The present disclosure provides for advantageous electrolyte filling systems/methods utilizing predetermined pressure/flow cycles. The disclosed electrolyte filling system enables filling of at least one jelly roll assembly under vacuum. The disclosed electrolyte filling system is capable of simultaneously filling at least two multi-core lithium ion batteries. The disclosed multi-core lithium ion batteries include a plurality of jelly roll assemblies positioned within cavities, which are further positioned within a sealed enclosure. The disclosed jelly roll assemblies are electrically connected to at least one bus bar. The disclosed bus bars include at least one flexible connective structure to electrically connect to a sealed enclosure.

A method for manufacturing a solid-state battery, the method preventing a reaction between lithium metal in a negative electrode and a sulfide-based solid electrolyte material in a solid electrolyte membrane during a pressurization process for binding electrode members with each other, and the method providing a solid-state battery which has low porosity in a positive electrode and the solid electrolyte membrane and reduced generation of a short-circuit, and the method providing an improved battery production yield.

A method for manufacturing a solid-state battery, the method preventing a reaction between lithium metal in a negative electrode and a sulfide-based solid electrolyte material in a solid electrolyte membrane during a pressurization process for binding electrode members with each other, and the method providing a solid-state battery which has low porosity in a positive electrode and the solid electrolyte membrane and reduced generation of a short-circuit, and the method providing an improved battery production yield.

Disclosed are a battery cell case having a dissoluble mechanism and a high-capacity battery. The battery cell case comprises at least one dissoluble mechanism, which comprises an isolating assembly and a dissoluble assembly; the battery cell case is provided with an opening, where the isolating assembly and the dissoluble mechanism are arranged sequentially in a direction away from the battery cell case; when the dissoluble assembly contacts with electrolyte outside the battery cell case, the isolating assembly is opened because the dissoluble mechanism is dissolved, thereby the interior of the battery cell case communicates with the exterior of the battery cell case. The high-capacity battery comprises at least two battery cells and an electrolyte storage pipeline, where the electrolyte storage pipeline comprises a main pipeline and a plurality of branch pipes, the branch pipes are in one-to-one correspondence to the openings of the battery cell cases.

Disclosed are a battery cell case having a dissoluble mechanism and a high-capacity battery. The battery cell case comprises at least one dissoluble mechanism, which comprises an isolating assembly and a dissoluble assembly; the battery cell case is provided with an opening, where the isolating assembly and the dissoluble mechanism are arranged sequentially in a direction away from the battery cell case; when the dissoluble assembly contacts with electrolyte outside the battery cell case, the isolating assembly is opened because the dissoluble mechanism is dissolved, thereby the interior of the battery cell case communicates with the exterior of the battery cell case. The high-capacity battery comprises at least two battery cells and an electrolyte storage pipeline, where the electrolyte storage pipeline comprises a main pipeline and a plurality of branch pipes, the branch pipes are in one-to-one correspondence to the openings of the battery cell cases.

Provided is a technology capable of improving the impregnation efficiency of an electrolyte into an electrode body. In accordance with a preferable one embodiment of a method for manufacturing a secondary battery herein disclosed, a method for manufacturing a secondary battery including an electrode body, an electrolyte, and a battery case is provided. The manufacturing method includes a solution introducing step of introducing the electrolyte into the battery case, and a pressure reducing step of reducing the pressure in the battery case after the solution introducing step. After an elapse of 10 hours or more after the solution introducing step, the pressure reducing step is carried out.

Provided is a technology capable of improving the impregnation efficiency of an electrolyte into an electrode body. In accordance with a preferable one embodiment of a method for manufacturing a secondary battery herein disclosed, a method for manufacturing a secondary battery including an electrode body, an electrolyte, and a battery case is provided. The manufacturing method includes a solution introducing step of introducing the electrolyte into the battery case, and a pressure reducing step of reducing the pressure in the battery case after the solution introducing step. After an elapse of 10 hours or more after the solution introducing step, the pressure reducing step is carried out.

A carrier includes a base assembly movably coupled to a transfer rail, a seating plate disposed above the base assembly and having a battery cell seated on an upper surface thereof, a pressurizing and fixing portion for fixing the battery cell to the seating plate by pressurizing the battery cell, and an elastic member for pressurizing the pressurizing and fixing portion toward the seating plate side, wherein the pressurizing and fixing portion is coupled to the base assembly to move in a first direction, which is a horizontal direction, and a second direction, which is a vertical direction.

A battery and an electric apparatus are described. The battery includes a firefighting pipe and a plurality of battery cells provided with a pressure relief mechanism. The pressure relief mechanism is configured to be actuated and release internal pressure in a first direction when the internal pressure or temperature of the battery cell reaches a threshold; the firefighting pipe is arranged on a side of the plurality of battery cells that is provided with the pressure relief mechanism, and is disposed in a staggered manner with the pressure relief mechanism; and the firefighting pipe is provided with a drainage opening, where the drainage opening is configured to discharge a firefighting medium toward the pressure relief mechanism when the pressure relief mechanism is actuated, so as to cool the battery cell. The battery allows the firefighting medium to more quickly cool a battery cell, thereby improving safety of the battery.

A battery and an electric apparatus are described. The battery includes a firefighting pipe and a plurality of battery cells provided with a pressure relief mechanism. The pressure relief mechanism is configured to be actuated and release internal pressure in a first direction when the internal pressure or temperature of the battery cell reaches a threshold; the firefighting pipe is arranged on a side of the plurality of battery cells that is provided with the pressure relief mechanism, and is disposed in a staggered manner with the pressure relief mechanism; and the firefighting pipe is provided with a drainage opening, where the drainage opening is configured to discharge a firefighting medium toward the pressure relief mechanism when the pressure relief mechanism is actuated, so as to cool the battery cell. The battery allows the firefighting medium to more quickly cool a battery cell, thereby improving safety of the battery.