A method and system of treating a formation and a well extending therethrough, including storing liquefied natural gas (LNG) at an on-site location of the well, injecting a first stream of LNG into the formation through the well to contact at least one of a surface of the formation or a metal surface locatable in the well, injecting a chemical agent into the formation through the well to contact at least one of the surface of the formation or the metal surface locatable in the well, and treating at least one of the surface of the formation or the metal surface locatable in the well with the chemical agent and the first stream of LNG.

Methods and apparatus are provided for optimizing operations for a fracturing injection waste disposal well especially where the formation is damaged or tight such that pressure fall-off tests are impractical due to extended leak-off rate times. Formation closure pressure and formation stress are calculated using Instantaneous Shut-in Pressure rather than traditional methods requiring actual fracture closure.

A system and method for monitoring disposal of wastewater in a disposal well includes: an event monitor sensor configured to identify a wastewater disposal event; and a second sensor configured to collect data about one or more characteristics of the wastewater during the wastewater disposal event. The data from the second sensor at the disposal well is analyzed to determine a classification of the wastewater, which is then reported to an operator or another interested party.

A system for injecting a portion of a drilling fluid waste into a well includes a receiving pit configured to receive a drilling fluid waste. A shaker is configured to receive the drilling fluid waste from the receiving pit and to separate solids from the drilling fluid waste to produce a separated drilling fluid waste. A mixing tank is configured to receive the separated drilling fluid waste from the shaker and to mix the separated drilling fluid waste. One or more tanks are configured to receive water. A pump is configured to cause the separated drilling fluid waste and the water to flow into a well.

Systems and/or methods of waste disposal use human-made caverns that are constructed within deep geological formations. A given human-made cavern may be constructed by first drilling out a vertical wellbore to a deep geological formation. Then a bottom portion of the vertical wellbore is jet drilled using an abrasive jetting fluid to form a launch chamber of void volume, that is sized to fit a reaming tool in its deployed open configuration. A reaming tool, in a closed configuration, is then inserted into the vertical wellbore for landing in the launch chamber. The reaming tool is then deployed into its open configuration while in the launch chamber. Reaming operations then occur from the launch chamber directed downwards within the deep geological formation, forming a given human-made cavern. The newly formed human-made cavern may be conditioned and/or configured for receiving amounts of the waste for long-term disposal and/or storage.

A drilling fluid waste disposal system includes a trench having an outlet, a receiving pit in fluid communication with the outlet of the trench, a first weir in the receiving pit, and a second weir in the receiving pit. The outlet of the trench feeds a slurry to the receiving pit, such that the slurry is at least partially separated into a liquid-enriched portion and a fluid-enriched portion using the first and second weirs. The system also includes a pump configured to draw the liquid-enriched portion of the slurry from the receiving pit and configured to introduce the at least some of the liquid-enriched portion of the slurry back into the trench. The system further includes a drying apparatus in communication with the receiving pit configured to receive the solids-enriched portion of the slurry from a second position in the receiving pit.

A tool having a downhole conveyance, a first packer, a second packer, a pump, and a first and second sensor. The pump defines a plurality of inlets and an outlet, wherein the plurality of inlets is aligned with a first plurality of holes in the downhole conveyance, and the outlet oriented in a direction longitudinally opposite the first plurality of holes and the second plurality of holes. The second sensor is longitudinally separated further away from the first plurality of holes than the first sensor and configured to activate the pump when a water level is detected. The first sensor is configured to deactivate the pump when the water level is detected.

An example modeling process of pore pressure and injected waste distribution profile may include several steps. A hydrodynamic flow simulation model may be built according to the geometry and/or physical properties of the subsurface formation. A fluid distribution and pore pressure profile in the subsurface may be affected by the geometry and orientation of hydraulic fractures created as a result of drill cuttings subsurface injection (cuttings re-injection or CRI). A fracture profile may be generated using a hydraulic fracturing simulation and may then be embedded into the hydrodynamic simulation model. In some examples, the nature of injected fluids in the same formation and through the same well, fracture, and/or perforation interval may lead to modification of the subsurface formation properties, and this may be accounted for in the simulation.

A system for injecting a portion of a drilling fluid waste into a well includes a receiving pit configured to receive a drilling fluid waste. A shaker is configured to receive the drilling fluid waste from the receiving pit and to separate solids from the drilling fluid waste to produce a separated drilling fluid waste. A mixing tank is configured to receive the separated drilling fluid waste from the shaker and to mix the separated drilling fluid waste. One or more tanks are configured to receive water. A pump is configured to cause the separated drilling fluid waste and the water to flow into a well.

A method of drilling multiple boreholes within a single caisson, for recovery of methane gas from a coal bed, including the steps of drilling first and second vertical boreholes from a single location within a single caisson; drilling at least one or more horizontal wells from the several vertical bore hole, the horizontal wells drilled substantially parallel to a face cleat in the coal bed; drilling at least one or more lateral wells from the one or more horizontal wells, the lateral wells drilled substantially perpendicular to one or more face cleats in the coal bed; continuously circulating water through the drilled vertical, horizontal and lateral wells to recover the water and entrained methane gas from the coal bed; applying friction or choke manifold to the water circulating down the well bores so that the water appears to have a hydrostatic pressure within the well sufficient to maintain an equilibrium with the hydrostatic pressure in the coal bed formation; and drilling at least a third vertical borehole within the single caisson, with one or more horizontal boreholes and one or more lateral boreholes for returning water obtained from the lateral wells into a water zone beneath the surface.