A method and a bowling ball enclosure are provided for encasing and reducing temperature fluctuations of and within a bowling ball. The bowling ball enclosure includes a flexible inner vapor barrier layer and a flexible outer layer that are made of a polymer material, the inner layer forming an interior region that receives the bowling ball. The bowling ball enclosure also includes a bottom portion and a top portion, wherein the top portion is positionable from a first position to a second position to encapsulate the bowling ball. In the first position, the top portion being in an open position to receive the bowling ball into the interior region. In the second position, the top portion being in a closed position to encapsulate the bowling bowl. A thermal resistor can be located between the bowling ball enclosure and a support surface.

An antislip, heat sealable plastic packaging bag, is formed from an antislip flexible packaging material whose wall has an average surface weight of at most 500 g/m.sup.2. The packaging material includes a multiplicity of randomly distributed, separate antislip protrusions of a first substance. The protrusion height is between 50 micrometres and 10000 micrometres, with an average of top-plan-view aspect ratios of the antislip protrusions being at most 5.0. Some antislip protrusions have a hidden surface portion being a portion of a free surface of the antislip protrusion, which the antislip protrusion covers from a viewer in a top plan view of the wall. The first substance is a thermoplastic polymer, and the wall's outer surface is of a substance at least somewhat different from the first substance. It is an important feature that the first substance has a melt mass flow rate of at least 0.6 g/10 min. An apparatus, for producing the packaging material, includes a film blowing die head, a cooling air ring, and a particle dispersing unit therebetween, for dispersing polymer particles on the bubble neck at a place in, or closely under, an expanding area where the bubble has a divergent shape.

A method and a bowling ball enclosure are provided for encasing and reducing temperature fluctuations of and within a bowling ball. The bowling ball enclosure includes a flexible inner vapor barrier layer and a flexible outer layer that are made of a polymer material, the inner layer forming an interior region that receives the bowling ball. The bowling ball enclosure also includes a bottom portion and a top portion, wherein the top portion is positionable from a first position to a second position to encapsulate the bowling ball. In the first position, the top portion being in an open position to receive the bowling ball into the interior region. In the second position, the top portion being in a closed position to encapsulate the bowling bowl. A thermal resistor can be located between the bowling ball enclosure and a support surface.

A method and a bowling ball enclosure are provided for encasing and reducing temperature fluctuations of and within a bowling ball. The bowling ball enclosure includes a flexible inner vapor barrier layer and a flexible outer layer that are made of a polymer material, the inner layer forming an interior region that receives the bowling ball. The bowling ball enclosure also includes a bottom portion and a top portion, wherein the top portion is positionable from a first position to a second position to encapsulate the bowling ball. In the first position, the top portion being in an open position to receive the bowling ball into the interior region. In the second position, the top portion being in a closed position to encapsulate the bowling bowl. A thermal resistor can be located between the bowling ball enclosure and a support surface.

A method for forming an antislip material. A flexible thermoplastic carrier is provided. A hot release surface is provided. Provided is a first layer of discrete thermoplastic particles, sifting on the hot release surface. The discrete particles are above their softening temperatures, providing in the first layer a tackiness. The method includes contacting the carrier with the tacky first layer for sticking the first layer to the carrier, and thereafter removing the carrier, and therewith the tacky first layer stuck to the carrier, from the release surface. Thereby the carrier is provided with a hot, preferably discontinuous and/or elastomeric antislip coating. With a heat energy of the hot coating a bond is formed between the carrier and the coating. The removing of the carrier includes pulling the carrier out of the contact with a pulling-out force. The temperature of the hot release surface is above the melting temperature of the carrier. The carrier would be spoiled, if heated completely to the temperature of the release surface and simultaneously pulled with the pulling-out force. Therefore the contacting time is kept shorter than a minimum time required by a heat of the hot release surface for spoiling the carrier. Flat-topped roughening projections can be included in the antislip coating.

An antislip, heat sealable plastic packaging bag, is formed from an antislip flexible packaging material whose wall has an average surface weight of at most 500 g/m.sup.2. The packaging material includes a multiplicity of randomly distributed, separate antislip protrusions of a first substance. The protrusion height is between 50 micrometres and 10000 micrometres, with an average of top-plan-view aspect ratios of the antislip protrusions being at most 5.0. Some antislip protrusions have a hidden surface portion being a portion of a free surface of the antislip protrusion, which the antislip protrusion covers from a viewer in a top plan view of the wall. The first substance is a thermoplastic polymer, and the wall's outer surface is of a substance at least somewhat different from the first substance. It is an important feature that the first substance has a melt mass flow rate of at least 0.6 g/10 min. An apparatus, for producing the packaging material, includes a film blowing die head, a cooling air ring, and a particle dispersing unit therebetween, for dispersing polymer particles on the bubble neck at a place in, or closely under, an expanding area where the bubble has a divergent shape.

A stackable package includes a packaging sack and a block of plate-frozen fish packed therein. The sack is a plastic sack having a second outer surface, on which the package can be laid on a stack, and an opposing first outer surface. A roughened surface-part of the first outer surface includes antislip protrusions projecting from a first wall of the sack. A skidproofed surface-part of the second outer surface includes a skidproofing material, of a suitable fibrous structure, fixed to a second wall of the sack. The skidproofing material is capable of a nonslip bond with the antislip protrusions. The sack has a wear rate of between 0 and 0.35. The wear rate is determined in a wear-rate test in which (at a temperature of 20 C. and a compression of 11557 Pa) a specimen of the skidproofed surface-part is slided on a roughened surface-part specimen and the wear rate is defined as the proportion of the number of anstislip protrusions breaking off the roughened surface-part specimen due to the slide. Accordingly, multiple packages can be manually re-stacked without losing too many of their antislip protrusions.

A method for forming an antislip material. A flexible thermoplastic carrier is provided. A hot release surface is provided. Provided is a first layer of discrete thermoplastic particles, sifting on the hot release surface. The discrete particles are above their softening temperatures, providing in the first layer a tackiness. The method includes contacting the carrier with the tacky first layer for sticking the first layer to the carrier, and thereafter removing the carrier, and therewith the tacky first layer stuck to the carrier, from the release surface. Thereby the carrier is provided with a hot, preferably discontinuous and/or elastomeric antislip coating. With a heat energy of the hot coating a bond is formed between the carrier and the coating. The removing of the carrier includes pulling the carrier out of the contact with a pulling-out force. The temperature of the hot release surface is above the melting temperature of the carrier. The carrier would be spoiled, if heated completely to the temperature of the release surface and simultaneously pulled with the pulling-out force. Therefore the contacting time is kept shorter than a minimum time required by a heat of the hot release surface for spoiling the carrier. Flat-topped roughening projections can be included in the antislip coating.

A flammable liquid transport system includes a container that may contain a flammable liquid. A bag is provided and the bag may be transported in a vehicle. The container is positioned within the bag. Thus, the bag inhibits the flammable liquid from spilling into the vehicle. The bag is comprised of a fire resistant and fluid impermeable material.