Patent ID: 11917010
Assignee: CHENGDU QINCHUAN IOT TECHNOLOGY CO., LTD.
Field: Chemical engineering (Chemistry)
Classification: CPC G  H  B  F | IPC G  H

Claim 0:
1. A method for gas purification management in a storage and distribution station, wherein
the method is implemented based on an Internet of Things (IOT) system, and the IoT system includes a smart gas user platform, a smart gas service platform, a smart gas sensor network platform, a smart gas object platform, and a smart gas device management platform; wherein
the smart gas service platform is configured to send an operation parameter to the smart gas user platform;
the smart gas object platform is configured to obtain a gas quality condition parameter of a raw gas, and transmit the gas quality condition parameter of the raw gas to the smart gas device management platform through the smart gas sensor network platform;
the method for gas purification management in a storage and distribution station is performed by a processor of the smart gas device management platform, the method comprising:
obtaining the gas quality condition parameter of the raw gas, the gas quality condition parameter being obtained based on the storage and distribution station; wherein the gas quality condition parameter at least includes at least one of a hydrogen sulfide content, a carbon dioxide content, and a target purification volume;
predicting, based on the at least one of the hydrogen sulfide content, the carbon dioxide content, and the target purification volume, at least one group of recommended operation parameters and at least one effect score corresponding to the at least one group of recommended operation parameters through a recommended operation parameter prediction model, wherein the recommended operation parameter prediction model is a machine learning model obtained through a training process, comprising:
generating a second training sample and a second label, wherein the second training sample is obtained based on the gas quality condition parameter and a purification parameter of the raw gas in an actual purification process, and the second label is an actual operation parameter and an actual effect score corresponding to the second training sample;
inputting the second training sample and the second label into an initial recommended operation parameter prediction model to determine a prediction result of recommended operation parameter and effect score;
determining a loss function based on the prediction result of the recommended operation parameter and effect score and the second label;
updating the initial recommended operation parameter prediction model based on the loss function;
obtaining the recommended operation parameter prediction model until the initial operation parameter prediction model meets preset conditions;
determining, based on the at least one effect score and at least one energy consumption information, at least one recommendation coefficient corresponding to the at least one group of recommended operation parameters;
determining, based on the at least one group of recommended operation parameters and the at least one recommendation coefficient, the operation parameter in a purification process; wherein the operation parameter is used for a purification operation of the raw gas, the operation parameter includes at least one of an amine liquid circulation volume, an absorption tower temperature, and an amine liquid feeding location, and the energy consumption information is determined through a process including:
predicting, based on the operation parameter, the energy consumption information corresponding to the operation parameter through an energy consumption prediction model, an input of the energy consumption prediction model including the operation parameter, the gas quality condition parameter, an environmental condition and a purification parameter, and an output of the energy consumption prediction model including the energy consumption information corresponding to the operation parameter, wherein the environmental condition includes a position and a temperature of the environment where the gas device is located, and the purification parameter includes a purification type, a gas purification device type, and a purification standard in a purification process;
generating, based on the operation parameter, a remote control instruction and sending the remote control instruction to the smart gas sensor network platform; and
sending, based on the smart gas sensor network platform, the remote control instruction to the smart gas object platform for controlling a gas purification device performing the purification operation.