Abstract: A portable, single-phase bioreactor provides the in situ study of mesophilic and thermophilic corrosion inducing microbial biofilms on metal surfaces by oil, chemical, petrochemical, oil refining, food, metallurgical, paper fluids. The bioreactor is a batch-type for turbulent and piston-driven laminar flow, operated by cycles, with continuous circulation of the fluid. A culture medium or industrial or production fluid containing microbiota is introduced into a homogenizing container. The bioreactor includes a support section having removable corrosimetric test coupons that contact the fluid under dynamic conditions corresponding to fluid-carrying pipelines, and promote the formation of the microbial biofilm for analysis of the kinetics of microbial biofilm development. The bioreactor produces turbulence to homogenize the fluid and maintain a temperature of 20 to 80° C. for the microorganism growth. The fluid has a salinity of 2 to 200 ppm (NaCl) and a pH of 2 to 10.

Abstract: The present invention refers to a two-systems compact specimen holder (SH) easy to use which enables to analyze the same sample by employing either an atomic force microscope (AFM) or a scanning electron microscope (SEM), by preserving the setting reference of the details for both microscopies, so that it satisfies the requirements of size, conductivity, magnetization, tidiness, reference and adaptability. The capacity of preserving the location reference of the details for both microscopies, in the scope of correlational microscopy, results essential to obtain information and images in both fields of microscopy, which can be correlated in order to acquire valuable combined information.

Abstract: The present invention refers to a procedure which includes the following objectives: a) To determine the morphology of the micro and nanocavities produced by chemical and/or microbiological corrosion in metallic materials, in the space of three dimensions as well as the effective advance of corrosion, the true length of corrosion cavities and their associated parameters: corrosion vectors, corrosion intensity and determination of the cavities diameter/true length of corrosion ratio, applying scanning electron microscopy (MEB) techniques, and analytic, gravimetric and volumetric formulations; b) To quantitatively determine the rate of chemical and/or microbiological corrosion in metallic materials, through their volumetric and gravimetric properties; and c) To obtain a graphic interface to access the numeric information and the micrographs in a simple and friendly manner.

Abstract: The present invention refers to a two-systems compact specimen holder (SH) easy to use which enables to analyse the same sample by employing either an atomic force microscope (AFM) or a scanning electron microscope (SEM), by preserving the setting reference of the details for both microscopies, so that it satisfies the requirements of size, conductivity, magnetization, tidiness, reference and adaptability. The capacity of preserving the location reference of the details for both microscopies, in the scope of correlational microscopy, results essential to obtain information and images in both fields of microscopy, which can be correlated in order to acquire valuable combined information.

Abstract: A portable bioreactor is provided for the in situ study of mesophilic and thermophilic corrosion inducing microbial biofilms on metal surfaces used in any industry, such as oil, chemical, petrochemical, oil refining, food, metallurgical, paper. The bioreactor's configuration is a “batch” type for turbulent and piston-driven laminar flow, operating by cycles, with the continuous circulation of fluid. A culture medium, or industrial operation or production fluids containing microbiota is introduced into the load of the receiving body, thus the bioreactor is single phase. The bioreactor comprises a support section for corrosimetric test coupons that are in touch with the fluid under dynamic conditions, such as found in the fluid carrying pipelines, naturally promoting the formation of the microbial biofilm. The coupons are removed for analysis to follow the kinetics of microbial biofilm development.

Abstract: The present invention refers to a procedure which includes the following objectives: a) To determine the morphology of the micro and nanocavities produced by chemical and/or microbiological corrosion in metallic materials, in the space of three dimensions as well as the effective advance of corrosion, the true length of corrosion cavities and their associated parameters: corrosion vectors, corrosion intensity and determination of the cavities diameter/true length of corrosion ratio, applying scanning electron microscopy (MEB) techniques, and analytic, gravimetric and volumetric formulations; b) To quantitatively determine the rate of chemical and/or microbiological corrosion in metallic materials, through their volumetric and gravimetric properties; and c) To obtain a graphic interface to access the numeric information and the micrographs in a simple and friendly manner.

Abstract: The present invention is concerned with a procedure to quantitatively determine both, total and effective porosity of carbonated sedimentary rocks, and is based on the elaboration of molds of the rock pores-structure and on the determination of the volumetric and gravimetric properties of the rock and its mold. Determination of the effective porosity is achieved by using an original formula, developed by the authors of the present invention. Additionally, the structure of micro and nanopores in the rock is characterized by scanning electron microscopy (SEM), to identify relevant properties for permeability analyzes such as: dimensions, shapes, type of connections, pore-structure patterns and pore throats. These and other parameters are used as indicators of the reservoir production and storage capacity.

Abstract: The present invention is concerned with a procedure to quantitatively determine both, total and effective porosity of carbonated sedimentary rocks, and is based on the elaboration of molds of the rock pores-structure and on the determination of the volumetric and gravimetric properties of the rock and its mold. Determination of the effective porosity is achieved by using an original formula, developed by the authors of the present invention. Additionally, the structure of micro and nanopores in the rock is characterized by scanning electron microscopy (SEM), to identify relevant properties for permeability analyses such as: dimensions, shapes, type of connections, pore-structure patterns and pore throats. These and other parameters are used as indicators of the reservoir production and storage capacity.