Provided is a buffer body 5 for a lead-acid battery 1 having two terminals 12, the buffer body 5 being made of pulp mold, the buffer body 5 including, in a state where the buffer body 5 is disposed outside a first wall portion 22 facing the two terminals 12 among wall portions of a packing box 2 in which the lead-acid battery 1 is packed: a second wall portion 50 facing the first wall portion 22; and a first recessed portion 53A formed at a position facing the terminal 12 in the second wall portion 50 and recessed in a direction away from the first wall portion 22.

A packaging and shipping system for dry charged batteries. The packaging system includes a shipping crate having a lower section that defines an open interior. The open interior is sized to receive a dry charged battery and a plurality of electrolyte bottles. Each of the electrolyte bottles contains a volume of electrolyte sufficient to fill one of the individual cells of the dry charged battery. Each of the electrolyte bottles are separately packaged and positioned within the open interior of the shipping crate. Upon reaching the desired destination, the shipping crate can be stored. When the dry charged battery is to be placed into use, the shipping crate is opened and the individual cells of the dry charged battery are filled with electrolyte from the plurality of electrolyte bottles. Once the dry charged battery has been activated, the empty electrolyte bottles can be placed back into the shipping crate and returned for recycling.

The purpose of the present disclosure is to provide a battery accommodation tray in which the amount of material used is readily reduced and of which the strength is readily improved. The battery accommodation tray comprises a plurality of accommodation parts that respectively accommodate batteries and that are positioned at intervals from each other. The accommodation parts have insertion openings demarcated by insertion-side circular parts that have a circular shape when viewed from the insertion side of the batteries in the height direction (Z direction). The battery accommodation tray has insertion-side connection parts by which the outer peripheral surfaces of the insertion-side circular parts are connected to the outer peripheral surfaces of adjacent insertion-side circular parts. The plurality of insertion-side circular parts are connected by the plurality of insertion-side connection parts to form an integrated whole.

In the present invention, a porous separator roll (12U, 12L) is wrapped with a wrapping material (21) whose average transmittance with respect to light having a wavelength of 360 nm to 390 nm is 25% or lower. From this, it is possible to provide a package of a porous separator roll which package can inhibit change in color of a separator, and can thus provide a high-quality separator with good appearance.

Shipping containers for batteries are described herein. An example shipping container includes a base defining a cavity, a lid to be coupled to a top of the base to substantially seal the cavity, and an absorbent pad disposed within the cavity to absorb liquid from the battery if the battery leaks.

A safe and environmental protection package for tiny battery provides the tiny battery recycled and prevents the children from obtaining and eating by mistake, the technical scheme comprising a bottom cover body and a top cover body; the bottom cover body including a bottom piece body and a containing groove; an exit part disposed in one end of the containing groove and an access groove disposed in the other end thereof; two symmetric low positioning blocks and two symmetric high positioning blocks, by which a containing space is formed with the top cover body; said top cover body including a top piece body, a top groove part, and inserting slit; by applied to the above-mentioned structures, the tiny battery dispose inside the package is removed by inserting the used tiny battery.

An apparatus for storing and dispensing energy cells having a housing with spaced front and rear walls, side walls and a top and a bottom to form an enclosure for containing energy cells. An opening is provided in the front wall of a size to permit a single energy cell to be discharged, the opening having a top portion positioned below the top front edge of an energy cell when the cell is positioned in the upper most position ready for discharge. A platform urges the energy cells upward so the uppermost cell is in a discharge position with the top front edge of the energy cell positioned above the top portion of the opening. The rear wall, top and upper portion of the side wall are cut out to enable a user to engage the rear of the top energy cell to cause its discharge through the opening.

The present invention relates to a shipping container for mitigating external fire risks. The shipping container is configured for shipping lithium ion batteries with a cargo cavity proximate and interior to a second inner flame-retardant corrugated layer. The second inner flame-retardant corrugated layer is proximate and interior to an inner thermal paste panel. The inner thermal paste panel is proximate and interior to a dead air space panel. The dead air space panel is proximate and interior to a first inner flame-retardant corrugated layer. The first inner flame-retardant corrugated layer is proximate and interior to an outer thermal paste panel. The outer thermal paste panel is proximate and interior to a flame-retardant corrugated carton. The thermal paste panels preferably comprise aluminum flashing containing a mesh matrix for holding flowable thermal paste. The shipping container is lidded by a fitted cap above an air cap above a vacuum plenum cap.

A packaging and shipping system for dry charged batteries. The packaging system includes a shipping crate having a lower section that defines an open interior. The open interior is sized to receive a dry charged battery and a plurality of electrolyte bottles. Each of the electrolyte bottles contains a volume of electrolyte sufficient to fill one of the individual cells of the dry charged battery. Each of the electrolyte bottles are separately packaged and positioned within the open interior of the shipping crate. Upon reaching the desired destination, the shipping crate can be stored. When the dry charged battery is to be placed into use, the shipping crate is opened and the individual cells of the dry charged battery are filled with electrolyte from the plurality of electrolyte bottles. Once the dry charged battery has been activated, the empty electrolyte bottles can be placed back into the shipping crate and returned for recycling.

A resealable blister package is described that includes a receiving member and a peelable lidding member. The receiving member has a cavity that can hold items, such as consumer products, and the peelable lidding member can be attached to a peripheral portion of the receiving member to seal the items within the cavity. The peelable lidding member includes a first film layer and a second film layer that are laminated via an adhesive layer. The blister package is designed to be opened to provide access to the cavity and the items therein by peeling the peelable lidding member away from the receiving member. The peelable lidding member can be resealed to the receiving member by bringing the lidding member back into contact with exposed portions of the adhesive layer remaining on the peripheral portion of the receiving member.