SAUDI ARABIAN OIL COMPANY patent applications on January 30th, 2025
Patent Applications by SAUDI ARABIAN OIL COMPANY on January 30th, 2025
SAUDI ARABIAN OIL COMPANY: 26 patent applications
SAUDI ARABIAN OIL COMPANY has applied for patents in the areas of G05D105/80 (2), F02D41/06 (2), F02D41/00 (2), G01N33/00 (2), E21B41/00 (2) F02D41/0027 (2), B65G5/00 (1), G01N21/6428 (1), G06Q50/2057 (1), G06Q50/02 (1)
With keywords such as: well, drilling, gas, supply, engine, further, chain, hydrocarbon, determining, and configured in patent application abstracts.
Patent Applications by SAUDI ARABIAN OIL COMPANY
20250033886. HYDROGEN GAS SUBSURFACE STORAGE (HSS)_simplified_abstract_(saudi arabian oil company)
Inventor(s): Abdulaziz S. Al-Qasim of Dammam (SA) for saudi arabian oil company, Sunil Kokal of Dhahran (SA) for saudi arabian oil company, Yuguo Wang of Dhahran (SA) for saudi arabian oil company
IPC Code(s): B65G5/00, C25B1/04, F17C1/00
CPC Code(s): B65G5/00
Abstract: a method of storing hydrogen gas in a subsurface formation may include compressing hydrogen gas by utilizing a compressor. this may create pressurized hydrogen gas that may be introduced into a subsurface formation through a wellhead to store as reserved hydrogen gas. the reserved hydrogen gas may be stored and maintained in the subsurface formations for a period. another method in accordance with one or more embodiments of the present disclosure relates to recovering previously stored hydrogen gas from a subsurface storage for energy production. the method may include extracting reserved hydrogen gas from a subsurface formation. the extracted hydrogen gas may be purified by using at least a dehydrator, a pressure swing adsorption unit (psa) and at least a temperature swing adsorption unit (tsa). the purified hydrogen gas may then be pressurized and used as a fuel for combustion in a turbine-generator unit.
Inventor(s): Vallinayagam Raman of Dhahran (SA) for saudi arabian oil company, Junseok Chang of Dhahran (SA) for saudi arabian oil company
IPC Code(s): C10L1/04
CPC Code(s): C10L1/04
Abstract: a method for blending fuel streams to produce a low-sulfur distillate blend includes formulating a blend composition using a model, calculating a projected stability of the determined composition using a predictive stability model, and forming a low-sulfur distillate blend based on the determined composition by mixing determined input streams at the blending ratio. a low-sulfur distillate blend (lsdb) for marine engines includes a blend of residual and distillate fuel streams that satisfies the imo global sulfur cap of 0.5 wt % sulfur and is stable without any separation of blend components.
Inventor(s): Bodong Li of Dhahran (SA) for saudi arabian oil company, Guodong Zhan of Dhahran (SA) for saudi arabian oil company, Abdulaziz Almusa of Dhahran (SA) for saudi arabian oil company, Abdulwahab Aljohar of Dhahran (SA) for saudi arabian oil company, Timothy Eric Moellendick of Dhahran (SA) for saudi arabian oil company, Zhongwei Suo of Beijing (CN) for saudi arabian oil company
IPC Code(s): E21B4/00, E21B4/14
CPC Code(s): E21B4/003
Abstract: a tubular apparatus includes an upper joint, an inner cylinder, a piston, a metal seal, a bearing, and an anvil. the upper joint is connected to an outer cylinder. the inner cylinder has a cavity and is disposed within the outer cylinder. the piston has a piston rod disposed within the cavity of the inner cylinder and is moveable along an axis. the metal seal is disposed between the inner cylinder and a cylinder gland. the piston rod extends through the cylinder gland to a hammer, and a portion of the hammer is disposed within an outer tube. the bearing is disposed between the hammer and the outer tube. the anvil has a bit head and is connected to the hammer.
Inventor(s): Rae Younger of Aberdeenshire (GB) for saudi arabian oil company, Richard Mark Pye of Aberdeenshire (GB) for saudi arabian oil company
IPC Code(s): E21B33/129, E21B7/06, E21B33/12
CPC Code(s): E21B23/02
Abstract: a system including a plug with a first end connected to a lower drill string and a second end connected to an upper drill string. the plug further includes a sealing element configured to seal against a reservoir pressure that is downhole from the plug, and an anchoring element configured to releasably couple the plug to a wellbore to disallow an axial movement of the plug in the wellbore. the plug is configured to couple to a retrieving tool. the retrieving tool includes a first engagement element configured to release the anchoring element, thereby allowing axial movement of the plug and retrieval of the upper drill string in order to shut in the wellbore.
20250034967. PHOTOPOLYMER CURING FOR WATER SHUT-OFF_simplified_abstract_(saudi arabian oil company)
Inventor(s): Abdullah Mohammed Alharith of Dhahran (SA) for saudi arabian oil company
IPC Code(s): E21B33/138, C09K8/44
CPC Code(s): E21B33/138
Abstract: a system and method for treatment of a subterranean formation are provided. the treatment includes pumping a water shut-off material into a wellbore and to a target zone in the subterranean formation and pumping a photo-curable polymer material to the target zone behind the water shut-off material, thereby forming a layer of photo-curable polymer material between the water shut-off material and the wellbore. an energy source may be directed to the layer of photo-curable polymer material until the layer of polymer solidifies to yield a solid barrier between the water shut-off material and the wellbore.
Inventor(s): Pareshkumar L. Patel of Al Khobar (SA) for saudi arabian oil company
IPC Code(s): E21B41/00, G01N33/00
CPC Code(s): E21B41/0021
Abstract: an apparatus for a cellar of a well includes a first track, a first mounting block displaceably mounted to the first track and a first gas detector mounted on the first mounting block. the apparatus further includes a displacement mechanism that displaces the first mounting block along the first track between: a first position located inside the cellar; and a second position located outside of the cellar. a related method includes: providing a first track; displaceably mounting a first mounting block to the first track; and mounting a first gas detector on the first mounting block. the method further includes displacing, via a first displacement mechanism, the first mounting block along the first track between: a first position located inside a cellar; and a second position located outside of the cellar.
Inventor(s): Mohammed A. AlHuraifi of Al-Qatif (SA) for saudi arabian oil company, Abdulrahman Mishkhes of Dhahran (SA) for saudi arabian oil company, Obiomalotaoso Leonard Isichei of Dhahran (SA) for saudi arabian oil company
IPC Code(s): E21B43/12, E21B47/117
CPC Code(s): E21B43/12
Abstract: this disclosure describes methods and systems for solving well completion problems in injection networks. a method involves generating respective water injection hydraulic simulation models for a plurality of injection wells in a water injection network, the water injection network including a plurality of well completion segments; generating, using the respective water injection hydraulic simulation models, respective simulated pressure profiles for the plurality of injection wells at one or more injection rates; determining respective internal yield pressure limits for the plurality of well completion segments; determining, based on the respective internal yield pressure limits and the respective simulated pressure profiles, a potential leak problem in the water injection network; and performing a corrective action to resolve the potential leak problem.
Inventor(s): Mohammed A. Al-Abdulhay of Ahsa (SA) for saudi arabian oil company, Sanjiv Kumar of Udhailiyah (SA) for saudi arabian oil company
IPC Code(s): E21B43/30, E21B43/25
CPC Code(s): E21B43/30
Abstract: methods and systems are disclosed. the method includes obtaining a well production dataset for a plurality of wells penetrating a reservoir, where the dataset includes a well production parameter set for each well, and partitioning the dataset into a plurality of training datasets based on a criterion. the method further includes, for each of the plurality of training datasets, training a machine learning (âmlâ) network to predict a future hydrocarbon production rate for a candidate well, where the training includes generating a production decline curve using the well production parameter set for well, fitting an empirical model to the production decline curve, and determining the future hydrocarbon production rate for the candidate well based on the model. the method still further includes determining a drilling target, using the trained ml network, for a future production well based on evaluating the future hydrocarbon production rate for each candidate well.
20250034982. TRIMMING ATTACHMENT TOOL AND METHODS_simplified_abstract_(saudi arabian oil company)
Inventor(s): Sameeh Issa Batarseh of Dhahran (SA) for saudi arabian oil company
IPC Code(s): E21B44/02, B23K26/08, B23K26/10, B23K26/36, E21B47/07
CPC Code(s): E21B44/02
Abstract: a tool for trimming an interior surface in a wellbore includes a jacket configured to be mounted at an external surface of a main body. the jacket includes a proximal end and a distal end, and also includes two or more mutually detachable portions. one or more fiberoptic cables extend to the distal end of the jacket and produce a ring-shaped laser beam for trimming the interior surface in the wellbore. a related method includes: mounting a jacket at an external surface of a main body, wherein the jacket includes two or more mutually detachable portions; extending one or more fiberoptic cables to a distal end of the jacket; deploying the main body and the jacket into a wellbore; via the one or more fiberoptic cables, producing a ring-shaped laser beam; and via the ring-shaped laser beam, trimming an interior surface in the wellbore.
Inventor(s): Hatem M. Elashmawi of Udhailiyah (SA) for saudi arabian oil company, Tarek D. Aboghoniem of Udhailiyah (SA) for saudi arabian oil company, Shadi M. Al-Hazmi of Al-Ahsa (SA) for saudi arabian oil company, Khalid A. Hejji of Al-Ahsa (SA) for saudi arabian oil company
IPC Code(s): E21B47/01, E21B47/14, E21B47/26
CPC Code(s): E21B47/01
Abstract: methods and systems for a telescopic stick and a data gathering verification system is disclosed. the method includes receiving a schedule for an equipment structure, obtaining parameter data and an ultrasonic transducer (ut) measurement from a telescopic stick, wherein the telescopic stick is configured to generate the ut measurement representing a condition of the equipment structure at an out-of-reach condition monitoring location (cml), and determining a verification assessment, wherein the verification assessment comprises a health report for the equipment structure based on a service acceptable range criterion. the method further includes inputting the ut measurement and parameter data into an artificial intelligence model, producing a degradation prediction from the model, and updating the schedule based on the verification assessment, the degradation prediction, and a service accepted range criterion, wherein the schedule is displayed by a handheld device configured to communicate with the data gathering and verification system.
Inventor(s): Yunlai Yang of Dhahran (SA) for saudi arabian oil company, Wei Li of Beijing (CN) for saudi arabian oil company, Maher I. Almarhoon of Al Qatif (SA) for saudi arabian oil company
IPC Code(s): E21B47/16, G01V1/32, G01V1/50
CPC Code(s): E21B47/16
Abstract: a well site may include a wellbore extending into a subsurface formation and a drilling rig with a top drive and a drive shaft to rotate a drill string extending into the wellbore. the drill string includes a drill bit at an end distal to the drilling rig to cut rock of the subsurface formation to form the wellbore. acoustic sensors may be positioned on the drive shaft, or the top drive, or the drill string. the acoustic sensors are configured to record and transmit drilling acoustic signals during a dummy drilling operation and a real drilling operation. a computer system may be in communication with the acoustic sensors. the computer system processes the drilling acoustic signals during the dummy drilling operation and the real drilling operation to minimize a drilling environmental effect by deducting a drilling environmental noise from the drilling acoustic signals to calculate clean drilling acoustic signals.
Inventor(s): Yu Zhang of Novi MI (US) for saudi arabian oil company, Praveen Kumar of New Hudson MI (US) for saudi arabian oil company, Anqi Zhang of Canton MI (US) for saudi arabian oil company, Nayan Engineer of Canton MI (US) for saudi arabian oil company
IPC Code(s): F02D41/00, F02D41/06
CPC Code(s): F02D41/0027
Abstract: a hydrogen-diesel dual-fuel engine that includes an engine block, where the engine block includes a cylinder outfitted with at least two hydrogen fuel injectors and a piston. the engine further includes an air-handling system that includes an intake manifold, an intake pipe, an exhaust pipe, a variable geometry turbocharger, and an exhaust gas recirculation system configured to recirculate exhaust gases from the exhaust pipe to the intake manifold. the engine further includes a two-step camshaft, where the two-step camshaft is configured with the air-handling system for exhaust re-breathing and late intake valve closing, and a port fuel injector system that provides hydrogen gas to the at least two hydrogen fuel injectors. the engine further includes a diesel injector, a common-rail fuel injection system, a plurality of sensors, and a controller configured to receive engine data from the plurality of sensors and to control operation of the hydrogen-diesel dual-fuel engine.
Inventor(s): Yu Zhang of Novi MI (US) for saudi arabian oil company, Praveen Kumar of New Hudson MI (US) for saudi arabian oil company, Anqi Zhang of Canton MI (US) for saudi arabian oil company, Nayan Engineer of Canton MI (US) for saudi arabian oil company
IPC Code(s): F02D41/00, F02D41/06
CPC Code(s): F02D41/0027
Abstract: a hydrogen-diesel dual-fuel engine that includes an engine block, where the engine block includes a cylinder outfitted with at least two hydrogen fuel injectors and a piston. the engine further includes an air-handling system that includes an intake manifold, an intake pipe, an exhaust pipe, a variable geometry turbocharger, and an exhaust gas recirculation system configured to recirculate exhaust gases from the exhaust pipe to the intake manifold. the engine further includes a two-step camshaft, where the two-step camshaft is configured with the air-handling system for exhaust re-breathing and late intake valve closing, and a port fuel injector system that provides hydrogen gas to the at least two hydrogen fuel injectors. the engine further includes a diesel injector, a common-rail fuel injection system, a plurality of sensors, and a controller configured to receive engine data from the plurality of sensors and to control operation of the hydrogen-diesel dual-fuel engine.
Inventor(s): Soliman A. Walaie of Dammam (SA) for saudi arabian oil company, Khaled Abu-Salem of Dhahran (SA) for saudi arabian oil company, Khalid A. Al-Binali of Dammam (SA) for saudi arabian oil company, Rashed F. Alhajri of Al-Nabiyah (SA) for saudi arabian oil company, Harish Badrinarayanan of Dhahran (SA) for saudi arabian oil company, Faleh S. Aldawsari of Hofuf (SA) for saudi arabian oil company
IPC Code(s): G01M3/04, G01N33/00, G05D1/689, G05D105/80
CPC Code(s): G01M3/04
Abstract: a robotic system includes a mobile platform; a gas payload suite mounted on the platform and including at least one gas emissions detection sensor; a navigation sensors suite mounted on the platform and including at least one navigation sensor; and a control system communicably coupled to the gas payload suite and the navigation sensor suite and configured to perform operations including identifying gas emissions measurements from the at least one gas emissions detection sensor, determining a location of gas emissions based at least in part on the identified gas emissions measurements, and operating a motion controller to move the mobile platform relative to the determined location of the gas emissions.
Inventor(s): Ziyad Hamad Alayadah of Dhahran (SA) for saudi arabian oil company, Mohamad Rizal Mohamad Yatim of Abqaiq (SA) for saudi arabian oil company
IPC Code(s): G01M13/00, G08B21/18
CPC Code(s): G01M13/00
Abstract: embodiments of the present disclosure are directed to a system for monitoring operating conditions of a saltwater disposal pump system, which includes a processing device that causes a controller to receive an alarm from the at least one machine that exceeds a predetermined alarm level indicative of an abnormal machine operation, receive a plurality of data from a plurality of sensors that are indicative of a current operating conditions of a saltwater disposal pump assembly, derive an expected value utilizing a statistical regression analysis, determine whether the expected value and a history of the plurality of data correlate at a point where the plurality of data exceeds the predetermined alarm level, determine whether a deviation from a predefined operating profile exceeds a predetermined machine data validation threshold value, validate the alarm, output an alert of the deviation and inhibit further operation of the saltwater disposal pump assembly.
Inventor(s): Raed Z Makeen of Cambridge MA (US) for saudi arabian oil company, S. Sherry Zhu of Cambridge MA (US) for saudi arabian oil company, Saleh Altuwayjiri of Cambridge MA (US) for saudi arabian oil company, Sehoon Chang of Cambridge MA (US) for saudi arabian oil company, Marta Antoniv of Cambridge MA (US) for saudi arabian oil company, Gawain Thomas of Cambridge MA (US) for saudi arabian oil company
IPC Code(s): G01N21/64, G01N33/28
CPC Code(s): G01N21/6428
Abstract: the disclosure relates to compositions, methods and systems that include gel particles that include a tag. the gel particles can be used to label drill cuttings generated during a drilling operation.
Inventor(s): Nour M. Alzamil of Dammam (SA) for saudi arabian oil company, Ezzedeen Alfataierge of Dhahran (SA) for saudi arabian oil company
IPC Code(s): G01V1/18, G01H9/00, G01V1/42, G05D1/661, G05D105/80, G05D109/25, G06Q10/0631
CPC Code(s): G01V1/18
Abstract: a method to perform measurements of a field is disclosed. the method includes disposing a landing dock at a target location in the field, the landing dock being coupled to a fiber optic cable for distributed fiber-optic sensing measurement, directing an unmanned aerial vehicle (uav) to land on the landing dock, the uav including an interrogator unit, communicatively coupling, in response to the uav landing on the landing dock, the interrogator unit and the fiber optic cable, sending, by the interrogator unit, a light pulse to the fiber optic cable, receiving, by the interrogator unit and in response to sending the light pulse, a backscattered light signal from the fiber optic cable, and generating, by the interrogator unit and based on the received backscattered light signal, a measurement of the target location.
Inventor(s): Salma AlSinan of Dhahran (SA) for saudi arabian oil company, Ali Aldawood of Safwa (SA) for saudi arabian oil company, Maksim Makarenko of Dhahran (SA) for saudi arabian oil company, Sixiu Liu of Dhahran (SA) for saudi arabian oil company
IPC Code(s): E21B7/04, E21B44/00, G01V1/28
CPC Code(s): G01V1/282
Abstract: a method for performing a seismic processing task using a machine-learned model developed using an in-domain adversarial attacker. the method includes obtaining a machine-learned model parameterized by a set of weights and generating a synthetic seismic dataset and associated target. the method further includes determining a noise profile for the synthetic seismic dataset in a frequency domain that when added, in a spatial-temporal domain, to the synthetic seismic dataset reduces a performance of the machine-learned model. the method further includes adding the noise profile to the synthetic seismic dataset forming a noisy seismic dataset and updating the set of weights of the machine-learned model based on the noisy seismic dataset and the target. the method further includes receiving a seismic dataset corresponding to a subsurface, processing the seismic dataset with the machine-learned model to form a predicted target, and developing a geological model for the subsurface using the predicted target.
Inventor(s): Apostolos Kontakis of Delft (NL) for saudi arabian oil company
IPC Code(s): G01V1/30
CPC Code(s): G01V1/301
Abstract: a method and a system for determining a minimum bounding box-based grid are disclosed. the method includes obtaining a seismic survey of an area and constructing a convex hull of the seismic survey area. further, the method includes determining a minimum bounding box containing a minimum convex hull area and generating two linear maps based on the minimum bounding box using a rotation angle and an axis origin. the two linear maps are used to generate a grid populated by geological models of a subsurface.
Inventor(s): Dwight W. Swett of Cypress TX (US) for saudi arabian oil company, Robert W. Adams of Houston TX (US) for saudi arabian oil company
IPC Code(s): G01V3/30, G01S13/02, G01S13/88
CPC Code(s): G01V3/30
Abstract: borehole radar systems send a radar pulse into the subterranean formation using a transmitter. the radar pulse is reflected back when it encounters a formation feature that has a different electromagnetic property. the receiver receives the reflected energy back. however, in a highly conductive rock or in the presence of highly conductive fluids in the borehole region, the radar pulse is not transmitted far enough with sufficient intensity to be detected by the receivers. this technology provides a design for a device which amplifies the radar transmitted power, using a metamaterial. the metamaterial enhanced device is designed for an electric source frequency ranging between 1-5 ghz. further, a metamaterial based antenna design achieves a directivity over d=20. this provides high intensity far field radiation into the subterranean formation which can be detected by the receivers with high signal to noise ratio (snr).
Inventor(s): Ahmed Alqahtani of Al Hofuf (SA) for saudi arabian oil company, Bayan Almomtan of Dammam (SA) for saudi arabian oil company
IPC Code(s): G06F30/28, G06F30/27
CPC Code(s): G06F30/28
Abstract: a method and a system for determining a well priority rank. the method includes obtaining well corrosion values and well barrier parameters, the well barrier parameters including properties of cement and casing and determining a corrosion severity rank using a machine learning model and based on the obtained well corrosion values and the obtained well barrier parameters. further, the method includes determining the well priority rank based on the determined corrosion severity rank and well criticality features, the well criticality features indicating an amount of damage caused by a deterioration of a well. the determined well priority rank is used to generate a wellbore drilling plan.
Inventor(s): Saud Al-Temyatt of Dhahran (SA) for saudi arabian oil company
IPC Code(s): G06Q10/0635, G06Q10/087
CPC Code(s): G06Q10/0635
Abstract: a system for hydrocarbon supply chain modification based on predicted hydrocarbon supply chain risk includes a hydrocarbon supply chain network element monitoring system; hydrocarbon supply chain modification hardware; a hydrocarbon supply chain data memory; a hydrocarbon supply chain risk prediction output translator; and a hydrocarbon supply chain risk predictor configured to cause the system to perform the following: identify a hydrocarbon supply chain for hydrocarbon supply chain risk prediction; receive a plurality of hydrocarbon supply chain variables for the hydrocarbon supply chain; identify a limiting factor of an affected hydrocarbon supply chain network element; predict an estimated lower supply bound and an estimated upper demand bound; determine whether the estimated lower supply bound meets or exceeds the estimated upper demand bound; generate a risk profile; generate a hydrocarbon supply chain risk mitigation levers; and implement the hydrocarbon supply chain risk mitigation lever.
Inventor(s): Saud Al-Temyatt of Dhahran (SA) for saudi arabian oil company
IPC Code(s): G06Q10/0637, G06Q10/067, G06Q10/083
CPC Code(s): G06Q10/06375
Abstract: a method for estimating supply chain carbon footprint comprises: identifying a supply chain for carbon footprint estimation, wherein the supply chain includes a delivery stream comprising a plurality of network elements; identifying supply chain variables including network element variables; in response to determining a change to at least one of the network element variables, generating, using at least one of the network element variables, a plurality of emissions factors, wherein each of the plurality of emissions factors is associated with an affected network element and represents an emissions volume for a predetermined time interval; modeling, using at least one emissions factor of the plurality of emissions factors, an estimated carbon footprint produced by the delivery stream; and providing the estimated carbon footprint for output.
Inventor(s): Hasan A. Nooruddin of Dhahran (SA) for saudi arabian oil company, Mohammed A. Shahri of Dhahran (SA) for saudi arabian oil company, Aidah G. Zahrani of Dammam (SA) for saudi arabian oil company
IPC Code(s): G06Q50/02, E21B41/00, G06F17/18
CPC Code(s): G06Q50/02
Abstract: systems and methods for stochastic modeling for drilling forecasts. one embodiment includes determining a plurality of potential well sites and a well attribute, determining available assets for drilling a well, and determining historical wells with a similar attribute. some embodiments include using a stochastic process to estimate drilling costs and drilling times for drilling the well at each of the plurality of potential well sites, generating a predetermined number of drilling schedules for the plurality of potential well sites, and predicting a cost and time estimate for drilling of each well at the plurality of potential well sites for each of the predetermined number of drilling schedules. some embodiments include determining a probability distribution of cost for implementing a subset of the predetermined number of drilling schedules for the predetermined time period and providing the probability distribution of cost for output prior to a start of the predetermined time period.
Inventor(s): Dorota A. Karas of Addlestone (GB) for saudi arabian oil company, Mohammed A. Alabbad of Dammam (SA) for saudi arabian oil company, Serkan Dursun of Dhahran (SA) for saudi arabian oil company
IPC Code(s): G06Q50/20, G06F3/147, G06F21/31
CPC Code(s): G06Q50/2057
Abstract: a method for bi-directional communication using a standby screen is disclosed. the method includes displaying, within the standby screen displayed on each of a number of computing devices of an organization, a message that prompts a user-specific response from each user of the organization, receiving, in response to displaying the message and from the computing devices, the user-specific response from at least one responding user, generating a result by at least analyzing the user-specific response from the at least one responding user, and dynamically adjusting the message for subsequent displaying within the standby screen to prompt a subsequent user-specific response from each of the users.
Inventor(s): Mohannad M. SHAHRANI of Udhailiyah (SA) for saudi arabian oil company, Tarek D. ABOGHONIEM of Udhailiyah (SA) for saudi arabian oil company, Yahya A. ALI of Udhailiyah (SA) for saudi arabian oil company
IPC Code(s): G06Q90/00
CPC Code(s): G06Q90/205
Abstract: a system for safe evacuation management of an industrial facility includes an analyzer operable to receive hazardous event indications and situational input. the analyzer can include a cloud engine operative to determine, from the hazardous event indications and the situational input, one or more of location, size, expansion rate, concentration, and motion direction and rate of a hazard at the industrial facility. the analyzer can also include a personnel tracking module operative to generate impacted personnel information from the hazardous event indications and the situational input, an evacuation route engine operative to receive the dynamic-state cloud representation, the impacted personnel information, and a plant model, and to generate therefrom an evacuation route representation, and a rendering engine operative to graphically represent an evacuation route customized for impacted personnel for delivery to user devices of impacted personnel.
SAUDI ARABIAN OIL COMPANY patent applications on January 30th, 2025
- SAUDI ARABIAN OIL COMPANY
- B65G5/00
- C25B1/04
- F17C1/00
- CPC B65G5/00
- Saudi arabian oil company
- C10L1/04
- CPC C10L1/04
- E21B4/00
- E21B4/14
- CPC E21B4/003
- E21B33/129
- E21B7/06
- E21B33/12
- CPC E21B23/02
- E21B33/138
- C09K8/44
- CPC E21B33/138
- E21B41/00
- G01N33/00
- CPC E21B41/0021
- E21B43/12
- E21B47/117
- CPC E21B43/12
- E21B43/30
- E21B43/25
- CPC E21B43/30
- E21B44/02
- B23K26/08
- B23K26/10
- B23K26/36
- E21B47/07
- CPC E21B44/02
- E21B47/01
- E21B47/14
- E21B47/26
- CPC E21B47/01
- E21B47/16
- G01V1/32
- G01V1/50
- CPC E21B47/16
- F02D41/00
- F02D41/06
- CPC F02D41/0027
- G01M3/04
- G05D1/689
- G05D105/80
- CPC G01M3/04
- G01M13/00
- G08B21/18
- CPC G01M13/00
- G01N21/64
- G01N33/28
- CPC G01N21/6428
- G01V1/18
- G01H9/00
- G01V1/42
- G05D1/661
- G05D109/25
- G06Q10/0631
- CPC G01V1/18
- E21B7/04
- E21B44/00
- G01V1/28
- CPC G01V1/282
- G01V1/30
- CPC G01V1/301
- G01V3/30
- G01S13/02
- G01S13/88
- CPC G01V3/30
- G06F30/28
- G06F30/27
- CPC G06F30/28
- G06Q10/0635
- G06Q10/087
- CPC G06Q10/0635
- G06Q10/0637
- G06Q10/067
- G06Q10/083
- CPC G06Q10/06375
- G06Q50/02
- G06F17/18
- CPC G06Q50/02
- G06Q50/20
- G06F3/147
- G06F21/31
- CPC G06Q50/2057
- G06Q90/00
- CPC G06Q90/205
