A battery for an implantable medical device (IMD) configured to support a relatively high rate of energy discharge relative to its capacity to support energy intensive therapy delivery, such as high energy anti-tachyarrhythmia shocks, by the IMD. The battery includes a first electrode, a second electrode separated a distance from the first electrode, an electrolyte disposed between the first electrode and the second electrode. The electrolyte includes a lithium salt including LiAsF6, an organic solvent, and an electrolyte additive that includes vinylene carbonate.

A flexible secondary battery includes an electrode stack assembly including a first electrode layer, a second electrode layer, and a separator between the first and second electrode layers; wherein the electrode stack assembly has a first end portion and a second end portion located opposite to the first end portion; and a fixing member fixing the first electrode layer, the separator, and the second electrode layer together; wherein the electrode stack assembly includes a fixing member region in which the fixing member is formed, the fixing member region being located between the first and second end portions of the electrode stack assembly in a first direction, and wherein the first electrode layer, the separator, and the second electrode layer are flexible at both sides of the fixing member.

A device for maskless thin film etching, including an ablation tool adapted to emit an ablative output for etching a surface, a gas jet associated with a source of carrier gas and adapted to emit a stream of the carrier gas at an area of the surface where the output of the ablation tool impinges, and a suction member associated with a vacuum source and adapted to collect ablated particulate from the area of the surface where the output of the ablation tool impinges, wherein the ablation tool, the gas jet, and the suction member are mounted adjacent one another.

A battery having flat, stacked, anode and cathode layers. The battery can be adapted to fit within an implantable medical device.

An electrochemical cell may have a PVDF microporous membrane that may be adhesively bonded to electrodes. The adhesive may be a mixture of a solvent and non-solvent that may cause the PVDF membrane to become tacky and adhere to an electrode without collapsing. An adhesively bonded cell may be constructed using multiple layers of adhesively bonded membranes and electrodes. In some embodiments, the adhesive solution may be used as a sizing to prepare electrodes for bonding.

Positive active material pastes for flooded deep discharge lead-acid batteries, methods of making the same and lead-acid batteries including the same are provided. The positive active material paste includes lead oxide, a sulfate additive, and an aqueous acid. The positive active material paste contains from about 0.1 to about 1.0 wt % of the sulfate additive. Batteries using such positive active material pastes exhibit greatly improved performance over batteries with conventional positive active material pastes.

Embodiments of the present invention disclose a composition of matter comprising a silicon (Si) nanoparticle coated with a conductive polymer. Another embodiment discloses a method for preparing a composition of matter comprising a plurality of silicon (Si) nanoparticles coated with a conductive polymer comprising providing Si nanoparticles, providing a conductive polymer, preparing a Si nanoparticle, conductive polymer, and solvent slurry, spraying the slurry into a liquid medium that is a non-solvent of the conductive polymer, and precipitating the silicon (Si) nanoparticles coated with the conductive polymer. Another embodiment discloses an anode comprising a current collector, and a composition of matter comprising a silicon (Si) nanoparticle coated with a conductive polymer.

A method of welding a bus bar to battery cell terminals to produce a bus bar clip assembly. A bus bar is provided with spring clips. The clips fit over the battery terminals and hold the bus bar and terminals in contact for welding the components together.

An apparatus and method for transporting used, damaged, or defective galvanic cells while impeding and combating safety-critical states of the galvanic cells, in particular lithium-ion-based cells and/or lithium-ion polymer cells, includes an outer container, which defines a space, an inner container being arranged in the space. The inner container has spacers in order to maintain a distance from the bottom and inner faces of the outer container, an accommodating container for accommodating at least on galvanic cell being arranged in the inner container, free intermediate spaces being filled with a fire protection agent composed of inert, non-conductive, non-flammable, absorbent hollow glass granular material.

Provided are an electrode assembly and a battery. The electrode assembly includes a positive electrode piece, a negative electrode piece and a first protective layer arranged on the surfaces of the positive electrode piece and the negative electrode piece; and in a projection plane based on a length direction and a width direction of the electrode assembly, an orthographic projection of the first protective layer in the projection plane covers an orthographic projection of a first region of a positive electrode tab in the projection plane. The electrode assembly can take into account the energy of battery on the basis of preventing burrs of tab from piercing a separator.