A healthcare system capable of ingesting hydrogen, oxygen, or the like required based on a vital sign of a user by ingestion with a portable gas generator, whereby the healthcare system can ingest an appropriate gas according to the physical condition of the user. The healthcare system includes: a portable gas generator capable of orally suctioning a gas selected from hydrogen and/or a mixed gas of a gas having an effect of promoting neural activity and/or blood circulation activity of an oxygen-containing living body, the gas being produced by electrolysis of an electrolyte filled in an internal electrolysis tank of the healthcare system; and a wearable portable terminal capable of detecting a vital sign that has been fixed in contact with a part of a human body part and has been digitized.

The present disclosure provides a method and an Internet of Things system for regulating a gas in-home pressure based on smart gas. The method includes: determining a gas in-home pressure regulation scheme, and the gas in-home pressure regulation scheme including a pressure regulation parameter of a gas device; generating, based on the gas in-home pressure regulation scheme, a pressure regulation instruction; regulating, based on the pressure regulation instruction, a gas in-home pressure of at least one floor; and transmitting the gas in-home pressure regulation scheme to a smart gas user terminal.

A system and method for remote monitoring and control of landfill and recycling operations provide an intelligent centralized platform for remote, real-time industrial data gathering and process control for management of landfill and recycling operations such as leachate, gas, water and other liquids. The system and method can directly upload machine data (such as liquid volumes, flows, level, equipment runtime, sorter data, status, etc) into a centralized platform. This data can be used for analytics and automation of processes and equipment control.

A system for flare combustion control includes a sound speed measurement device for measuring sound speed in a flare vent gas, and a flare combustion controller including a memory and a processor. The processor is configured to receive the measured sound speed and determine, based on the measured sound speed, a molecular weight of the flare vent gas. The processor is further configured to determine, based on the determined molecular weight, a net heating value of the flare vent gas, and adjust the net heating value of the flare vent gas by regulating an amount of a supplemental fuel gas in the flare vent gas.

Various embodiments of the teachings herein include a method for optimizing a gasifier model. Some examples include: virtually partitioning the gasifier by temperature; enabling the gasifier model to input feed split from total feed based on a respective proportion coefficient in each virtual partition to perform gasification reactions independently by each virtual partition; enabling the gasifier model to determine a virtual value of a gasifier parameter after mixing the virtual partitions, quenching and shifting when gasification reactions reach an equilibrium in each virtual partition; determining a measured value of the gasifier parameter when the total feed is input; and adjusting the proportion coefficients based on a comparison result between the measured value and the virtual value of the gasifier parameter.

Embodiments of the present disclosure provide for generation and use of multiple representations of a processing plant, for example a refinery plant. In some embodiments a first representation is utilized to visualize the component(s) and/or connection(s) of the processing plant, with a second representation utilized to process one or more aspect(s) of the processing plant. The first representation in some embodiments represents the physical components and/or connections between such components to enable intuitive visualization and monitoring of the components thereof. The second representation in some embodiments represents a virtualized representation of the physical components and/or connections between such components in a manner that is better processable via one or more computing process(es). Such processing is performable to generate data for controlling configuration and/or operation of component(s) in the processing plant.

Embodiments of the present disclosure provide for generating at least one optimized operational parameter associated with a processing plant, such as an oil refinery. Embodiments of the disclosure utilize a multi-horizon optimization process, for example that generates optimized operational parameter(s) based on at least a long-horizon optimized plan and a short-horizon optimized plan. Some embodiments utilize the multiple horizons to generate the optimized operational parameter(s) via different process(es) based on configuration(s) and/or characteristic(s) of a processing plant. The resulting optimized operational parameter(s) enable operation of the processing plant during the immediate term in a manner that is optimized specifically for the processing plant in its particular configuration.

The present disclosure provides a method and an Internet of Things system for managing a gas pressure based on smart gas. The method includes: determining a gas in-home pressure regulation scheme, and the gas in-home pressure regulation scheme including a pressure regulation parameter of a gas device; generating, based on the gas in-home pressure regulation scheme, a pressure regulation instruction; regulating, based on the pressure regulation instruction, a gas in-home pressure of at least one floor; and transmitting the gas in-home pressure regulation scheme to a smart gas user terminal.

An industrial gas production plant operable to produce a feedstock gas at a variable production rate for supply to the downstream process; and a gas storage resource operable to store produced feedstock gas, the method comprising: determining the pressure of feedstock gas in a supply feed line to the downstream process; selectively controlling, using a control system, a flow of feedstock gas from the supply feed line to the gas storage resource or from the gas storage resource to the supply feed line in response to the determined pressure in order to regulate the pressure of the feedstock gas in the supply feed line to the downstream process at a predetermined set point pressure; and selectively controlling, using a control system, a flow rate of feedstock gas in the supply feed line to the downstream process in dependence upon at least one operational parameter of the gas storage resource.

A smart gas emergency gas supply equipment is provided. The smart gas emergency gas supply equipment may be an emergency vehicle including a skid-mounted vehicle, a gas storage tank, an extensible pipeline group, a pressure regulating device, a gasification device, and a control module. The control module may be configured to determine, based on an emergency gas supply plan of the smart gas emergency gas supply device, operating parameters of the pressure regulating device and the gasification device. The emergency gas supply plan at least includes a gas source selection plan and a gas demand, the gas source selection plan may at least include a gas pipeline network crossover and a gas tank direct supply.