Full-scale Test on Emergency Repair Pavement under Airplane Loading

In order to reveal structural response law of emergency repair pavement under the airplane loading and verify the backfill material and structural applicability, two craters (Crater 1 composed of 2.4 m thick flying objects (FO) + 0.4 m thick graded crushed rocks (GCR) + 0.2 m thick roller compacted concrete + fibre reinforced plastic (FRP) course, and Crater 2 composed of 2.4 m thick FO + 0.6 m thick GCR + FRP course) were backfilled. Static and dynamic loads were applied using two airplanes. Results show that, laying FRP pavement layers reduced the maximum deflection of Crater 2 by 21%. Crater 1 and concrete pavement were both slightly rigid structures with a strong load transfer ability. The dynamic deflection basin curves of Crater 2 could be fit using a Gaussian function; while the curves of Crater 1 and concrete pavement could be fit using a quartic polynomial. Under static loading, the earth pressures of Crater 2 at −0.6 m, −0.4 m, and −0.2 m sites were 4.3, 9, and 9.6 times of those of Crater 1, respectively. At the −0.2 m site, the earth pressure of Crater 1 was 0.11 MPa, while that of Crater 2 reached 1.06 MPa. The research results can guide the rapid quality inspection and optimization design of emergency repair pavement structure and material.

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Performance Simulation Analysis and Design of the Scale Model for the Earth Pressure Balance Shield

Advanced Materials Research ◽

10.4028/www.scientific.net/amr.346.364 ◽

2011 ◽

Vol 346 ◽

pp. 364-371 ◽

Cited By ~ 1

Author(s):

Xu Chen ◽

Zhu Feng Shao ◽

Xiao Qiang Tang ◽

Ping Fa Feng

Keyword(s):

Optimization Design ◽

Driving Forces ◽

Simulation Analysis ◽

Earth Pressure ◽

Scale Model ◽

Pressure Balance ◽

Analysis And Design ◽

The Earth ◽

Earth Pressure Balance ◽

Epb Shield

Referring to the Earth Pressure Balance (EPB) shield with the diameter of 6.25m, a new experiment station of EPB shield is proposed, which is loaded with mechanical structure instead of traditional soil box. The structure of the experiment model is designed for the performance analysis of the EPB shield. The mechanical loading device, which is called the soil simulator, can simulate different geological environments. The soil simulator is capable of realizing three work states, such as earth balance pressure, earth under pressure, and earth over pressure. By adopting virtual prototype technology, parametric model of the shield station is established and the co-simulation scheme is determined. Besides, the kinematic analysis as well as variation principles between the displacement and driving forces of the propulsion system are obtained, which build the foundation for optimization design and control of the shield prototype.

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Characterization of Underlying Twin Shield Tunnels Due to Foundation-Excavation Unloading in Soft Soils: An Experimental and Numerical Study

Applied Sciences ◽

10.3390/app112210938 ◽

2021 ◽

Vol 11 (22) ◽

pp. 10938

Author(s):

Xiaodong Cheng ◽

Tianqiu Hong ◽

Zhitang Lu ◽

Xiaochun Cheng

Keyword(s):

Numerical Study ◽

Structural Response ◽

Earth Pressure ◽

Experimental Tests ◽

Foundation Pit ◽

Soft Soils ◽

Numerical Studies ◽

The Earth ◽

Depth Ratio ◽

Side Walls

Excavation near or above existing shield tunnels often results in adverse impacts on tunnel stability. To ensure the serviceability of existing tunnels, this paper presents experimental and numerical studies with reference to a foundation pit case history excavated above twin-tube shield tunnels in soft soils. The experimental tests were firstly applied to study the deformation characteristics and structural response of the shield tunnels. Thereafter, an extensive numerical investigation was performed to determine the influence of some factors such as cover-to-excavation depth ratio, length-to-depth ratio, and unloading ratio on tunnel displacement behaviors. It was demonstrated that the tunnel heaves as the excavation proceeds, and heaves and horizontal displacements reach their maximum values when the excavation is finished. The earth pressure around the tunnels is symmetrically distributed in a gourd shape, with a larger reduction at the tunnel crown and invert and a smaller reduction at tunnel side walls. Additionally, the earth pressure at the tunnel crown and invert changes more significantly than that at other parts. The tunnel moment increment is significantly affected by the tunnel excavation depth. The axial force at or near the side walls of the tunnel is the most sensitive to the unloading effect induced by the excavation activity.

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Coordinated optimization control of shield machine based on dynamic fuzzy neural network direct inverse control

Transactions of the Institute of Measurement and Control ◽

10.1177/0142331220980274 ◽

2020 ◽

pp. 014233122098027

Author(s):

Xuanyu Liu ◽

Wentao Wang ◽

Yudong Wang ◽

Cheng Shao ◽

Qiumei Cong

Keyword(s):

Fuzzy Neural Network ◽

Control Method ◽

Earth Pressure ◽

Screw Conveyor ◽

Inverse Control ◽

The Earth ◽

Coordinated Optimization ◽

Optimization Control ◽

Fuzzy Neural ◽

Shield Machine

During shield machine tunneling, the earth pressure in the sealed cabin must be kept balanced to ensure construction safety. As there is a strong nonlinear coupling relationship among the tunneling parameters, it is difficult to control the balance between the amount of soil entered and the amount discharged in the sealed cabin. So, the control effect of excavation face stability is poor. For this purpose, a coordinated optimization control method of shield machine based on dynamic fuzzy neural network (D-FNN) direct inverse control is proposed. The cutter head torque, advance speed, thrust, screw conveyor speed and earth pressure difference in the sealed cabin are selected as inputs, and the D-FNN control model of the control parameters is established, whose output are screw conveyor speed and advance speed at the next moment. The error reduction rate method is introduced to trim and identify the network structure to optimize the control model. On this basis, an optimal control system for earth pressure balance (EPB) of shield machine is established based on the direct inverse control method. The simulation results show that the method can optimize the control parameters coordinately according to the changes of the construction environment, effectively reduce the earth pressure fluctuations during shield tunneling, and can better control the stability of the excavation surface.

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Analytical solutions for the earth pressure of narrow cohesive backfill with retaining walls rotating about the top

Acta Geotechnica ◽

10.1007/s11440-021-01187-9 ◽

2021 ◽

Author(s):

Yu-jian Lin ◽

Fu-quan Chen ◽

Yan-ping Lv

Keyword(s):

Analytical Solutions ◽

Earth Pressure ◽

Retaining Walls ◽

The Earth

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The earth pressure behind full-height integral abutments

IABSE Symposium Report ◽

10.2749/222137805796271008 ◽

2005 ◽

Vol 90 (6) ◽

pp. 55-58 ◽

Cited By ~ 6

Author(s):

Ming Xu ◽

Alan G. Bloodworth

Keyword(s):

Earth Pressure ◽

The Earth ◽

Integral Abutments ◽

Full Height

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Experimental Study on Earth Pressure of Corrugated Steel Culvert under High Fill Embankment

Applied Mechanics and Materials ◽

10.4028/www.scientific.net/amm.405-408.1815 ◽

2013 ◽

Vol 405-408 ◽

pp. 1815-1819

Author(s):

Wen Sheng Yu ◽

Zhu Long Li ◽

Xiao Ru Xie ◽

Li Yuan Guo

Keyword(s):

Mechanical Property ◽

Experimental Study ◽

Reinforced Concrete ◽

Concrete Slab ◽

Earth Pressure ◽

Reinforced Concrete Slab ◽

The Earth ◽

Filling Height ◽

Test Points ◽

Better Than

To analyze the earth pressure of corrugated steel culvert under high fill embankment, a field test was taken and the change law was got with the filling height increasing, the force state when geotechnical grilles were laid on the top of corrugated steel culvert was compared to that of reinforced concrete slab culvert. Results show that the pressure on the top of corrugated steel culvert is smaller than that on the external in same level when test points are near to culvert, the values of test points above and below geotechnical grilles are close, and the pressure of corrugated steel culvert is smaller than that of reinforced concrete slab culvert when filling height is above 7.3 m. So analysis indicates corrugated steel culvert spreads the upper load better, the geotechnical grille can reduce the pressure effectively through earth pressure redistribution, and the mechanical property of corrugated steel culvert is better than reinforced concrete slab culvert under high fill embankment.

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Nomograph-how to calculate the earth pressure on a retaining wall

International Journal of Rock Mechanics and Mining Sciences & Geomechanics Abstracts ◽

10.1016/0148-9062(75)91381-9 ◽

1975 ◽

Vol 12 (5-6) ◽

pp. 83

Keyword(s):

Retaining Wall ◽

Earth Pressure ◽

The Earth

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Predicting the Earth Pressure on Integral Bridge Abutments

Journal of Bridge Engineering ◽

10.1061/(asce)be.1943-5592.0000263 ◽

2012 ◽

Vol 17 (2) ◽

pp. 371-381 ◽

Cited By ~ 19

Author(s):

Alan G. Bloodworth ◽

Ming Xu ◽

James R. Banks ◽

Chris R. I. Clayton

Keyword(s):

Earth Pressure ◽

Bridge Abutments ◽

Integral Bridge ◽

The Earth

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Evaluation of load transfer characteristics in roller-compacted concrete pavement

International Journal of Pavement Engineering ◽

10.1080/10298436.2018.1511782 ◽

2018 ◽

Vol 21 (6) ◽

pp. 796-804

Author(s):

Tetsya Sok ◽

Seong Jae Hong ◽

Young Kyu Kim ◽

Seung Woo Lee

Keyword(s):

Load Transfer ◽

Concrete Pavement ◽

Roller Compacted Concrete ◽

Transfer Characteristics

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Analysis of Concrete Pavement Responses to Temperature and Wheel Loads Measured from Intrumented Slabs

Transportation Research Record Journal of the Transportation Research Board ◽

10.3141/1639-10 ◽

1998 ◽

Vol 1639 (1) ◽

pp. 94-101 ◽

Cited By ~ 37

Author(s):

H. Thomas Yu ◽

Lev Khazanovich ◽

Michael I. Darter ◽

Ahmad Ardani

Keyword(s):

Structural Response ◽

Plain Concrete ◽

Negative Temperature ◽

Concrete Pavement ◽

Temperature Gradients ◽

Critical Conditions ◽

Test Analysis ◽

Longitudinal Edge ◽

Critical Edge ◽

Using Data

The structural response of jointed plain concrete pavement slabs was evaluated using data obtained from instrumented slabs. The instrumented slabs were a part of newly constructed jointed plain concrete overlay that was constructed on existing asphalt concrete pavement on I–70 in Colorado, near the Kansas–Colorado border. The instrumentation consisted of dial gauges for measuring curling deflections at the slab corner and longitudinal edge and surface-mounted strain gauges for measuring load strains at the longitudinal edge at midslab. The through-thickness temperature profiles in the pavement slabs were also measured at 30-min intervals during the field test. Analysis of the field data showed that the instrumented slabs had a considerable amount of built-in upward curling and that concrete slabs on a stiff base can act completely independent of the base or monolithically with the base, depending on the loading condition. The built-in upward curling of the slabs has the same effect as negative temperature gradients. These findings suggest that the effects of temperature gradients on the critical edge stresses may not be as great as previously thought and that the corner loading, in some cases, may produce more critical conditions for slab cracking. Another important finding of this study is that a physical bond between pavement layers is not required to obtain a bonded response from concrete pavements.

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