A method of filling a beverage bag. The beverage bag is part of a beverage container that also includes a rigid container housing supporting a dispensing spout of the beverage bag, the dispensing spout forming a dispensing passage from an interior of the beverage bag to an exterior of the beverage container for dispensing a content of the beverage bag. The method includes running a siphoning line from a beverage reservoir to the beverage bag, removing the dispensing tap, extending a siphon line outlet portion of the siphoning line into the beverage bag through the dispensing passage, sealing the dispensing spout around the siphon line outlet portion to prevent pressure release through the dispensing spout around the siphon line outlet portion, and siphoning the beverage from the beverage reservoir into the beverage bag to expand the beverage bag to fill inner dimensions of the rigid container housing.

A lawn refuse bag insert includes a rear wall disposed at a rear end of the lawn refuse bag insert; a first side wall hingedly coupled to the rear wall at a first side of the lawn refuse bag insert; and a second side wall hingedly coupled to the rear wall at a second side of the lawn refuse bag insert opposite the first side; wherein the lawn refuse bag insert further defines a front end opposite the rear end, and wherein the lawn refuse bag insert is unobstructed at the front end from a top end of the lawn refuse bag insert to a bottom end of the lawn refuse bag insert.

A bag processing machine includes: a rotation body which is intermittently rotated; a plurality of holding units which are attached to the rotation body and are moved along a circular movement path in accordance with rotation of the rotation body, the movement path being divided into a plurality of processing sections; a fixation support member which is positioned above the rotation body and does not rotate by rotation of the rotation body; and two or more processing devices which are supported by the fixation support member and perform processes on bags held by the plurality of holding units in two or more processing sections respectively of the plurality of processing sections.

Provided is a production line management system for managing a manufacturing line for containers. The production line management system includes a first reading unit for reading an identification code applied to each of the containers when the container with the identification code indicating an identifier being information identifying the container passes through a first point on the manufacturing line, a second reading unit for reading the identification code applied to each of the containers after the first reading unit reads the identification code, and a computing unit for generating a database in which the identifier indicated by the identification code and relevant information about each of the containers are associated, and determining normality/abnormality of each of the containers by comparing the relevant information associated in the database with the identifier indicated by the identification code read in the second reading unit with predetermined setting information.

Provided is a production line management system for managing a manufacturing line for containers. The production line management system includes a first reading unit for reading an identification code applied to each of the containers when the container with the identification code indicating an identifier being information identifying the container passes through a first point on the manufacturing line, a second reading unit for reading the identification code applied to each of the containers after the first reading unit reads the identification code, and a computing unit for generating a database in which the identifier indicated by the identification code and relevant information about each of the containers are associated, and determining normality/abnormality of each of the containers by comparing the relevant information associated in the database with the identifier indicated by the identification code read in the second reading unit with predetermined setting information.

Embodiments described herein relate to articles and methods for forming liquid surface films on the interior surfaces of containers for holding one or more products comprising one or more Bingham plastic materials. Bingham plastic materials behave as a solid under no or low shear stress, and behave as viscous liquids when an applied shear stress exceeds a yield stress. In some embodiments, a container for containing a product includes an interior surface and a liquid disposed on the interior surface. Before introduction of a product into a container, the liquid may be surrounded by air. The liquid-air interface in contact with the interior surface makes a contact angle, θ.sub.os(a), with respect to the interior surface of the container, of about 0°. After a product has been introduced to the container, the liquid is at least partially covered by the product. The liquid-product interface in contact with the interior surface, makes a contact angle, θ.sub.os(p), with respect to the interior surface, of less about 60°. The subscript “o” denotes the liquid, subscript “s” denotes the interior surface, subscript “a” denotes air, and subscript “p” denotes a product. In some embodiments, the contact angle θ.sub.os(p) can be less than about 50°, less than about 40°, or less than about 30°.

Embodiments described herein relate to articles and methods for forming liquid surface films on the interior surfaces of containers for holding one or more products comprising one or more Bingham plastic materials. Bingham plastic materials behave as a solid under no or low shear stress, and behave as viscous liquids when an applied shear stress exceeds a yield stress. In some embodiments, a container for containing a product includes an interior surface and a liquid disposed on the interior surface. Before introduction of a product into a container, the liquid may be surrounded by air. The liquid-air interface in contact with the interior surface makes a contact angle, θ.sub.os(a), with respect to the interior surface of the container, of about 0°. After a product has been introduced to the container, the liquid is at least partially covered by the product. The liquid-product interface in contact with the interior surface, makes a contact angle, θ.sub.os(p), with respect to the interior surface, of less about 60°. The subscript “o” denotes the liquid, subscript “s” denotes the interior surface, subscript “a” denotes air, and subscript “p” denotes a product. In some embodiments, the contact angle θ.sub.os(p) can be less than about 50°, less than about 40°, or less than about 30°.

A package has a plurality of seamless compartments coupled together. A different one of the plurality compartments each includes a different respective one of a plurality of respective void spaces and a different respective one of a plurality of respective void space delimiting surfaces. A different one of a plurality of fill entries each forms a fluent entry into a different respective compartment's void space. At least one fill entry of said plurality is in an elastomeric portion of said package, and the at least one fill entry has a largest cross sectional area which is equal to or less than 25% of a largest cross sectional area of the compartment having the respective void space for which the fill entry forms the fluent entry. Each void space delimiting surface follows an outline of a separate 3D pill shape.

A package has a plurality of seamless compartments coupled together. A different one of the plurality compartments each includes a different respective one of a plurality of respective void spaces and a different respective one of a plurality of respective void space delimiting surfaces. A different one of a plurality of fill entries each forms a fluent entry into a different respective compartment's void space. At least one fill entry of said plurality is in an elastomeric portion of said package, and the at least one fill entry has a largest cross sectional area which is equal to or less than 25% of a largest cross sectional area of the compartment having the respective void space for which the fill entry forms the fluent entry. Each void space delimiting surface follows an outline of a separate 3D pill shape.

A filling device (10) comprises a filler nozzle (12) comprising a plurality of capillaries (14), and a filler valve (16), which is moveable relative to the filler nozzle (12). The filler valve (16) comprises a sealing plate (18) and a sealing component (20) moveable relative to the sealing plate (18). The sealing plate (18), when in contact with the filler nozzle (12), closes a plurality of the capillaries (14) but leaves at least one main capillary (14a) open. The sealing component (20) closes the at least one main capillary (14a) and is operable to create pressure along the at least one main capillary (14a).