarly journals Application of Vibrating Wire Strain Gages for Evaluating Main Pipeline Stress-Strain State

2021 ◽  
Vol 137 (6) ◽  
pp. 57-61
Author(s):  
А. А. Ignatik ◽  
Keyword(s):  
Strain Gage ◽  
Strain State ◽  
Strain Gages ◽  
Vibrating Wire ◽  
Stress Strain ◽  
Stress Strain State ◽  
Wire Strain ◽  
Wire Method ◽  
Different Diameters ◽  
Longitudinal Strains

The use of anti-turbulent and depressant additives makes it possible to increase the efficiency of oil pipelines trThis article considers the physical basis of the vibrating wire method of monitoring the stress-strain state of the pipe walls. A laboratory experiment performed on a stand for measuring pipe strains during its bending by vibrating wire strain gages is described. The values of longitudinal strains obtained by vibrating wire and electrical strain gage methods are compared. The geometric task of determining the deflection of the strain gage wire when it is installed in the circumferential direction on pipelines of different diameters is solved in order to assess the reliability of the strain gage readings. The main points of the methodology for evaluating the stress-strain state of main pipelines by the vibrating wire method are considered and the classification of pipeline section functional state is proposed.

Improvements in Data Acquisition for Propulsion Shaft Alignment

2015 ◽  
Author(s):  
W. David Joiner ◽  
Charles J. Cook
Keyword(s):  
Data Acquisition ◽  
Strain Gage ◽  
Strain Gages ◽  
Construction Process ◽  
Crucial Step ◽  
Ship Construction ◽  
Shaft Line ◽  
Load Cells ◽  
Shaft Alignment

Propulsion shaft alignment is a necessary and crucial step in the ship construction process, with manning and schedule constraints requiring accurate results as efficiently as possible. There are two methods for measuring the bearing loading along the shaft line: strain gages and load cells. The legacy method for using strain gages required a lot of man power and the legacy method for using load cells was dependent on the quality of machinist made available. Strain gages are the transducers of choice for measurement; however the data acquisition, especially for ships with long shafting systems, can require many strain gage positions and personnel to conduct tests. Load cells are used to validate the accuracy of the strain gage method and to calculate the shaft runout at each bearing location.

Accounting for the transverse sensitivity of wire strain gages

1972 ◽  
Vol 15 (9) ◽  
pp. 1316-1318
Author(s):  
O. N. Ivanov ◽  
I. Kh. Sologyan ◽  
A. Kh. Baliullin ◽  
F. D. Chegolyaev
Keyword(s):  
Strain Gages ◽  
Transverse Sensitivity ◽  
Wire Strain

Evaluation of Negative Skin Friction on Bridge Abutment Piles

2021 ◽  
Vol 15 (2) ◽  
Author(s):  
Osama Drbe
Keyword(s):  
Skin Friction ◽  
Pore Water Pressure ◽  
Design Method ◽  
Water Pressure ◽  
Strain Gauges ◽  
Total Stress ◽  
Vibrating Wire ◽  
Negative Skin Friction ◽  
Drag Forces ◽  
Wire Strain

Piles are used to transfer loads of structures to deeper and stronger soil layers through skin friction and/or end bearing. Surcharge loads, site grading, or dewatering may induce downward movement of soil adjacent to piles installed in a compressible medium. This movement creates negative skin friction stresses acting downward at the pile-soil interface, which applies additional loads “drag forces” to the pile causing a maximum axial load in the pile shaft at the “neutral plane”. To evaluate the development of drag forces, a comprehensive field monitoring program was conducted over four years for three instrumented abutment H-piles as part of a three-span bridge project. The soil settlement and changes in pore water pressure in the soil adjacent to the piles due to the construction of an approach embankment were monitored using multiple-point extensometers and vibrating wire piezometers. The piles’ elastic settlement and strains were measured using single-point extensometers and vibrating wire strain gauges. The field measurements are presented and discussed in terms of responses time histories and load distribution along one pile shaft. In addition, the calculated forces from vibrating wire strain gauges are compared with the unified design method prediction considering the total stress method (α-method) for cohesive soils. The results show that the maximum drag force was developed after the complete dissipation of excess pore water pressure and that the location of neutral plane varied during the embankment construction stages. Employing the total stress method in the unified design method provided a reasonable prediction of the drag force and the neutral plane’s location.

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