Your cart is empty
Add prompt packs to continue
This masterful collection represents the cutting edge in hydrocarbon engineering, designed for professionals who demand technical precision and operational efficiency. By integrating artificial intelligence with industry pillars—from seismic exploration to advanced refining—this compendium transforms complex data into high-impact strategic decisions, ensuring asset optimization across the entire oil value chain. Each prompt has been structured under instructional design standards to solve critical challenges such as well stability, process decarbonization, and global logistics management. It is the definitive tool for engineers and consultants seeking to lead the energy transition through robust, safe and economically viable technical solutions in a highly competitive global market.
100 resources included
He acts as a Senior Petrochemical Process Engineer with more than 20 years of experience in the design and optimization of secondary conversion units. Your task is to generate a comprehensive technical report and an operational optimization guide for a Heavy Naphtha Hydrotreatment (NHT) unit that processes a load of [FLOW_FLOW] bpd, with the objective of preparing the feed for a high severity Catalytic Reforming unit. Analyzes in depth the kinetics of the hydrodesulfurization (HDS), hydrodenitrogenation (HDN) and hydrodeoxygenation (HDO) reactions, considering that the load has a sulfur concentration of [CONCENTRACION_AZUFRE_PPM] and nitrogen of [CONCENTRACION_NITROGENO_PPM]. You must evaluate the selectivity of the [CATALYST_TYPE: CoMo/NiMo] type catalyst supported on alumina, justifying its choice against the metallic impurities (Arsenic, Lead, Silicon) that could be present if the gasoline comes from a [CHARGE_ORIGIN: e.g. Coker or FCC] unit. Develop a temperature profile model along the reactor bed, detailing the expected exotherm and management of the [COOLING_SYSTEM: Hydrogen Quench/Heat Exchange] system. It is imperative that the analysis includes the impact of the Hydrogen/Hydrocarbon ratio ([RELATION_H2_HC]) and the Partial Pressure of Hydrogen on the inhibition of coke formation and olefin saturation, avoiding color degradation and gum formation in the final product. Provides a detailed section of mass and energy balances for the stripping and subsequent fractionation section. The objective is to ensure that the treated naphtha meets an ultra-low sulfur specification (< 0.5 ppm) and an end boiling point of [END_BOILING_POINT_C]. It also includes a 'Troubleshooting' protocol to mitigate the increase in pressure drop (Delta P) in the reactor due to the polymerization of diolefins or deposition of iron scales. Finally, it integrates a sustainability vision by evaluating the specific energy consumption (GigaJoules per ton of load) and proposes thermal integration strategies to reduce the carbon footprint of the unit, comparing the use of direct-fired furnaces versus high-efficiency effluent/load preheaters.
He acts as a Senior Directional Drilling Engineer with over 20 years of experience managing complex drilling operations and real-time data analysis. Your main objective is to supervise and optimize the 'MWD Telemetry Monitoring' process for a well of type [Well Type: Exploratory/Development/Injection] located in the [Field Name] field, currently operating at a depth of [Current Depth] meters/feet. I require a thorough technical analysis that ensures the integrity of the data transmission from the bottom of the hole (BHA) to the surface, ensuring that the trajectory remains within the geological window and the established directional plan. It begins by evaluating the quality of the mud pulse telemetry (Mud Pulse Telemetry) or electromagnetic (EM) signal, as appropriate for this project. Analyzes the current signal-to-noise ratio (SNR), considering drilling mud properties such as [Mud Density] and [Plastic Viscosity], and how these affect the attenuation of the pressure wave. You must identify possible anomalies in the pulse signatures that may indicate premature wear of the pulser, blockage by bridging agents (LCM) or mechanical interference due to the speed of the mud pumps at [Pump Flow in GPM]. Provides a detailed interpretation of the latest Survey records obtained: Inclination ([Inclination Value]°), Azimuth ([Azimuth Value]°) and Toolface ([Toolface Type: Magnetic/Gravity]). Cross-reference this information with surface drilling parameters such as WOB, Torque and RPM to diagnose the dynamic behavior of the string. If you detect a deviation greater than [Tolerable Margin of Error] degrees with respect to the original plan, immediately propose a correction strategy (slide drilling or rotation with a steerable system) calculating the 'dogleg severity' (DLS) necessary to return to the target. Develop a mitigation protocol for specific risks detected in monitoring, such as excessive bottom vibrations (Whirl, Stick-Slip or Lateral Shocks) that exceed the [Vibration Threshold in G's] defined in the drilling program. Explains how MWD telemetry should be adjusted in its baud rate to prioritize critical safety data over formation data (LWD) in intervals of high geological complexity or loss of circulation zones. Finally, it generates a synthesized technical report that includes the health status of the tool (Battery life, Temperature logs), the efficiency of surface decoding, and a data-based recommendation for the next [Number of Hours] hours of operation. The report must be oriented towards critical decision making by the Company Man and the Geosteering team, ensuring that the well reaches its Geological Target [Target Name] with maximum operational efficiency and the shortest non-productive time (NPT).
He acts as a Senior Refining Engineer and Aviation Fuel Formulation Specialist with over 20 years of experience in quality control and hydrocarbon logistics. Your objective is to perform a comprehensive technical analysis and propose a comprehensive storage stability management strategy for a specific batch of Jet A-1 fuel that is stored at [GEOGRAPHIC_LOCATION] under the conditions of [INFRASTRUCTURE_TYPE]. The analysis should address the risks of chemical and physical degradation during a prolonged period of inactivity or strategic storage. The core of the report should focus primarily on the oxidative and thermal stability of the middle distillate, taking as mandatory technical reference the ASTM D3241 (JFTOT) standard and the evaluation of existing and potential gums according to ASTM D381. You must evaluate how intrinsic factors such as aromatic compound content, residual sulfur species, and the presence of trace metals (especially copper) catalyze the formation of sludge and varnish in the fuel system. Considers the external variables of [AVERAGE_AMBIENT_TEMPERATURE] and vapor pressure to model the rate of product degradation over a cycle of [STORAGE_TIME_MONTHS]. Develop a detailed technical section that quantifies the effectiveness and need for dosing of Antioxidant (AO) and Metal Deactivator (MDA) additives according to the guidelines of the AFQRJOS (Check List) regulations and Def Stan 91-091. Compare the projected dosage of [DOSE_ADITIVO_PPM] against the maximum allowed limits and predict the color stability (Saybolt) and the formation of insoluble particles based on the oxidation kinetics of the unsaturated hydrocarbons present in the sample from [ORIGEN_DEL_CRUDO_O_UNIIDAD_PROCESO]. Finally, develop a proactive monitoring protocol that includes sampling frequencies at high, medium and low levels (multi-level sampling), critical control points in the tank [STORAGE_TANK_ID], and alert thresholds for water separation rate (MSEP) and electrical conductivity. The deliverable must include a simulation of extreme degradation scenarios and engineering recommendations to mitigate peroxide formation and microbiological growth at the fuel-water interface through drainage and moisture control strategies.