A bus bar assembly for electrically connecting a plurality of battery cells having electrode leads includes a fixed bus bar provided in the form of a rod-shaped conductor; a pair of movable bus bars disposed to be spaced from both sides of the fixed bus bar in a lateral direction with the fixed bus bar being interposed therebetween to form a fitting space respectively between the pair of movable bus bars and the fixed bus bar so that at least one electrode lead can be inserted therein; and an adhering member configured to move the pair of movable bus bars close to the fixed bus bar when an electrode lead is located in each fitting space so that the electrode leads can be adhered to the fixed bus bar.

An electrical terminal is disclosed. The electrical terminal has a contact made of a first kind of metal and a coupling member made of a second kind of metal fixed to the contact. The coupling member has a crimping portion crimped to press the first contact against an electrical wire made of the first kind of metal.

The present invention relates to a HVIL system for a HV connector, in particular in a motor vehicle, which HV connector is configured to transmit HV current from the HV connector to a further component, wherein the HVIL system has a first HVIL contact element and a second HVIL contact element, wherein, in a non-plugged state of the HV connector, the first HVIL contact element is spaced apart from the second HVIL contact element by at least one first spring element; and wherein, in a plugged state of the HV connector, the first spring element is deformed in such a way that the first HVIL contact element makes contact with the second HVIL contact element in such a way that the HVIL system ensures that HV current is transmitted from the HV connector to the further component if the connection between the HV connector and the further component is secure. The present invention furthermore relates to a method for establishing a HV connection.

A spring clamp for plugging onto an electrical conductor of an electric machine, having a first spring leg and a second spring leg adjoining the first spring leg. The spring legs are arranged and/or formed with respect to one another in such a way that a receiving opening for receiving the electrical conductor is formed between a free first end portion of the first spring leg and a free second end portion of the second spring leg, and the conductor is clamped between the first end portion and the second end portion. The second spring leg has a sensor holder and a spring arm with a press-on tab, a spring force is exerted by way of the spring arm such that a sensor arranged in the sensor holder is fixed in the sensor holder by way of the press-on tab, and the sensor holder is pressed onto the electrical conductor.

A component carrier is illustrated and described. The component carrier has i) a stack with at least one electrically conductive layer structure and/or at least one electrically insulating layer structure, and ii) at least one elastic element attached to the stack and configured to reversibly connect the component carrier with a further component carrier by elastically deforming the at least one elastic element and essentially not deforming the stack and the further component carrier.

A connector includes wires (10), a connector housing (30) to hold ends of the wires (10), sealing members mounted on the wires (10) to seal clearances between the connector housing (30) and the wires (10), and a cover (40) assembled with the connector housing (30) to cover the wires (10). The connector housing (30) has a wire pull-out surface (34F1) and cavities (35) open in the wire pull-out surface (34F1) to accommodate ends of the wires (10) and the sealing members inside. The sealing member has a wire draw-out surface (20F) and includes a wire insertion hole (21) open in the wire draw-out surface (20F). The wire (10) is inserted into the wire insertion hole (21). The cover (40) includes a cover body (41) to cover the wires (10) and guides (71) extend from the cover body (41) for contacting the wire draw-out surfaces (20F) and guiding the wires (10).

A leaf spring compression system comprising a mechanical assembly for securing a plurality of leaf springs on a battery cell stack of a flow battery system is disclosed. The cell stack may, comprise: a plurality of cells stacked together to form a flow battery; and a compression system comprising at least two tie rods extending through the plurality of cells clamping a spring acting at opposite ends to compress the cells together, the spring contacting at least two fulcrum elements positioned between the tie rods. In this way, the compression system may exert uniform loading on the battery cell stack, while minimizing deflection of pressure plates attached to the cell stack.

Provided is a coupling structure of a bus bar equipped in a power part. The coupling structure of the bus bar includes a female type bus bar and a male type bus bar respectively coupled to different elements of the power part, wherein the female type bus bar is fitting-coupled to the male type bus bar. In the coupling structure of the bus bar, since bus bars of high voltage elements are connected to each other by a connecting method instead of a conventional bolting coupling structure, the miniaturization effect and cooling effect of an inverter may increase, and moreover, a tool used to couple bus bars may be omitted, thereby enabling power parts to be easily disposed.

A terminal block includes a housing having insulation properties, the housing having a holding portion provided in the housing and a terminal connection surface, a first opening portion through which a conductor portion of an electric wire can be inserted and pulled out and a second opening portion that is adjacent to the first opening portion and through which a jig can be inserted and pulled out being arranged in series in an array direction on the terminal connection surface and each communicating with the holding portion, and an opening surface being provided on a side of the holding portion in a width direction intersecting the array direction and a direction intersecting the terminal connection surface, and a terminal electrode portion and a leaf spring portion arranged in the holding portion. The housing is provided with a first movement restriction portion that restricts the movement of the moveable portion of the leaf spring portion in the width direction.

A terminal block includes a display-use moveable member which has a main body portion that can reciprocate in the direction intersecting a terminal connection surface and a contact moveable portion that extends along a guide surface, has a first end portion in an extension direction that is disposed so as to come into contact with a conductor portion in an electric wire passage portion and move in a first direction away from the terminal connection surface, and has a second end portion in the extension direction that is connected to the main body portion, and moves in an array direction in response to movement of the first end portion in the first direction to move the main body portion in a second direction toward the terminal connection surface.