A container for receiving therein a liquid is provided. The container comprises an upper portion, a lower portion opposite thereto, and sidewalls extending therebetween and all defining an enclosed volume therewithin. The upper portion comprises an opening to the volume. The container further comprises a cap configured to be secured to the upper portion for closing the enclosed volume. The upper portion is configured to be connected to the lower portion. The sidewalls are associated with one or more arrangements configured to facilitate connection to sidewalls of similarly constructed containers.

A stretch blow moulding system for PET containers with PET integral handles: the containers blown from injection moulded preforms: each preform having the integral handle projecting from a junction point on a body portion of the preform: containers blown in a continuously rotating stretch blow moulding machine of the system. In a preferred form the preforms are progressed continuously at a substantially constant speed: the containers blown therefrom progress at the same substantially constant speed through to the filling and capping machine: and wherein the containers progress continuously through the filling and capping machine at the same substantially constant speed. Also described is a continuous stretch blow moulding system applied to specified integral handle PET preform and PET blown container structures stretch blown from the preforms thereby to obtain variable wall thickness of the preforms and/or variable wall thickness of the containers.

An integrated liquid container system includes a housing and a liquid delivery container. The housing includes a housing top portion having a neck aperture, a housing bottom portion opposite the housing top portion, and a housing body portion extending between the housing top portion and the housing bottom portion and defining a housing inner cavity. The housing body portion includes a first surface and at least one aperture extending through the first surface of the housing body portion. The liquid delivery container includes a container top portion having a neck, a container bottom portion opposite the container top portion, and a container body portion extending between the container top portion and the container bottom portion to define a container inner cavity that stores liquid. The liquid delivery container being able to be received within the container inner cavity such that the neck aperture circumferentially extends around the neck.

Optimization method of a non-optimized glass bottle and optimized glass bottle, the optimized glass bottle comprising a base (11), a body portion (12), a shoulder portion (13), and a neck portion (14) with a mouth (15) providing access to a hollow interior thereof, wherein the body portion (12) presents axial symmetry around the axial axis (E) at least in its lower two-thirds, simplifying its manufacture, handling, and/or labeling; and the neck portion (14) presents axial symmetry around the axial axis (E) at least in its upper two-thirds, simplifying its manufacture, handling, labeling, and/or capping; wherein the shoulder portion (13) has a cross-section, perpendicular to the axial axis (E), that is oblong at least in its central part farthest away from the body and neck portions (12, 14), maximizing the visual front of the bottle (10) in relation to the inner volume of the shoulder portion (13).

A blow-molded article having improved well-defined corners is provided.

A dispensing container configured to store at least one substance wherein the dispensing container is further configured to be releasably secured to a vertical support surface. The dispensing container includes a body being formed from a plurality of walls, a top and a bottom contiguously formed to create an interior volume. The interior volume is configured to have at least one storage compartment having a substance stored therein. The body further includes a first dispenser integrally formed on the front wall of the body proximate the bottom thereof. A second dispenser is further included and is formed in the bottom of the body. A mounting tab is secured to the rear wall of the body. The mounting tab includes an upper portion and a lower portion wherein the lower portion has a pressure sensitive adhesive disposed thereon. The body is manufactured from a lightweight material.

A container defining a longitudinal axis and a transverse direction that is transverse with respect to the longitudinal axis. The container includes a finish and a sidewall portion extending from the finish. A plurality of ribs are defined by the sidewall. A base portion extends from the sidewall portion and encloses the sidewall portion to form a volume therein for retaining a commodity. The base portion has a contact surface for supporting the container. A plurality of straps extend radially along the base portion away from the longitudinal axis in the transverse direction, each one of the straps defines a strap surface that is closer to the finish than the contact surface. The plurality of ribs and the base portion are configured to place the container in a state of hydraulic charge-up when top load is applied to the container after the container is filled.

A polymeric container including a base, a body, a finish, finish threads, and a tamper lip. The body extends from the base. The finish defines an opening through which a product can pass into, and out of, an internal volume of the container defined at least in part by the body. The finish threads are at an outer surface of the finish, and are configured to cooperate with closure threads of a closure to secure the closure to the finish. The tamper lip extends from the outer surface of the finish, and is configured to replace the support flange during handling, and to cooperate with a tamper tab of the closure. The closure diameter is about the same as the neck diameter.

A multiple-chamber container that is extrusion blow molded with a single neck finish and a method to trim the single neck finish is provided. The physical appearance of the multiple-chamber container before the trimming process differs from the multiple-chamber container after the trimming process. The multiple-chamber container includes multiple openings that are configured to engage with a single cap after the trimming process to create a seal. The multiple-chamber container may contain different materials, such as liquids, gel-like substances, granular materials, food, etc. that are not permitted to flow from one chamber to the other chamber when the cap is engaged with the chamber openings.