Abstract: The invention relates to a battery module housing (2001, . . . 2004) for a battery pack (10), characterized in that: the battery module housing (2001, . . . 2004) can contain a large number of battery cells (100111, . . . 100432) which each have a large wall surface (1201, 1202) and a small wall surface (1301, 1302), of which small wall surface the surface area is less than a surface area of the large wall surface (1201, 1202), wherein the battery cells (100119, 100129, 100132, 100142, 100219, 100229, 100232, 100242, 100319, 100329, 100332, 100342, 100419, 100432) which can be arranged adjacent to outer sides of the battery pack (10) can be oriented in such a way that their large wall surfaces (1201, 1202) run along the outer sides, so that a force which acts on one of the outer sides can initially be received by one of the large wall surfaces (1201, 1202), and also to a battery module (201, 204), to a battery pack (10), to a battery, to a vehicle and also to a method for producing a battery module (201, . .

Abstract: The invention relates to a temperature-controlling device for a battery module, having a flow space (4) which has a multiplicity of spacer elements (11) and is essentially closed. The spacer elements (11) are arranged within the flow space (4) and the temperature-controlling device (3) further has a flow deflection unit (15) which is arranged within the flow space (4) and has a longitudinal direction (16) extending along the flow deflection unit (15) from a first end (24) to a second end (25) of said flow deflection unit (15). The flow deflection unit (15) forms a first side face (17) and a second side face (18) which sides are arranged in the longitudinal direction (16) on opposite sides of the flow deflection unit (15), and wherein at least portions of the first side face (17) and the second side face (18) are arranged directly adjacent to a spacer element (11, 111, 112).

Abstract: The invention relates to a receptacle (34) for at least partially compressively receiving at least one battery cell (12) for a battery module, wherein the receptacle (34) has at least two end plates (10) which can be arranged on two opposing sides of the at least one battery cell (12), wherein the end plates (10) are connected to one another by a plurality of connecting means (24), which are fixed to the end plates (10) and in each case have at least two plug elements (28), in such a way that the plug elements (28) of the connecting means (24) for fixing the connecting means (24) to the end plates (10) engage in bushings (22) of the end plates (10) in a plane arranged substantially at right angles to the direction of extension of the connecting means (24).

Abstract: The invention relates to a temperature-controlling device for a battery module, having a flow space (4) which has a multiplicity of spacer elements (11) and is essentially closed. The spacer elements (11) are arranged within the flow space (4) and the temperature-controlling device (3) further has a flow deflection unit (15) which is arranged within the flow space (4) and has a longitudinal direction (16) extending along the flow deflection unit (15) from a first end (24) to a second end (25) of said flow deflection unit (15). The flow deflection unit (15) forms a first side face (17) and a second side face (18) which sides are arranged in the longitudinal direction (16) on opposite sides of the flow deflection unit (15), and wherein at least portions of the first side face (17) and the second side face (18) are arranged directly adjacent to a spacer element (11, 111, 112).

Abstract: The invention relates to a battery module housing (2001, . . . 2004) for a battery pack (10), characterized in that: the battery module housing (2001, . . . 2004) can contain a large number of battery cells (100111, . . . 100432) which each have a large wall surface (1201, 1202) and a small wall surface (1301, 1302), of which small wall surface the surface area is less than a surface area of the large wall surface (1201, 1202), wherein the battery cells (100119, 100129, 100132, 100142, 100219, 100229, 100232, 100242, 100319, 100329, 100332, 100342, 100419, 100432) which can be arranged adjacent to outer sides of the battery pack (10) can be oriented in such a way that their large wall surfaces (1201, 1202) run along the outer sides, so that a force which acts on one of the outer sides can initially be received by one of the large wall surfaces (1201, 1202), and also to a battery module (201, 204), to a battery (10), to a battery, to a vehicle and also to a method for producing a battery module (201, . . .

Abstract: The invention relates to a cooling plate for an electric energy storage element, said cooling plate comprising at least two non-detachably interconnected metal sheets and at least one plastic covering. The joined metal sheets comprise at least one cooling channel which can be created by separating means.

Abstract: The invention relates to a frame device (18) for accommodating storage cells (12) of an energy storage module (10), in particular a battery module, comprising—two plate-like closure elements (20) which form two ends (22, 24) of the frame device (18) that are opposite one another along an axis (14), —connection elements (30) which are arranged on mutually opposite sides (26, 28) of the frame device (18) and which extend from one end (22) to the other end (24) of the frame device (18) and mechanically connect the two closure elements (20) over a distance. For connection to the two closure elements (20), provision is made for each of the connection elements (30) to be provided at each of the ends thereof with a pin (42) which is oriented transversely to the axis (14) and which respectively engages in a cutout (40) in one of the closure elements (20) and is releasably fixed there by means of a respective latch-type securing element (32). The invention further relates to a corresponding energy storage module (10).

Abstract: The invention relates to a receptacle (34) for at least partially compressively receiving at least one battery cell (12) for a battery module, wherein the receptacle (34) has at least two end plates (10) which can be arranged on two opposing sides of the at least one battery cell (12), wherein the end plates (10) are connected to one another by a plurality of connecting means (24), which are fixed to the end plates (10) and in each case have at least two plug elements (28), in such a way that the plug elements (28) of the connecting means (24) for fixing the connecting means (24) to the end plates (10) engage in bushings (22) of the end plates (10) in a plane arranged substantially at right angles to the direction of extension of the connecting means (24).

Abstract: The invention relates to a cooling plate for an electric energy storage element, said cooling plate comprising at least two non-detachably interconnected metal sheets and at least one plastic covering. The joined metal sheets comprise at least one cooling channel which can be created by separating means.

Abstract: The invention relates to a frame device (18) for accommodating storage cells (12) of an energy storage module (10), in particular a battery module, comprising—two plate-like closure elements (20) which form two ends (22, 24) of the frame device (18) that are opposite one another along an axis (14),—connection elements (30) which are arranged on mutually opposite sides (26, 28) of the frame device (18) and which extend from one end (22) to the other end (24) of the frame device (18) and mechanically connect the two closure elements (20) over a distance. For connection to the two closure elements (20), provision is made for each of the connection elements (30) to be provided at each of the ends thereof with a pin (42) which is oriented transversely to the axis (14) and which respectively engages in a cutout (40) in one of the closure elements (20) and is releasably fixed there by means of a respective latch-type securing element (32). The invention further relates to a corresponding energy storage module (10).