Evaluation of Microwave Heating on Fluid Invasion and Phase Trapping in Tight Gas Reservoirs

Wang, Hongcai; Rezaee, Reza; Saeedi, Ali

doi:10.2118/176906-ms

Cited by 7 publications

(1 citation statement)

References 8 publications

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“…Table 4 Depth of invasion (distance from borehole wall) versus porosity (after Miesch and Albright (1967) and Rider (1986) After microwave heating for 1 day, the maximum temperature in the near wellbore region reached to about 900°C and the depth influenced by the heat reached around 0.4 m. In this simulation, we focused on the penetration depth of microwave heating, temperature distribution and its effect on water saturation. The effects of microwave heating on relative permeability and gas production have been discussed in another paper (Wang, Rezaee and Saeedi, 2015). The water saturation in the near wellbore region was reduced significantly.…”

Section: Numerical Simulationmentioning

confidence: 98%

Preliminary study of improving reservoir quality of tight gas sands in the near wellbore region by microwave heating

Wang

Rezaee

Saeedi

2016

Journal of Natural Gas Science and Engineering

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The formation damages, such as water blocking and clay swelling, in tight gas reservoir have been recognized as severe problems impairing gas production. To remedy these damages, formation heat treatment (FHT) was taken as one of the effective measures by some researchers. In this paper, the effects of microwave heating on the petrophysical properties of sandstone samples has been investigated. A modified commercial microwave oven was used to heat the core plugs and aluminum tubes were used to accommodate tight sandstone samples in order to confine them and reduce their contact with air. After microwave heating, any alterations in the porosity, permeability, texture, structure, mineralogy, and pore size distribution of tight sandstones were investigated by a series of lab experiments. By subjecting tight sandstone samples to microwave, the surface temperature of sandstone can be elevated to approximately 400 C or more. The intense heat is effective in changing the structure, texture and mineralogy of the sandstone. The shrinkage or decomposition of minerals, which are shown by XRD analysis, and generation of micro-fractures created more spaces in the samples. By employing Automated Permeameter, porosity and permeability are found increased after heating. Nuclear Magnetic Resonance (NMR) and CT numbers of all samples after microwave heating indicate the increase of porosity as well. Moreover, the NMR T2 distribution reveals the smaller pores diminished, so the incremental porosity of short NMR T2 decreased. Micro-fractures generated between grains or in grains due to decomposition of some cement minerals and clay shrinkage, so the amplitude of long NMR T2 increased. The fractures are visible both in X-ray CT images and in Scanning Electronic Microscopy (SEM) images. By comparing with NMR T2 distribution data, it is found that the presence of microfractures accounts for the increased population of pores with T2 larger than 10ms. The numerical simulation of microwave heating in the borehole indicates that the microwave heating is effective to raise the temperature of reservoir rock to approximately 900 °C within 1 day and to remove the water within a distance of 25cm from the borehole wall. The efficiency of microwave heating can be further improved by optimizing the downhole microwave device.

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Section: Numerical Simulationmentioning

confidence: 98%

Preliminary study of improving reservoir quality of tight gas sands in the near wellbore region by microwave heating

Wang

Rezaee

Saeedi

2016

Journal of Natural Gas Science and Engineering

Self Cite

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Evaluation method and treatment effectiveness analysis of anti-water blocking agent

Fan

Lyu

Zhao

et al. 2016

Journal of Natural Gas Science and Engineering

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Numerical modelling of microwave heating treatment for tight gas sand reservoirs

Wang

Rezaee

Saeedi

et al. 2017

Journal of Petroleum Science and Engineering

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Formation Heat Treatment (FHT) has been proved effective in removing water phase and creating micro-fractures in the near wellbore area previously. In order to improve the cost and time efficiency of FHT, microwave heater is considered as an alternative in this paper, and its feasibility in FHT is discussed in this paper. Numerical simulation is carried out to investigate the effects of microwave heating on reservoir quality and gas production. It is found that the water phase can be effectively removed by microwave heating, as a result, the relative permeability to gas increased significantly after heating. In terms of gas production rate, the cumulative gas in 90 days in heated well is 4×10 5 m 3 more than the non-heated well. As the most important parameter, the temperature distributions in the reservoir are computed with two methods and their value against the heating depth agree with each other reasonably. On the other hand, the surface temperature variations of three tight sandstone plugs are heated with microwave in the lab and their surface temperatures are carefully recorded against time. Then the laboratory data are compared with simulation results, and they correlate well with each other. The simulation work conducted in this paper shows the promising improvement of gas relative permeability and production by microwave heating.

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Evaluation of Microwave Heating on Fluid Invasion and Phase Trapping in Tight Gas Reservoirs

Cited by 7 publications

References 8 publications

Preliminary study of improving reservoir quality of tight gas sands in the near wellbore region by microwave heating

Preliminary study of improving reservoir quality of tight gas sands in the near wellbore region by microwave heating

Evaluation method and treatment effectiveness analysis of anti-water blocking agent

Numerical modelling of microwave heating treatment for tight gas sand reservoirs

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