The disclosure relates to a vehicular energy storage module, including an outer casing having two parallel first and second side walls, parallel upper and lower walls, and opposing first and second ends; a battery module housed inside the casing, the battery module including a plurality of battery cell groups, where each battery cell group includes at least two battery cells which are electrically interconnected to each other and arranged side-by-side between the side walls. The battery module comprises multiple heat pipes, wherein each heat pipe comprise parallel first and second heat pipe sections connected by intermediate sections at their respective ends. At least one heat pipe has a first heat pipe section electrically connected to the positive poles of a first battery cell group and a second heat pipe section electrically connected to the negative poles of an adjacent battery cell group. The heat pipes are arranged in contact with positive and negative poles of adjacent battery cell groups on opposite sides of the battery module; wherein the battery cell groups making up the battery module are connected in series.

The disclosure relates to a vehicular energy storage module, including an outer casing having two parallel first and second side walls, parallel upper and lower walls, and opposing first and second ends; a battery module housed inside the casing, the battery module including a plurality of battery cell groups, where each battery cell group includes at least two battery cells which are electrically interconnected to each other and arranged side-by-side between the side walls. The battery module comprises multiple heat pipes, wherein each heat pipe comprise parallel first and second heat pipe sections connected by intermediate sections at their respective ends. At least one heat pipe has a first heat pipe section electrically connected to the positive poles of a first battery cell group and a second heat pipe section electrically connected to the negative poles of an adjacent battery cell group. The heat pipes are arranged in contact with positive and negative poles of adjacent battery cell groups on opposite sides of the battery module; wherein the battery cell groups making up the battery module are connected in series.

A battery system has a plurality of battery cells including a first battery cell. Each battery cell includes a casing enclosing an anode and a cathode. The battery system also includes a first fluid circulation system with a plurality of fluid conduits including a first fluid conduit that is adjacent to the first battery cell, where the first fluid circulation system is configured to circulate a first fluid through the battery system in a first direction. The battery system also includes a second fluid circulation system with a plurality of fluid conduits including a first fluid conduit that is adjacent to the first fluid conduit of the first fluid circulation system. The second fluid circulation system is configured to circulate a second fluid through the battery system in a second direction that is opposite the first direction.

The present disclosure relates to a can for a secondary battery and a secondary battery. The can for the secondary battery can include a can body, in which an electrode assembly accommodation part accommodating an electrode assembly are formed. The can body can be opened to one side. The secondary battery can include a cover to cover one end of the can body to seal an opening and in which a through-hole through which an electrode lead of the electrode assembly passes. The can body can include a body heat pipe that transfers heat so that the heat is dissipated through the can body when the heat generated in the electrode lead is transferred from the cover to the can body.

The present disclosure relates to a can for a secondary battery and a secondary battery. The can for the secondary battery can include a can body, in which an electrode assembly accommodation part accommodating an electrode assembly are formed. The can body can be opened to one side. The secondary battery can include a cover to cover one end of the can body to seal an opening and in which a through-hole through which an electrode lead of the electrode assembly passes. The can body can include a body heat pipe that transfers heat so that the heat is dissipated through the can body when the heat generated in the electrode lead is transferred from the cover to the can body.

A battery pack includes: a battery stack; a housing that houses the battery stack; and a skeleton part that is housed in the housing and reinforces the housing. The skeleton part includes a stem extending in a first direction, a plurality of branch portions that protrude from the stem and are arranged in a row in the first direction, and a plurality of housing spaces, each of the housing spaces being defined by a pair of branch portions disposed adjacently to each other and housing the battery stack. The stem and the plurality of branch portions are fixed to the housing.

A battery pack includes: a battery stack; a housing that houses the battery stack; and a skeleton part that is housed in the housing and reinforces the housing. The skeleton part includes a stem extending in a first direction, a plurality of branch portions that protrude from the stem and are arranged in a row in the first direction, and a plurality of housing spaces, each of the housing spaces being defined by a pair of branch portions disposed adjacently to each other and housing the battery stack. The stem and the plurality of branch portions are fixed to the housing.

A partition member has a thickness direction and a surface direction perpendicular to the thickness direction, and which separates single cells that make up an assembled battery in the thickness direction, or a single cell that makes up the assembled battery in the thickness direction and a member other than the single cells. The partition member includes, in the interior thereof, a fluid having a boiling point at normal pressure of 80° C. to 250° C., and a flow channel of the fluid extending along the surface direction. The fluid is held in a fluid holding part, and the fluid holding part is hermetically sealed by a packaging material.

A battery pack includes a battery column and a liquid cooling tube. The battery column includes at least two batteries, and the batteries are arranged in a first direction. The liquid cooling tube is disposed on a surface of the battery column and is configured to dissipate heat for the batteries. The liquid cooling tube includes cooling portions, and the cooling portions are portions having orthographic projections on the battery column. The orthographic projections of the cooling portions on the battery column are cooling regions. The cooling portions extend in a second direction, and the second direction is not parallel to the first direction.

The disclosure relates a battery technology field, and in particular, relates to a battery pack. The battery pack includes a battery array and a liquid cooling tube. The battery array includes at least two batteries, and the batteries are arranged in a first direction. The liquid cooling tube is disposed on a surface of the battery array and is configured to dissipate heat for the batteries. The liquid cooling tube includes cooling portions, and the cooling portions are portions of an orthographic projection of the liquid cooling tube on the battery array. Orthographic projections of the cooling portions on the battery array are cooling regions. In the battery array, at least one of the batteries is located outside a range of the cooling portions.