Fluid activities injection

Nearly all of the treatment processes in which fluids are injected into oil wells to increase or restore the levels of production make use of surface-active agents (surfactant) in some of their various applications, e.g., surface tension reduction, formation and stabilization of foam, anti-sludging, prevention of emulsification, and mobility control for gases or steam injection. The question that sometimes arises is whether the level of surfactant added to the injection fluids is sufficient to ensure that enough surfactant reaches the region of treatment. Some of the mechanisms which may reduce the surfactant concentration in the fluid are precipitation with other components of the fluid, thermally induced partition into the various coexisting phases in an oil-well treatment, and adsorption onto the reservoir walls or mineral... 

Fluids were injected into a central well, surrounded by 6 production wells at distances from about 200-360 ft (Figure 1). Injection equipment consisted of an air compressor, a pump for the 25 drums of 60% active surfactant that were used, a pump for dilution of the concentrated surfactant solution with plant water, a foam generator (2-ft long, 3-in. diameter pipe packed with ceramic particles) that optionally could be bypassed, and a sight glass for visual observation of the fluids before they entered the well. 

Thiomersal is approximately 0.02 % soluble in water. The active concentration is 0.01 %. It is mainly used in eye drops, contact lens fluids and injection fluids. In solution the active molecule is ethylmercuric that is somewhat more toxic than phenylmercuric but less than ionogenic mercury. Also the risk of hypersensitivity reactions is greater than with phenylmercuric borate. With prolonged use in eye drops or contact lens fluids damage of the cornea epithelium may occur. 

Coelenterazine and the corresponding luciferase can be easily tested in the field. A small piece of tissue sample is put in a test tube with methanol (for coelenterazine) or water (for luciferase), and crushed with a spatula. To measure coelenterazine, a buffer solution containing a coelenterazine luciferase is injected into a small amount of the fluid part of the crushed sample mixture. Similarly, luciferase can be measured with a buffer solution containing coelenterazine. The presence of Cypridina luciferin can be tested in the same fashion, with the methanol extract of samples and crude Cypridina luciferase. However, the detection of a very weak Cypridina luciferase activity in the field is not recommended (see Section C5.6). To test the presence of a Ca2+-sensitive photoprotein, crush a sample in a neutral buffer solution containing 20-50 mM EDTA, and then add lOmM calcium acetate to a small portion of the fluid part of the crushed sample to detect any light emission. 

Smith and Udseth [154] first described SFE-MS in 1983. Direct fluid injection (DFT) mass spectrometry (DFT-MS, DFI-MS/MS) utilises supercritical fluids for solvation and transfer of materials to a mass-spectrometer chemical ionisation (Cl) source. Extraction with scC02 is compatible with a variety of Cl reagents, which allow a sensitive and selective means for ionising the solute classes of interest. If the interfering effects of the sample matrix cannot be overcome by selective ionisation, techniques based on tandem mass spectrometry can be used [7]. In these cases, a cheaper and more attractive alternative is often to perform some form of chromatography between extraction and detection. In SFE-MS, on-line fractionation using pressure can be used to control SCF solubility to a limited extent. The main features of on-line SFE-MS are summarised in Table 7.20. It appears that the direct introduction into a mass spectrometer of analytes dissolved in supercritical fluids without on-line chromatography has not actively been pursued. 

A patented water injection system has been devised for extinguishing oil and gas well fires in case of a blowout. The "Blowout Suppression System" (BOSS) consist of finely atomized water injected to the fluid stream of a gas and oil mixture before it exits a release point. The added water lowers the flame temperature and flame velocities thereby reducing the flame stability. In the case where the flame cannot be completely dissipated, the fire intensity is noticeably deceased, preserving structural integrity and allowing manual intervention activities. A precaution in the use of such a device is that, if a gas release fire is suppressed but the flow is not immediately isolated, a gas cloud may develop and exploded that would be more destructive that the pre-existing fire condition. 

There are five classes of injection wells (Class I through V). Class I disposal wells are used for the disposal of industrial and hazardous waste streams, and may also be subject to certain RCRA, Subtitle C hazardous waste management regulations. Class II wells are defined as those wells used in conjunction with oil and gas production activities. Class III wells are defined as those wells that inject fluids ... 

The flow control system provides facilities for injecting air, steam, oxygen or other fluids into the reactor, and is governed by d/p cell transmitters and pneumatically-activated valves which permit automatic or manual regulation of flow rates and pressures. 

Hydromorphone is more soluble than morphine and approximately eight times more active upon parenteral administration. High solubility permits a lower volume of injected fluid, which is important if multiple injections are needed. It begins to work faster than morphine, but lasts for a shorter amount of time. It has a high sedative effect and a lessened capability of causing euphoria. Hydromorphone is used the same way as morphine. Side effects are analogous. Synonyms for this drug are dilaudid and others. 

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