A conductive connecting member includes a first terminal, a second terminal, and a braided member for electrically connecting the first and second terminals. The braided member is a member formed by braiding a plurality of metal strands each other. The braided member includes a first fixing portion to be fixed and electrically connected to the first terminal, a second fixing portion to be fixed and electrically connected to the second terminal and an intermediate portion serving as a part of the braided member between the first and second fixing portions. The intermediate portion retains its own shape in a natural state where no external force is applied and is deformed to allow a relative movement of the second terminal with respect to the first terminal when an external force for relatively changing a position of the second terminal with respect to the first terminal is applied.

A conductive connecting member includes a first terminal, a second terminal, and a braided member for electrically connecting the first and second terminals. The braided member is a member formed by braiding a plurality of metal strands each other. The braided member includes a first fixing portion to be fixed and electrically connected to the first terminal, a second fixing portion to be fixed and electrically connected to the second terminal and an intermediate portion serving as a part of the braided member between the first and second fixing portions. The intermediate portion retains its own shape in a natural state where no external force is applied and is deformed to allow a relative movement of the second terminal with respect to the first terminal when an external force for relatively changing a position of the second terminal with respect to the first terminal is applied.

A fabric wet power generation material based on molybdenum disulfide and a preparation method and use therefor. Taking molybdenum disulfide as a base material, an in-situ grown MoS.sub.2 carbonized fabric and a MoS.sub.2-based conductive cellulose fiber fabric are prepared by using a hydrothermal method. Then the two fabrics are superposed to form a double-potential layer, so that under a wet condition, the textile uses water evaporation as a driving force, and the water molecules migrate in the double-conductive layers to generate a current, so as to achieve self-power generation, and the fabric wet power generation material is prepared. The fabric wet power generation material provided by the present invention uses metal as a negative electrode, and after being packaged, the fabric wet power generation material is applied to a wet power generation apparatus. In the fabric wet power generation material provided by the present invention, a transition metal disulfide nanomaterial having a three-dimensional micro-channel structure is constructed on the nano scale, and the structure ensures a large moisture conduction conductivity; meanwhile, a large number of pore channels existing in the three-dimensional structure can shorten the ion transmission distance, so that the power generation performance is improved, and there are advantages of being simple and rapid in preparation process and high in yield, and being beneficial to industrial production and application in the field of flexible intelligent textile.

A fabric wet power generation material based on molybdenum disulfide and a preparation method and use therefor. Taking molybdenum disulfide as a base material, an in-situ grown MoS.sub.2 carbonized fabric and a MoS.sub.2-based conductive cellulose fiber fabric are prepared by using a hydrothermal method. Then the two fabrics are superposed to form a double-potential layer, so that under a wet condition, the textile uses water evaporation as a driving force, and the water molecules migrate in the double-conductive layers to generate a current, so as to achieve self-power generation, and the fabric wet power generation material is prepared. The fabric wet power generation material provided by the present invention uses metal as a negative electrode, and after being packaged, the fabric wet power generation material is applied to a wet power generation apparatus. In the fabric wet power generation material provided by the present invention, a transition metal disulfide nanomaterial having a three-dimensional micro-channel structure is constructed on the nano scale, and the structure ensures a large moisture conduction conductivity; meanwhile, a large number of pore channels existing in the three-dimensional structure can shorten the ion transmission distance, so that the power generation performance is improved, and there are advantages of being simple and rapid in preparation process and high in yield, and being beneficial to industrial production and application in the field of flexible intelligent textile.

The invention relates to a method for uniformly coating a metallic or metallised braided hose, in particular a stranded braided hose with a solder or a soldering and fluxing agent. According to the invention, the solder is provided in bar or tubular form, wherein the outer diameter or the cross-sectional area of the bar or the tube is chosen to be less than the inner diameter or the inner cross-sectional area of the braided hose. Furthermore, the solder is pushed into at least one longitudinal portion of the braided hose and the solder is fixed in the braided hose cavity. Further processing of the braided hose, in particular heating to the melting point of the solder introduced, can then be performed in a generally known way.

The invention relates to a method for uniformly coating a metallic or metallised braided hose, in particular a stranded braided hose with a solder or a soldering and fluxing agent. According to the invention, the solder is provided in bar or tubular form, wherein the outer diameter or the cross-sectional area of the bar or the tube is chosen to be less than the inner diameter or the inner cross-sectional area of the braided hose. Furthermore, the solder is pushed into at least one longitudinal portion of the braided hose and the solder is fixed in the braided hose cavity. Further processing of the braided hose, in particular heating to the melting point of the solder introduced, can then be performed in a generally known way.

An electrical conductor for an electrical installation. The electrical conductor includes: a first end segment; a second end segment; and a middle segment. The middle segment is formed by a plurality of conductor branches which electrically couples and mechanically couples the first end segment and the second end segment. The first end segment and conductor branches of the plurality of conductor branches are monolithically united by connections, thus shaping, concavely, corners between the first end segment and conductor branches of the plurality of conductor branches and spatially separating conductor branches of the plurality of conductor branches in two different transversal directions.

A battery module connector for electrically conductive connecting of two battery modules includes a first contact element for electrically conductive contacting of a first battery module, a second contact element for electrically conductive contacting of a second battery module, a band-shaped wire braid that is electrically conductively connected at a first end to the first contact element and at a second end to the second contact element, and at least one spring element that is inserted into a section of the wire braid between the first end and the second end, and is configured to impinge the section with a spring force such that the section is widened radially with respect to a longitudinal axis of the wire braid.

A battery module connector for electrically conductive connecting of two battery modules includes a first contact element for electrically conductive contacting of a first battery module, a second contact element for electrically conductive contacting of a second battery module, a band-shaped wire braid that is electrically conductively connected at a first end to the first contact element and at a second end to the second contact element, and at least one spring element that is inserted into a section of the wire braid between the first end and the second end, and is configured to impinge the section with a spring force such that the section is widened radially with respect to a longitudinal axis of the wire braid.

A shield including: a plurality of insulating filaments that extend in an X direction; and a plurality of conductive filaments that extend in a Y direction intersecting the X direction and are interknitted with the plurality of insulating filaments, wherein the plurality of insulating filaments includes: a first pair of insulating filaments that are adjacent to each other in the Y direction at a first interval, and a second pair of insulating filaments that are adjacent to each other in the Y direction at a second interval that is larger than the first interval.