Abstract: A system to create a surface log by using a processor connected to data storage on a network that creates and executive dashboard of surface log information using computer instructions to (a) form an editable surface log template, (b) import user information, well sensor information, well event based observation data; well fluid testing data, (c) scale the imported data, forming scaled values, (d) computing a microview and a macroview log plot using the scaled values; (e) creating an executive dashboard, (f) inserting the log plots onto the executive dashboard and other real time well logging information allowing viewing of the log plots simultaneously with the other information on a real time basis, enabling safety interpretations for drilling, geological interpretations for drilling, operational interpretations for drilling, and combinations of these interpretations, in real time.

Abstract: A system to create a surface log by using a processor connected to data storage on a network that creates and executive dashboard of surface log information using computer instructions to (a) form an editable surface log template, (b) import user information, well sensor information, well event based observation data; well fluid testing data, (c) scale the imported data, forming scaled values, (d) computing a microview and a macroview log plot using the scaled values; (e) creating an executive dashboard, (f) inserting the log plots onto the executive dashboard and other real time well logging information allowing viewing of the log plots simultaneously with the other information on a real time basis, enabling safety interpretations for drilling, geological interpretations for drilling, operational interpretations for drilling, and combinations of these interpretations, in real time.

Abstract: A system to create a surface log by using a processor connected to data storage on a network that creates and executive dashboard of surface log information using computer instructions to (a) form an editable surface log template, (b) import user information, well sensor information, well event based observation data; well fluid testing data, (c) scale the imported data, forming scaled values, (d) computing a microview and a macroview log plot using the scaled values; (e) creating an executive dashboard, (f) inserting the log plots onto the executive dashboard and other real time well logging information allowing viewing of the log plots simultaneously with the other information on a real time basis, enabling safety interpretations for drilling, geological interpretations for drilling, operational interpretations for drilling, and combinations of these interpretations, in real time.

Abstract: A method for providing geological trends and real time mapping of a geological basin by forming a geochemical surface well log. The method provides in real time, information from a mass spectrometer on fluid samples from a wellbore, into a geochemical well log template using computer instructions to create a plurality of graphical tracks. The dataset includes geochemical, engineering, and geological information. The geochemical surface well log is transmitted to and viewable on a client device. The geochemical surface well log provides information on well fluids and rock. The mass spectrometer receives fluid samples and performs analysis on the fluid samples, and then communicates fluid testing data in real time to a geochemical surface well log with a plurality of graphical tracks which is then further communicated to a client device via a network.

Abstract: A system for providing geological trends and real time mapping of a geological basin. The system provides in real time, information from a mass spectrometer on fluid samples from a wellbore, and forms a geochemical surface well log with graphical tracks. The system uses a dataset that includes geochemical, engineering, and geological information. The geochemical surface well log is viewable on a client device connected to a network. The geochemical well log provides information on well fluids and rocks, and displays data in graphical tracks. The mass spectrometer receives samples from a total hydrocarbon analyzer or a gas trap connected to the wellbore. The mass spectrometer performs analysis on fluid samples, and communicates in real time to the geochemical surface well log.

Abstract: An automatic method for providing geological trends and real time mapping of a geological basin using a mass spectrometer. The method provides information from a mass spectrometer on fluid samples from a wellbore into a geochemical surface well log with graphical tracks in real time. The dataset includes geochemical, engineering, and geological. The viewable geochemical well log provides information on well fluids and rock, and displays data in graphical tracks on client devices. The mass spectrometer receives samples from a gas trap connected to the wellbore, performs analysis on the samples, and communicates in real time to a geochemical surface well log with a plurality of graphical tracks which is then further communicated to a client device via a network.

Abstract: A drilling rig having continuous gas analysis can include a substructure, base, mast, pipe handler, mud pump, drilling rig power source, drawworks, cabling, rotating head, blowout preventer, drill string, and drill bit. A rig server of the drilling rig can have a rig processor and rig data storage for implementing rig operations. Piping can be in fluid communication between the blowout preventer and a gas analyzer system for real-time measurement of a concentration of gases in a drilling fluid. The gas analyzer system can include a sample chamber, means for agitating and creating a vortex, gas capturing chamber for receiving liberated fluid, gas analyzer for providing real-time gas speciation of the liberated fluid, suction pump for pulling the liberated fluid, filtration means, exhaust port, and exhaust line for flowing non-analyzed fluid to a drilling fluid storage chamber, drilling fluid conduit, or both.

Abstract: A gas trap with a gas analyzer for continuous gas analysis can include a sample chamber, means for agitating and creating a vortex, gas capturing chamber for receiving liberated gas, gas analyzer for providing real-time gas speciation of the liberated gas. A suction pump can pull the liberated fluid, a filtration means can condition the liberated fluid, and an exhaust port can exhaust analyzed fluid. An exhaust line can flow non-analyzed fluid to a drilling fluid storage chamber, drilling fluid stream, or both.

Abstract: A cloud computing method for geosteering during directional drilling of a wellbore. The method includes a cloud processor, cloud data storage, and client devices in communication with the cloud processor through a network. The cloud processor receives data from directional drilling equipment and presents that data to users in an executive dashboard. Users can send data and/or commands to the directional drilling equipment. The executive dashboard can present: a portion of interest in a stratigraphic cross section for user identification of: the drill bit in the stratigraphic cross section, formations in the stratigraphic cross section, and other formation data. The method can be used to: identify a projected path for the drill bit, import data, compute wellbore profiles and stratigraphic cross sections, plot actual drilling paths, overlay the actual drilling path onto the projected path, and present control buttons to the user.

Abstract: A method for gas analysis can include continuously diverting a portion of drilling fluid into a sample chamber from a drilling fluid stream, creating a bidirectional drilling fluid circulation to liberate gas from the drilling fluid, applying a suction to a gas capturing chamber, and allowing a sample of the liberated fluid to continuously flow through the gas capturing chamber, continuously be filtered, and continuously flow into a gas analyzer. The method can include maintaining the sample chamber in an open configuration or decompressing the gas capturing chamber by closing off one or more sample inlets and sample outlets and exhausting portions of the liberated fluid that do not flow to the gas analyzer. The method can include simultaneously providing analysis data to client devices.

Abstract: A drilling rig for geo-steering during directional drilling of a wellbore including a processor, a data storage, and client devices in communication with the processor through a network. The processor can receive data from directional drilling equipment and can present that data to users in an executive dashboard. Users can send data and/or commands to the directional drilling equipment. The executive dashboard can present a portion of interest in a stratigraphic cross section for user identification of the drill bit in the stratigraphic cross section, formations in the stratigraphic cross section, and other formation data. The system can be used to identify a projected path for the drill bit, import data, compute wellbore profiles and stratigraphic cross sections, plot actual drilling paths, overlay the actual drilling path onto the projected path, and present control buttons to the user.

Abstract: A computer drilling model for geo-steering during directional drilling of a wellbore including a processor, a data storage, and client devices in communication with the processor through a network. The processor can receive data from directional drilling equipment and can present that data to users in an executive dashboard. Users can send data and/or commands to the directional drilling equipment. The executive dashboard can present: a portion of interest in a stratigraphic cross section for user identification of: the drill bit in the stratigraphic cross section, formations in the stratigraphic cross section, and other formation data. The computer drilling model can be used to: identify a projected path for the drill bit, import data, compute wellbore profiles and stratigraphic cross sections, plot actual drilling paths, overlay the actual drilling path onto the projected path, and present control buttons to the user.

Abstract: A method for geo-steering, during directional drilling of a wellbore, including a processor, a data storage, and client devices in communication with the processor through a network. The processor can receive data from directional drilling equipment and can present that data to users in an executive dashboard. Users can send data and/or commands to the directional drilling equipment. The executive dashboard can present a portion of interest in a stratigraphic cross section for user identification of: the drill bit in the stratigraphic cross section, formations in the stratigraphic cross section, and other formation data. The method can be used to identify a projected path for the drill bit, import data, compute wellbore profiles and stratigraphic cross sections, plot actual drilling paths, overlay the actual drilling path onto the projected path, and present control buttons to the user.

Abstract: A system for geo-steering during directional drilling of a wellbore including a processor, a data storage, and client devices in communication with the processor through a network. The processor can receive data from directional drilling equipment and can present that data to users in an executive dashboard. Users can send data and/or commands to the directional drilling equipment. The executive dashboard can present: a portion of interest in a stratigraphic cross section for user identification of: the drill bit in the stratigraphic cross section, formations in the stratigraphic cross section, and other formation data. The system can be used to identify a projected path for the drill bit, import data, compute wellbore profiles and stratigraphic cross sections, plot actual drilling paths, overlay the actual drilling path onto the projected path, and present control buttons to the user.

Abstract: A method for providing real-time streaming drilling data transmission services using self-aligning satellites. The method can include receiving and transmitting the drilling data using client devices, radio boxes, a processor, a local network, a satellite network, a router and switch, a satellite modem, and self-aligning satellite dishes. The drilling data can be transmitted to a remote network operation center and a remote central server. The remote central server can real-time stream the remote client devices.

Abstract: A system and computer assisted method to fractionate an oil or other well using a user moveable and rotatable three dimensional model of a lateral pay zone for a directionally drilled well, and other information relative to the lateral pay zone, enabling accurate identification of fractionation zones, accurate placement of well perforating guns, and accurate insertion of fractionation plugs to maximize production of the well, while additionally enabling the three dimensional model of the lateral pay zone to be viewable and updatable by on site uses at the location of the fractionation and by remote users as events occur, in some cases, in providing updates in less than 1 minute.

Abstract: An automatic method for providing geological trends and real time mapping of a geological basin using a mass spectrometer. The method provides information from a mass spectrometer on fluid samples from a wellbore into a geochemical surface well log with graphical tracks in real time. The dataset includes geochemical, engineering, and geological. The viewable geochemical well log provides information on well fluids and rock, and displays data in graphical tracks on client devices. The mass spectrometer receives samples from a gas trap connected to the wellbore, performs analysis on the samples, and communicates in real time to a geochemical surface well log with a plurality of graphical tracks which is then further communicated to a client device via a network.

Abstract: A system for providing geological trends and real time mapping of a geological basin. The system provides in real time, information from a mass spectrometer on fluid samples from a wellbore, and forms a geochemical surface well log with graphical tracks. The system uses a dataset that includes geochemical, engineering, and geological information. The geochemical surface well log is viewable on a client device connected to a network. The geochemical well log provides information on well fluids and rocks, and displays data in graphical tracks. The mass spectrometer receives samples from a total hydrocarbon analyzer or a gas trap connected to the wellbore. The mass spectrometer performs analysis on fluid samples, and communicates in real time to the geochemical surface well log.

Abstract: A method for providing geological trends and real time mapping of a geological basin by forming a geochemical surface well log. The method provides in real time, information from a mass spectrometer on fluid samples from a wellbore, into a geochemical well log template using computer instructions to create a plurality of graphical tracks. The dataset includes geochemical, engineering, and geological information. The geochemical surface well log is transmitted to and viewable on a client device. The geochemical surface well log provides information on well fluids and rock. The mass spectrometer receives fluid samples and performs analysis on the fluid samples, and then communicates fluid testing data in real time to a geochemical surface well log with a plurality of graphical tracks which is then further communicated to a client device via a network.

Abstract: A system for creating a log during gas detection and monitoring is disclosed herein. The system can include a gas detection and well logging device for sensing and transmitting data, which can include a processor in communication with a monitoring device. The monitoring device can monitor, acquire, and transmit data associated with a drilling operation. The processor can receive the data, calibrate the data, and log the data into files. The processor can capture sensed data based on a time event and a depth event. The processor can scale the data and form a geological-hydrocarbon log for transmission. A client device can be in communication with the gas detection and well logging device, and can have computer instructions for querying the geological hydrocarbon log, the data, and the files to obtain real time streaming data for instant display.