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Using the capacitive coupled geoelectrical measurement, velocities between 1.5 km/h and 2 km/h are possible for the detection of bedding defects in the road area. Depending on the type of the measurement equipment, data can be captured at the same time from up to six different depths up to a maximum depth of about 6 m. The resolution of the method depends on the resistance contrast between the “undisturbed” soil and the defects (bedding defect = … |
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The method is not to be recommended or rather limited in its use given the following limiting conditions:
Under favourable conditions (that is, with resistance differences of > 10 %) intra-urban … |
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In the soil- or georadar, also called ”Ground Penetrating Radar (GPR)”, an impulse-type high-frequency electromagnetic radio wave is sent into the ground via a broadband antenna. The signal is partly reflected at layer borders and interference bodies and received by the antenna. The radargram created that way records the structures in the underground in an interpretable form [Lenz97]. The schematic image on the top left shows the principle of measurement. … |
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When this method is used in intra-urban areas, exploration depths of up to about 4 m can be reached [Pulsf96]. Normally, the more conductive the underground, the smaller the range of the ground-penetrating radar. Thus, in wet clay, it is absolutely possible that lines below 1.5 m can no longer be located [Katha91]. Unsealed cohesive and very inhomogeneous soils also represent physical limitations of use for the geo-radar [Busch96]. In the area that … |
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Overall, the areas of application and the limits of the procedure are thus essentially determined by the following relationships:
When using georadar from the road surface, bearing defects cannot be detected due to the shading below the sewer. (Image: Schematic illustration of the GPR principle of measurement … |
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The commonly used frequencies are between 200 MHz and 900 MHz, depending on the task, also up to 2.5 GHz. Due to the shorter wavelengths, higher frequencies allow a higher resolution at the expense of the exploration depth. Empirical values are compiled in the table below. [DWAM149-4:2008] [ISA07] At least 20 scanning points per meter (scans) for a longitudinal scale of 1 : 250 are required to be able to display individual bedding defects or cavities … |
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The use of a georadar within a pipeline is done by means of a TV camera to which the antenna is mounted or coupled. If a radar measurement is made from within the sewer pipeline, synchronous camera tracking must be carried out in order to enable visual control. This can be done together with the optical inspection. (Image: Georadar measurements from the pipeline - Camera vehicle - Neu) |
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Jan 17, 2023 |
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Jan 17, 2023 (Image: Plus/Minus) Advantages of geophysical methods The advantage of geophysical measuring methods is that a usable statement about the non-visible areas outside the sewer wall and below the road surface in the existing subsurface and in the backfilling of the pipe trench can be made with relatively little effort. The following criteria have to be taken into consideration [Reute92] [Altha99]:
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Jan 17, 2023 (Image: Plus/Minus) Disadvantage of geophysical methods A device-specific disadvantage of geophysical methods is that all signals have to penetrate layers that are often very inhomogeneous, earthwork and road surfaces before they reach the measuring object. Thus, the virtual signal can be strongly disturbed, resulting in useless measurement data. What does the selection of the most suitable method depend on? Consequently, the choice of the geophysical … |
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Jan 17, 2023 What influences the significance and reliability of geophysical measurements? The methods used in the field campaign and the adequate arrangement of the measurement equipment are of great importance with respect to the significance and reliability of geophysical measurements. Geophysical results of measurement are ambiguous by their nature and there exists a high complexity of correlations between the stimulating signal and the response behaviour … |
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Jan 17, 2023 Which boundary conditions influence the choice of geophysical exploration methods? The choice of suitable geophysical methods of exploration for the assessment of the pipe-soil-system’s condition is influenced by the following limiting conditions:
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Jan 17, 2023 The following is a summary overview of the geophysical methods presented, with assignment of the areas of application. (Table: Overview of application areas of geophysical methods) |
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Jan 17, 2023 The left and right table provide an overview of the areas of application of geophysical measuring methods (georadar, geoelectrics, seismics). (Table: Fields of application for geophysical methods of analysis in sewer construction according to DWA-M 149-4) (Table: Impact of the underground onto the possible fields of application for geophysical methods according to DWA-M 149-4) Important: None of the geophysical methods explained above is suitable to … |
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(Image: Picto Bodenuntersuchung) The results of the geotechnical investigations and laboratory analyses have to be determined by a subsoil expert and then written down in a geotechnical report. The geotechnical report (in practice also called subsoil report or subsoil expertise) includes the geotechnical investigation report according to Eurocode 7 (EC 7). This report forms part of the geotechnical design report in accordance with EC 7, which additionally … |
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Jan 17, 2023 This module teaches the basics of geophysical soil investigation and is to be understood as a supplement to the module "Geotechnical Investigation". Geophysical measurement methods belong to the indirect exploration methods and allow statements regarding local inhomogeneities in the pipeline zone (e.g. bedding defects, cavities, disruptions, concrete encasements) or, in the case of investigations of existing sewers and pipelines, statements regarding the condition and load-bearing capacity of the embedment. In addition to ground or georadar (EMR - electromagnetic reflection), which is well-known in pipeline construction and rehabilitation, the measurement methods seismic, seismic tomography, air gun seismic, magnetics, electromagnetics and geoelectrics are also introduced. After completing this module, you will have knowledge regarding:
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Nov 07, 2022 News TRACTO-TECHNIK Australia Pty Ltd. TRACTO has partnered with New Zealand-based Pro Mechanical, making it the company’s mechanical service partner in the country.
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Nov 09, 2022 News Achim Kühn Herrenknecht AG starts the bauma 2022 with a highly coveted award and received the bauma Innovation Award 2022 in the category "Machine Technology" for the new development of continuous tunnelling.
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Sep 03, 2024 (Video: Introduction Video BE-13 Renovation: Final work, Acceptace, Renovation Defects) |
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Aug 02, 2023 News Alicia Barbieri System improvements designed to continue safe and reliable water service to Camden community
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Aug 03, 2023 Document Summary This lesson builds on the module "Application of coding systems using the example of EN 13508-2" and introduces the coding of damage (findings) for sewers and drains. In more detail, the causes and consequences of damage are explained for the damage and, in some cases, the damage mechanisms are presented as well. Learning Objectives Upon successful completion of this course, you will be able to:
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Aug 03, 2023 Document In the following, the types of defects in drains and sewers that can be detected during a visual internal inspection as well as their possible causes and consequences will be described in accordance with EN 13508-2 and DWA-M 149-2. In this context, EN 13508-2 distinguishes between a total of four main codes:
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