A lead-acid battery includes a positive electrode plate, a negative electrode plate, an electrolyte solution, and a polymer compound, in which the positive electrode plate includes a positive current collector and a positive electrode material, the negative electrode plate includes a negative current collector and a negative electrode material, the Ca content of the positive current collector is 0.13% by mass or less, and the polymer compound has a peak in a range of 3.2 ppm or more and 3.8 ppm or less in a chemical shift of .sup.1H-NMR spectrum, or the polymer compound contains a repeating structure of oxy C.sub.2-4 alkylene units.

An integrated-valve plug to be placed in a channel for conveying a gas is disclosed. The integrated-valve plug comprises a plug body having an opening for receiving the gas from the channel, and having a plug chamber. The integrated-valve plug further comprises a valve, a flame arrester, and a cap disposed in the plug chamber. The cap includes an aperture for exhausting the gas from the plug body. The integrated-valve plug further comprises a gas path defined in part from the opening, past the valve, through the flame arrestor, and through the aperture.

A battery is also disclosed. The battery includes a first cell compartment, a second cell compartment, a first plug for the first cell compartment, and a second plug for the second cell compartment. The first plug includes a first plug chamber and a first plug outlet in fluid communication with the first plug chamber. The first plug chamber receives a first gas from the first cell compartment and exhausts the first gas via the first plug outlet. The second plug includes a second plug chamber and a second plug outlet in fluid communication with the second plug chamber. The second plug chamber receives a second gas from the second cell compartment and exhausts the second gas via the second plug outlet. The battery further comprises a degassing channel coupled to receive the first gas from the first plug outlet and to receive the gas from the second plug outlet, and a valve plug coupled to receive a gas including at least portions of the first gas and the second gas from the degassing channel. The valve plug controllably exhausts the gas. The valve plug can include the integrated valve plug comprising the valve and the flame arrestor to take further advance of the integrated valve plug.

Provided is a catalyst device for a lead-acid battery, the catalyst device being capable of reducing gas release from an electrolyte solution and a decrease in electrolyte solution due to the leakage, thus providing a lead-acid battery having a long life, and being capable of ensuring safety even in excessive flow of gas. Also provided is a lead-acid battery including the catalyst device. A catalyst device for a lead-acid battery, including: a catalyst layer including a catalyst to accelerate a reaction for generating water or water vapor from oxygen and hydrogen; and a porous membrane including thermoplastic resin having a melting point or a glass transition temperature of 160° C. or less, and wherein at least one surface of the catalyst layer is in contact with the porous membrane, and the porous membrane has a planar size being equal to or greater than that of the catalyst layer. Also a lead-acid battery including the catalyst device.

A device for restoring energy parameters of a battery is provided. The device includes a supporting frame, a controller, and a battery container configured to receive the battery therein, the battery container being operably coupled to a controlling inverter and a motor comprising a motor reductor. The controlling inverter is configured to regulate a rotational speed of the motor. The motor reductor is configured to facilitate rotation of the battery container. Methods of restoring energy parameters of a battery are also provided.

The invention relates to an energy storage system for a vehicle, in particular a starter battery for a vehicle, having a plurality of energy storage cells for providing and/or storing electric energy and a housing which has a plurality of wall elements that delimit the interior of the housing. The housing is designed to receive the plurality of energy storage cells in the interior of the housing. A plurality of separating walls are arranged in the interior of the housing in order to divide the interior of the housing into a plurality of chambers, wherein each chamber is designed to receiving an energy storage cell. A fluidic connection is formed between the individual chambers, and a ventilation valve is arranged on one of the wall elements, preferably a cover element, of the housing in a respective region paired with the corresponding chamber. At least one of the ventilation valves is an active ventilation valve, and the remaining ventilation valves are blind closures.

A battery, a fixture for forming a battery plate, a kit, and a related method of manufacture are provided. The battery comprises a housing and a mechanically actuated valve. The housing defines a cell configured to receive battery plates. The mechanically actuated valve is in fluid communication with the cell and configured to control entry of electrolyte into the cell.

Provided is a catalyst part for a lead-acid battery, the catalyst part being capable of reducing gas release from an electrolyte solution and a decrease in electrolyte solution due to the leakage, thus providing a lead-acid battery having a long life. Also provided are a ventilation filter, a ventilation plug, and a lead-acid battery each including the catalyst part. A catalyst part for a lead-acid battery, including a catalyst layer including a catalyst to accelerate a reaction for generating water or water vapor from oxygen and hydrogen, and an arrangement through which at least part of the water or water vapor is condensed and/or flowed back to the inside of the battery.

A battery, a fixture for forming a battery plate, a kit, and a related method of manufacture are provided. The battery comprises a housing and a mechanically actuated valve. The housing defines a cell configured to receive battery plates. The mechanically actuated valve is in fluid communication with the cell and configured to control entry of electrolyte into the cell.

Battery separators comprising embossments are generally provided. The embossments may take the form of indentations formed in a surface of the battery separator, such as indentations formed by an embossing process. The embossments may comprise intersections with a first edge and a second edge of the battery separator, which may be the same or different.

Disclosed herein are soluble content absorbent glass mats or AGM separators for VRLA, AGM, or VRLA AGM batteries. Such glass mats may be prepared from insoluble glass fibers blended with soluble content materials. Upon exposure to a suitable solvent, the dissolving or solvating of the soluble content produces voids within the glass mat. The voids enhance the absorption of the solvent within the glass mat. The soluble content may be acid-soluble glass fibers or microfibers.