菜单
  
    The overall goal of this project was to advance the state-of-the-art in GPR techniques so that it can become a more practical and reliable tool for assessing the integrity of reinforced concrete bridge decks, with particular attention directed towards the specific problems of the bridges in New England. This project was conducted with funding by the New England Transportation Consortium (NETC) Project 94-2 “Nondestructive Testing of Reinforced Concrete Bridges Using Radar Imaging Techniques.” The project involved numerical, laboratory and field studies of GPR interactions with reinforced concrete roadways. 21607

    A multidisciplinary team of investigators with experience in GPR, electromagnetics, structural engineering and scientific instrument development, from the University of Vermont and consultants from Massachusetts worked on the project. The investigators from the University of Vermont included Professors Dryver R. Huston and Prof. Peter L. Fuhr and several graduate and undergraduate students. The Massachusetts-based investigators were Dr. Kenneth Maser of Infrasense, Inc. and Dr. William Weedon of Applied Radar, Inc.

    The overall result of the project was that most of the proposed objectives were met. A working high-frequency (0.5 – 6.0 GHz) system was built and tested on damaged and undamaged slabs in both the laboratory and the field. Damage in the form of thin air-filled delaminations and accelerated corrosion was identified in the laboratory. The field results are a little less certain because of the unknown state of the underlying roadway. The state of the art for GPR has advanced considerably in the past several years. Some of the modern imaging techniques show promise for routine use in GPR surveys of bridge decks. It is recommended that future GPR systems for roadways operate at frequencies above 2 GHz and that they include synthetic aperture radar imaging techniques.

    The bridge infrastructure of the United States is distressed. The United States Department of Transportation estimated in early 1994 that as many as 40% of the total number of bridges in this country are structurally deficient, with repair costs estimated in the billions of dollars (Smith, 1995; and Halabe et al. 1995). The leading cause is the deterioration of the bridge deck. Deterioration is due primarily to two mechanisms: 1) Freeze/thaw damage to the concrete (punky concrete), and 2) Corrosion-induced delamination resulting from infiltration of chlorides introduced by winter road salting operations or by ocean spray. Unfortunately, bridge deterioration – including rebar corrosion, delaminations and disintegrating concrete – is often hidden under an asphalt overlay (Maser and Kim Roddis, 1990). Efficiently managing maintenance activities for bridge decks requires tools that can assess the integrity or state of deterioration. One of the major problems with concrete deterioration is that its severity and extent is difficult to assess. The mechanisms of deterioration occur below the surface, and their manifestations are not readily seen in visual inspections. Consequently, agencies are forced to program, prioritize, and set budgets for the repair and replacement of many structures whose conditions are virtually unknown. This has led to "surprises" during construction, and to cost overruns and excess repairs.

    Current techniques for condition assessment are slow, labor intensive, intrusive to traffic, and do not produce an accurate estimate of the quantity of deteriorated concrete. These techniques, which include core sampling, corrosion (half-cell) potentials, and chloride ion measurements, are well documented (NCHRP, 1979). Corrosion potentials and chloride ion measurements infer corrosion, but do not address unseen freeze/thaw damage. A more reliable technique, the chain drag, does not work with either asphalt overlays or in heavy traffic conditions with high ambient noise. Alternative non-destructive evaluation (NDE) techniques offer the possibility of more efficiently and effectively assessing the state of a bridge deck.
  1. 上一篇:冷却系统研究及注射模设计英文文献和中文翻译
  2. 下一篇:建筑热舒适性英文文献和中文翻译
  1. RANSAC算法全景图像拼接关键技术研究+源程序

  2. Co和大幅面质子辐射效应...

  3. 模拟退火技术来设计英文文献和中文翻译

  4. 数字通信技术在塑料挤出...

  5. 快速成型制造技术英文文献和中文翻译

  6. 数控技术和设备的发展趋...

  7. CAE技术在车辆安全性应用英文文献和中文翻译

  8. 浅析中国古代宗法制度

  9. NFC协议物理层的软件实现+文献综述

  10. C++最短路径算法研究和程序设计

  11. 巴金《激流三部曲》高觉新的悲剧命运

  12. g-C3N4光催化剂的制备和光催化性能研究

  13. 高警觉工作人群的元情绪...

  14. 现代简约美式风格在室内家装中的运用

  15. 中国传统元素在游戏角色...

  16. 江苏省某高中学生体质现状的调查研究

  17. 上市公司股权结构对经营绩效的影响研究

  

About

优尔论文网手机版...

主页:http://www.youerw.com

关闭返回