A dispenser actuator assembly (100) has base member (102) and an actuator arm (104) that is configured to crush a glass ampoule assembly (10). The glass ampoule assembly (10) has a rupturable glass ampoule (12) containing a flowable material (M). The glass ampoule (12) is contained within an outer container (14), the outer container (14) having a first open end (22) and a second closed end (24). The glass ampoule assembly (10) has an applicator (16) positioned in the first open end (22). The dispenser actuator assembly (100) has the base member (102) that is configured to mount on the outer container (14). The actuator arm (104) is pivotally connected to the base member (102). The actuator arm (104) is pivotable from a first position to a second position that is configured to engage the outer container (14) to crush the glass ampoule (12) wherein the flowable material (M) is dispensed from the glass ampoule assembly (10).

A tool slide, in particular a wedge drive, including at least one slide bed and one slide part. The slide part is arranged on the slide bed in sliding fashion and in order to absorb transverse forces, a groove and a stud protrudcvfording into the groove are provided, which restrict a transverse motion of the slide part in the slide bed. Between the stud and the groove, at least one sliding element is provided. A driver that can be removed from the slide part is provided and between the slide part and the driver in the contacting state, there is a prism guide composed of inclined elements of the slide body and corresponding inclined surfaces of the driver. Between the slide bed and the slide body, a flat guide is embodied so that the sliding elements of the slide bed and corresponding sliding elements of the slide body are perpendicular to an x axis, thus enabling a movement transverse to the x axis.

An apparatus and system for dispensing a food and beverage product where a flowable product is extracted from a flexible pouch, and where a nozzle region exists through which the flowable product evacuates the flexible pouch. The nozzle region has a lock seal that locks the flowable product within the flexible pouch when a pressure less than a first threshold value is applied to the flexible pouch. There is also a frangible seal located above the nozzle region that is configured to lock the flowable product within the flexible pouch when pressure less than a second threshold value is applied to the flexible pouch and when the first threshold value is larger than the second threshold value.

A preform made from two different materials that do not bond together by a bi-injection process, using the same mold, is presented. An outer layer of the preform can be first made, then an inner layer molded through a center hole in a bottom of the outer layer, and the two layers connected. Inner/outer preform materials can be different, such as PET/polyolefin or polyamide, or the same, such as PET/PET. To prevent mutual bonding during molding of the second layer, a non-stick coating may be sprayed onto a surface portion of the first layer prior to molding the second. In embodiments, manufacturing order can be either outer/inner, or inner/outer, and the non-stick coating sprayed on the inside/outside of the layer first molded.

The present invention provides a double container capable of suppressing the deterioration of the gas barrier property under high humidity environment. According to the present invention, provided is a double container comprising a container body, wherein the container body has an outer shell and the inner bag, the container body is configured such that the inner bag contracts as content is reduced, and the inner bag comprises an inner layer, a gas barrier layer, and an outer layer, in order from an inside of the container body.

Disclosed are flexible fluid reservoirs including a front sheet and a back sheet, each comprising a four-layer insulated wall. The four-layer insulated wall includes an interior layer and an exterior layer, and a metallic film layer and an insulation layer disposed between the interior layer and the exterior layer where the metallic film layer is oriented toward the exterior layer and the insulation layer is oriented toward the interior layer. One or more of the interior or exterior layers can be a metallocene modified polyethylene film. The metallic film layer can be aluminum coated polyethylene terephthalate resin. The insulation layer can be a foam layer comprising closed cell polyethylene resin. The four-layer insulated wall can resist or limit temperature changes of a fluid disposed within the reservoir for a period of time. The insulated fluid reservoirs can include closure mechanisms for sealing an upper opening of the reservoir.

A cartridge for a dispensing device has at least one inherently non-rigid, elongate film pouch, which has a chamber for receiving a composition. The cartridge also has a head part for interacting with the film pouch. The head part has an inherently rigid insert, which is connected to the film pouch on a side facing the head part. A connecting device is provided, which can connect the insert to the head part in a form-fitting and/or force-fitting manner. The insert has at least one first connecting element of the connecting device and the head part has at least one second connecting element of the connecting device.

A manufacturing method includes an injection molding process of injection-molding a preform having a two-layer structure including an outer layer preform and an inner layer preform, and a blow molding process of blow molding the preform to mold a delamination container made of resin. The injection molding process includes an outer layer molding process of filling an outer layer injection mold with PET (outer layer resin material) to mold the outer layer preform and molding a thin film portion in a part of the outer layer preform, and an inner layer molding process of injecting PP (inner layer resin material) toward the thin film portion to break the thin film portion and filling an inner layer injection mold with PP having a temperature lower than a melting point of PET via the broken thin film portion to mold the inner layer preform.

Provided is a storage container that includes a body that defines an interior of the storage container, and a bag contained within the interior of the storage container. The bag is constructed of an elastomer, includes an opening, and defines a bag interior configured to contain a material. The storage container further includes a material valve assembly coupled to a portion of the body. The material valve assembly is coupled to the bag and configured to selectively provide fluid communication between the bag interior and an external environment of the storage container.

Provided is a closure device for closing a soft packaging container, the closure device including a holding section configured to hold a soft packaging container, a dispense section configured to dispense contents of the soft packaging container, a closure section configured to close the soft packaging container, and a control section configured to control timing for closing the soft packaging container by the closure section. The control section may include an acquisition section configured to acquire time information related to timing for closing the soft packaging container. Provided is a soft packaging container for accommodating contents, the soft packaging container including a main region for accommodating the contents, and an extension region provided by being extended from the main region.