A secondary battery includes an electrode assembly including a first electrode plate, a second electrode plate, and a separator between the first electrode plate and the second electrode plate, a case in which the electrode assembly and an electrolyte are received, and a finishing member attached to an outer surface of the electrode assembly. The finishing member includes a first layer, a second layer, and a third layer. The first layer has one surface attached to the electrode assembly. The second layer and the third layer are different from each other and are sequentially provided on another surface of the first layer. The second layer and the third layer react to the electrolyte.

Lithium-metal batteries with improved dimensional stability are presented along with methods of manufacture. The lithium-metal batteries incorporate an anode cell that reduces dimensional changes during charging and discharging. The anode cell includes a container having a first portion and a second portion to form an enclosed cavity. The first portion is electrically-conductive and chemically-stable to lithium metal. The second portion is permeable to lithium ions and chemically-stable to lithium metal. The anode cell also includes an anode comprising lithium metal and disposed within the cavity. The anode is in contact with the first portion and the second portion. The cavity is configured such that volumetric expansion and contraction of the anode during charging and discharging is accommodated entirely therein.

The present application discloses a method of quick charging a lithium battery for a brushless direct current motor drive system, including the steps: (1) a constant power charging stage; and (2) a linear charging stage. The above-mentioned method of quick charging a lithium battery for a brushless direct current motor drive system has the advantages of speeding up the charging process and reducing heat generation during the charging process so as to realize short charging time, and shorten the waiting time for battery charging. It has an extensive market prospect for the popularization of the method of quick charging a lithium battery for a brushless DC motor drive system.

Transfer films, articles made therewith, and methods of making and using transfer films to form an electrical stack are disclosed. The transfer films (100) may include a plurality of co-extensive electrical protolayers (22, 23, 24) forming an electrical protolayer stack (20), at least selected or each electrical protolayer independently comprising at least 25 wt % sacrificial material and a thermally stable material and having a uniform thickness of less than 25 micrometers. The transfer films may include a plurality of co-extensive electrical protolayers forming an electrical protolayer stack, at least selected or each protolayer independently exhibiting a complex viscosity of between 10.sup.3 and 10.sup.4 Poise at a shear rate of 100/s when heated to a temperature between its Tg and T.sub.dec.

Transfer films, articles made therewith, and methods of making and using transfer films to form an electrical stack are disclosed. The transfer films (100) may include a plurality of co-extensive electrical protolayers (22, 23, 24) forming an electrical protolayer stack (20), at least selected or each electrical protolayer independently comprising at least 25 wt % sacrificial material and a thermally stable material and having a uniform thickness of less than 25 micrometers. The transfer films may include a plurality of co-extensive electrical protolayers forming an electrical protolayer stack, at least selected or each protolayer independently exhibiting a complex viscosity of between 10.sup.3 and 10.sup.4 Poise at a shear rate of 100/s when heated to a temperature between its Tg and T.sub.dec.

An electrochemical storage cell is disclosed that comprises a core and a rectangular shell that receives the core snugly therein. The rectangular shell has first and second open ends. A first end cap is used to close the first open end. An anode terminal extends through the first end cap from an interior portion of the electrochemical storage cell to an external portion thereof. A first gasket is secured within the rectangular shell between the first end cap and the core to resiliently hold the core away from the first end cap. A second end cap is used to close the second open end. A cathode terminal extends through the second end cap from an interior portion of the electrochemical storage cell to an external portion thereof. A second gasket is secured within the rectangular shell between the second end cap and the core to resiliently hold the core away from the second end cap.

A mobile power supply for garden tools includes a strap structure and a power supply device. The strap structure includes a waist strap, and a shoulder strap provided on the waist strap. The power supply device is provided on one side of the waist strap. The power supply device includes a power source, a fabric case, and a dummy power source. The power source is provided in the fabric case. This can separate an actual power source from a garden tool, and transfer a large portion of the weight of the garden tool by placing the actual power source on the waist of a user. This uses other parts of the human body to bear the weight of the power source, and reduces the need for user's arm strength. It is easier to operate the garden tools, and therefore can extend the labor time.

A mobile power supply for garden tools includes a strap structure and a power supply device. The strap structure includes a waist strap, and a shoulder strap provided on the waist strap. The power supply device is provided on one side of the waist strap. The power supply device includes a power source, a fabric case, and a dummy power source. The power source is provided in the fabric case. This can separate an actual power source from a garden tool, and transfer a large portion of the weight of the garden tool by placing the actual power source on the waist of a user. This uses other parts of the human body to bear the weight of the power source, and reduces the need for user's arm strength. It is easier to operate the garden tools, and therefore can extend the labor time.

The present invention provides a battery cell, comprising: (a) an anode comprising an active metal or a metal ion storage material (e.g., an intercalation compound that accommodates lithium ion); (b) a cathode structure; and (c) an ionically conductive protective layer on a surface of the anode and interposed between the anode and the cathode structure. This protective layer comprises a porous membrane having pores therein and a soft matter phase disposed in at least one of the pores, wherein the soft matter phase comprises oxide particles dispersed in a non-aqueous alkali, alkaline, or transition metal salt solution. Most preferably, this battery cell is a lithium metal secondary cell that is essentially free from dendrite and exhibits a safer and more stable cycling behavior. Such a high-capacity rechargeable battery is particularly useful for powering portable electronic devices and electric vehicles.

Provided are a pouch case and a secondary battery using the same. The pouch case includes a first receiving part and a second receiving part which are concavely formed; a sealing part formed along an outer portion of the pouch case so as to surround the first receiving part and the second receiving part; and a partitioning part formed between the first receiving part and the second receiving part and protruding from a bottom surface of each receiving part to partition the first receiving part and the second receiving part. As one side surface of the secondary battery in which an electrode assembly is received and packaged in the pouch case is formed in a plane form, a flat side surface is in close contact with a cooling plate, thereby maximizing cooling efficiency of the secondary battery.