A method of forming a sulfur-based cathode material includes: 1) providing a sulfur-based nanostructure; 2) coating the nanostructure with an encapsulating material to form a shell surrounding the nanostructure; and 3) removing a portion of the nanostructure through the shell to form a void within the shell, with a remaining portion of the nanostructure disposed within the shell.

An electrode and a lithium secondary battery including the same. By preparing an electrode including an electrode active layer formed using a structure capable of supporting an electrode active material, safety and charge and discharge properties of a battery are improved due to morphological characteristics of the electrode active material being supported inside the structure.

A lead-acid battery electrode including a tubular bag. The tubular bag includes a textile fabric, wherein the textile fabric includes a consolidated binder with thermoplastic properties and at least one electrically conductive additive.

An electrode assembly, a rechargeable battery comprising the same, and a method for manufacturing the rechargeable battery are provided. The electrode assembly comprises an electrode stack in which a plurality of electrodes and a plurality of separators are alternately combined. The electrode assembly also comprises an electrode tab part including a plurality of electrode tabs respectively connected to the plurality of electrodes to extend from a side surface of the electrode stack. The electrode tab part comprises an inclined portion provided on a first side thereof and a tab collection portion provided on a second side thereof, the inclined portion extends from the side surface of the electrode stack and bent in a direction, in which the plurality of electrode tabs are collected, and the tab collection portion extends from the inclined portion and has a shape in which the plurality of electrode tabs are joined.

A vaporizer electrical system has a mouthpiece. The mouthpiece is configured to allow a user to aspirate a flow of air through the mouthpiece. A center airflow post is connected to the mouthpiece. The center airflow post has a post opening to admit air through the center airflow post. A burning chamber frame is connected to the center airflow post. The burning chamber frame has a burning chamber frame slot for receiving material. The material is a liquid or solid. A main base connects to the burning chamber frame, and a static electrode connects to the main base. The main base, the burning chamber frame, and the static electrode have a first electrical polarity. A moving electrode is mounted to a gasket insulator.

A method of making a cover for the positive plate for acid batteries, comprising a set of thermally formed tubes of non-woven fabric, characterised in that a tape (1) of non-woven fabric of a width corresponding to the length of future tubes is wrapped into a single, oval loop, and the extreme ends are laid so as to form an overlap (2) in the zone between vertices (4) of the loop, then the loop is stitched crosswise to form a set of multiple channels (3) which are then thermally formed into cover tubes (6).

A Water Activated Battery characterized by a) At least one anode selected from the group consisting of magnesium, aluminum, zinc and alloys thereof; b) A cathode comprising at least one basic copper salt comprising Cu(OH).sub.2 combined with a copper salt CuX (with n1 the molar ratio between the CuX and the Cu(OH).sub.2 in the basic copper salt), such that a discharge reaction in saline versus a Mg anode could be written nMg+Cu(OH).sub.2.(n-1)CuX=Mg(OH).sub.2+(n1)MgX+nCu) on a skeletal frame, the cathode further comprising a soluble, ionically conductive material; c) at least one cavity separating said cathode and said at least one anode; and d) a housing surrounding said at least one anode, cathode and cavity; (e) a lower aperture at the base of the housing for ingress of water and for expelling of heavier than water products of post immersion reaction, and (f) an upper aperture located near top of the housing for venting hydrogen generated by the post immersion reaction, wherein the upper aperture is positioned below the top of housing to create a cavity to provide a void for trapping hydrogen, so that hydrogen is only expelled from the cavity via the upper aperture after a quantity has accumulated, and is expelled in bubbles having a diameter of at least one millimeter.

A method of making a cover for the positive plate for acid batteries, comprising a set of thermally formed tubes of non-woven fabric, characterised in that a tape (1) of non-woven fabric of a width corresponding to the length of future tubes is wrapped into a single, oval loop, and the extreme ends are laid so as to form an overlap (2) in the zone between vertices (4) of the loop, then the loop is stitched crosswise to form a set of multiple channels (3) which are then thermally formed into cover tubes (6).

A method of forming a sulfur-based cathode material includes: 1) providing a sulfur-based nanostructure; 2) coating the nanostructure with an encapsulating material to form a shell surrounding the nanostructure; and 3) removing a portion of the nanostructure through the shell to form a void within the shell, with a remaining portion of the nanostructure disposed within the shell.

A miniaturized electrochemical cell and a method for making it are provided. The method includes preparing at least one inner electrode of an electron conducting or semi-conducting material M1; providing a hollow support made of an electrically insulating material M6 and having at least one internal hollow channel; depositing on the external surface of the support a layer of an electrically conducting material M2; forming a template of colloidal particles of an electrically insulating material M3, on the M2 layer; depositing a layer of an electrically conducting material M4 on the M2 layer; depositing a layer L1 of an electron conducting or semi-conducting material M5 on the M4 layer, introducing the at least one inner electrode into the at least one internal hollow channel of the obtained structure; stabilizing the structure at its two open ends with an electrically insulating material M7; and removing M2, M3, M4 and M6 materials.