A plastic container comprises an upper portion including a finish adapted to receive a closure, a lower portion including a base, and a sidewall extending between the upper portion and the lower portion. The upper portion, the lower portion, and the sidewall define an interior volume for storing liquid contents. The plastic container further comprises a pressure panel located on the container and moveable between an initial position and an activated position. The pressure panel is located in the initial position prior to filling the container, and is moved to the activated position after filling and sealing the container. Moving the pressure panel from the initial position to the activated position reduces the internal volume of the container and creates a positive pressure inside the container. The positive pressure reinforces the sidewall. A method of processing a container is also disclosed.

A manufacturing method of two-chamber type combined container-syringe including: a vacuum plugging process (S2) of eliminating air bubbles from the dissolving solution of the dissolving solution-filled cartridge and sealing the dissolving solution with a middle stopper after the dissolving solution filling process (S1); a vacuum plugging process (S2) has a first cooling processing (S21) of cooling the inside of a vacuum plugging equipment in which a dissolving solution-filled cartridge is disposed to a cooling temperature that does not freeze the dissolving solution, a first decompression processing (S23) of decreasing a pressure inside the vacuum plugging equipment while the vacuum plugging equipment maintains the cooling temperature after the first cooling processing (S21), and a middle stopper pushing processing (S24) of pushing the middle stopper downward and bringing the middle stopper into contact with the dissolving solution after the first decompression processing (S23). The dissolving solution can be easily filled in a bubble-free state in the two-chamber type combined container-syringe.

A manufacturing method of two-chamber type combined container-syringe including: a vacuum plugging process (S2) of eliminating air bubbles from the dissolving solution of the dissolving solution-filled cartridge and sealing the dissolving solution with a middle stopper after the dissolving solution filling process (S1); a vacuum plugging process (S2) has a first cooling processing (S21) of cooling the inside of a vacuum plugging equipment in which a dissolving solution-filled cartridge is disposed to a cooling temperature that does not freeze the dissolving solution, a first decompression processing (S23) of decreasing a pressure inside the vacuum plugging equipment while the vacuum plugging equipment maintains the cooling temperature after the first cooling processing (S21), and a middle stopper pushing processing (S24) of pushing the middle stopper downward and bringing the middle stopper into contact with the dissolving solution after the first decompression processing (S23). The dissolving solution can be easily filled in a bubble-free state in the two-chamber type combined container-syringe.

The present invention provides a method of producing a topping hanger comprising: (a) inspecting raw materials; (b) calculating a formula; (c) mixing uniformly; (d) dehumidifying the raw materials; (e) injection molding a colored mixed body: introducing the dehumidified raw materials into an injection molding machine at temperature 200-350° C., and the colored mixed body being produced by injecting molding after adjusting parameters of molds; (f) injection molding a transparent exterior body: a transparent PET and acrylics being formed of the transparent exterior body outside of the colored mixed body by injection molding at temperature 200-350° C.; and (g) packing the products. The transparent exterior body fully coats with the colored mixed body via injection molding, and this feature effectively enhances quality and visual effect, and chemical and color stability of the products, and reduces the cost. The present invention reduces damage during objects with colors contacting human.

A plastic container comprises an upper portion including a finish defining an opening into the container, a lower portion including a base defining a standing surface, a sidewall extending between the upper portion and the lower portion, the sidewall defining a longitudinal axis, and at least one substantially transversely-oriented pressure panel located in the lower portion. The pressure panel is movable between an outwardly-inclined position and an inwardly-inclined position to compensate for a change of pressure inside the container. The standing surface defines a standing plane, and the entire pressure panel is located between the standing plane and the upper portion of the container when the pressure panel is in the outwardly-inclined position.

A method for increasing the dielectric withstand strength in the enclosure E of an electrical apparatus, this method consisting in placing in the enclosure a dielectric material in liquid or solid form, then in bringing this material to a temperature and/or a pressure allowing for its total or partial evaporation in the enclosure. This method includes a device for retaining the abovementioned material in its container during the handling allowing the placement of the container in the enclosure E, and a device for inducing the evaporation of this material at a certain moment after this placement in the enclosure E and for allowing the dispersion of the gases resulting from this evaporation in the enclosure E.

A method for increasing the dielectric withstand strength in the enclosure E of an electrical apparatus, this method consisting in placing in the enclosure a dielectric material in liquid or solid form, then in bringing this material to a temperature and/or a pressure allowing for its total or partial evaporation in the enclosure. This method includes a device for retaining the abovementioned material in its container during the handling allowing the placement of the container in the enclosure E, and a device for inducing the evaporation of this material at a certain moment after this placement in the enclosure E and for allowing the dispersion of the gases resulting from this evaporation in the enclosure E.

To provide a hydrogen-containing water product which maintains the oxidation-reduction potential at a low value even when a certain period of time elapses after manufacture.

A hydrogen-containing water product for beverage including: a packaging container with a straw having a sealing cap attached to an opening; hydrogen-containing water filled in the container under pressure; and a gas atmosphere that is generated in a space above the hydrogen-containing water in the container by a heat treatment conducted after the filling under pressure and is present even when at least 90 days elapse after generation, wherein the hydrogen-containing water has an oxidation-reduction potential of {[−59×(pH value of hydrogen-containing water in hydrogen-containing water product for beverage after elapse of 90 days)]−170} mV or less when being stored at normal temperature for at least 90 days after manufacture.

To provide a hydrogen-containing water product which maintains the oxidation-reduction potential at a low value even when a certain period of time elapses after manufacture.

A hydrogen-containing water product for beverage including: a packaging container with a straw having a sealing cap attached to an opening; hydrogen-containing water filled in the container under pressure; and a gas atmosphere that is generated in a space above the hydrogen-containing water in the container by a heat treatment conducted after the filling under pressure and is present even when at least 90 days elapse after generation, wherein the hydrogen-containing water has an oxidation-reduction potential of {[−59×(pH value of hydrogen-containing water in hydrogen-containing water product for beverage after elapse of 90 days)]−170} mV or less when being stored at normal temperature for at least 90 days after manufacture.

A method, comprising steps: (a) placing a plurality of produce in an airtight chamber having a quantity of air and a first pressure, wherein the plurality of produce comprises water; (b) removing the quantity of air via a first vacuum pump to reduce the first pressure in the airtight chamber providing a vacuum cooling effect, wherein the water evaporates until the plurality of produce reaches a predetermined temperature; (c) packaging each individual produce of the plurality of produce in a container, wherein the container has a second pressure; (d) reducing the second pressure via a second vacuum pump; and (e) injecting a nitrogen gas inside the container until the container reaches a third pressure.