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Technologies used to control classes of microorganisms found in cooling systems and methods for monitoring and control. Of interest to owners, engineers, contractors, and operators.
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The problem of nonextractable chlorides on refinery equipment and lessons learned. A resource for refining, production & chemical-treatment suppliers for preventing corrosion at refineries.
This standard practice describes appropriate prevention and mitigation measures that can be applied to RC and PC structures that are, or can be, exposed to stray-currents from external sources in order to minimize or eliminate stray-current corrosion. This standard practice addresses only steel corrosion related issues, and does not deal with issues of safety and hazards to people or structures associated with DC and AC voltages; these are covered in national standards and regulations, such as EN 50443 and EN 50122-1.
This NACE/SSPC joint standard defines the Thorough Cleaning (WJ-3) degree of surface cleanliness of coated or uncoated metallic substrates achieved by the use of waterjet cleaning prior to the application of a protective coating or lining. Waterjet cleaning is the use of pressurized surface preparation water for removing coatings and other materials, including hazardous materials, from a substrate to achieve a defined degree of surface cleanliness. Waterjet cleaning includes various methods such as low-pressure water cleaning (LP WC), high-pressure water cleaning (HP WC), high-pressure waterjetting (HP WJ), and ultrahigh-pressure waterjetting (UHP WJ).
HISTORICAL DOCUMENT. Stress corrosion cracking direct assessment (SCCDA) is a structured process that is intended to assist pipeline companies in assessing the extent of stress corrosion cracking (SCC) on a section of buried pipeline and thus contribute to their efforts to improve safety by reducing the impact of external SCC on pipeline integrity. Primary guidance for assessing the structural integrity of a pipeline that has a significant risk of containing stress corrosion cracks is provided in Part A3 of ASME(1) B31.8S,1 which identifies several options for inspection and mitigation activities. The recommended practice for SCCDA presented in this standard addresses the situation in which a pipeline company has identified a portion of its pipeline as an area of interest with respect to SCC based on its history, operations, and risk assessment process and has decided that direct assessment is an appropriate approach for integrity assessment. This standard provides guidance for managing SCC by selecting potential pipeline segments, selecting dig sites within those segments, inspecting the pipe, collecting and analyzing data during the dig, establishing a mitigation program, defining the reevaluation interval, and evaluating the effectiveness of the SCCDA process.
This standard practice provides guidance on selecting and implementing the Pipeline Integrity Management (PIM) methods (i.e., technologies and processes) to assess and to mitigate threats to pipeline integrity. Predominant threats to pipeline integrity are external corrosion (EC), internal corrosion (IC), stress corrosion cracking (SCC), mechanical damage (first, second, and third party or vandalism), equipment malfunctioning, manufacturing anomalies, construction anomalies, incorrect operations, weather-related, and external forces. The standard is focused on the “selection” and “implementation” of methods and best practices to manage pipeline integrity, but not necessarily on defining all aspects of PIM programs.
Information about the dynamic scale inhibitor evaluation apparatus known as the tube-blocking apparatus. A resource for using dynamic flow-through test apparatus. Procedures typically used for evaluating
Selecting, applying, and evaluating the use of biocides in oil and gas field operations - including stimulation, production, storage, transmission, hydrostatic testing, and water injection applications.
Electrical isolation/continuity issues and coating issues to consider when designing and operating offshore pipeline cathodic protection (CP) systems. For owners, engineers, contractors, and operators.
The purpose of this AMPP standard practice is to present procedures and practices for the design, installation, operation, and maintenance of deep anode systems used for the control of external corrosion of underground or submerged metallic structures by impressed current cathodic protection (ICCP). It is intended to be used in conjunction with NACE SP0169 and SP0177. This standard is intended to be used by corrosion engineers, corrosion consultants, representatives from manufacturers, and others concerned with corrosion control of underground structures.
HISTORICAL DOWNLOADABLE 2015 EDITION.
Selection and qualification of carbon and low-alloy steels, corrosion-resistant alloys, and other alloys for service in equipment in oil and natural gas production and NG treatment plants in H2S-containing