Provided is a rising and lowering method and apparatus and a computer readable storage medium. The rising and lowering method is used to adjust the distance between a panel and an electrode that are spaced apart from and parallel with each other. The method includes steps of: detecting a position of a geometric center of a panel and manipulating geometric center to move along a first direction by a first predetermined distance, wherein the first direction is perpendicular to a direction of panel; and setting up a first area and a second area which are symmetrical with respect to geometric center on panel, and manipulating first area and second area to move along a first direction by a second predetermined distance. The first predetermined distance is not equal to second predetermined distance. The invention can suppress the occurrence of warp on panel and ensure the panel to endure uniform force.

A battery monitoring system includes at least one memory configured to store a first coordinate-related data set in which coordinate data indicating a position of an electrode moved in each of a plurality of processes is connected with inspection data and/or measurement data of the electrode obtained in the plurality of processes, and an identification data set including an electrode identifier (ID) identifying the electrode. The battery monitoring system further includes at least one processor configured to connect the electrode ID with the coordinate data of the first coordinate-related data set corresponding to the electrode ID, and send monitoring data for the electrode, based on data about the connection of the electrode ID with the coordinate data.

The disclosure relates to a method for error-minimized electrolysis stack contacting. The method includes: providing at least one electrolysis stack having at least two conductive, spaced-apart plates; providing an assembly device having at least one mount for at least two cores, wherein each core has a plug end and a connection end; providing a control device for automatic detection and/or for electrical testing; providing a contacting unit having at least one plug-in unit, wherein the plug-in unit is electrically connectable to the at least two plug ends of the at least two cores; providing at least one coding on the at least one plug-in unit and/or the respective plug end and/or the respective connection end and/or on the respective core of the at least two cores; carrying out an automatic acceptance test, wherein the position of the connection ends is controlled on the basis of the coding; evaluating the result; and transmitting the acceptance test result to a piece of data processing equipment and carrying out a predetermined acceptance test action.

A battery monitoring system includes at least one memory configured to store a first coordinate-related data set in which coordinate data indicating a position of an electrode moved in each of a plurality of processes is connected with inspection data and/or measurement data of the electrode obtained in the plurality of processes, and an identification data set including an electrode identifier (ID) identifying the electrode. The battery monitoring system further includes at least one processor configured to connect the electrode ID with the coordinate data of the first coordinate-related data set corresponding to the electrode ID, and send monitoring data for the electrode, based on data about the connection of the electrode ID with the coordinate data.