The present disclosure is directed to bottles that are configured to undergo a controlled collapse in response to pressure being placed on the front and rear walls manually by a user, vacuum forces acting inside the bottle during a tube feeding process, or both. The bottles include a rigid hanging element that is molded into an access channel provided on the base of the bottle, such that the top and sides of the hanging element are fixedly connected with a surface of the container. Due to the presence of the hanging element, the bottle includes hinge lines focus the collapse in the central area of the bottle between the hanging element and the shoulder of the bottle. Accordingly, the present bottles provide both a rigid hanging element and walls that collapse in a controlled manner.

A plastic container including a top container portion having a plurality of spaced top strut members, a bottom container portion having a plurality of spaced bottom strut members, and a middle container portion located between the top and bottom container portions. The top, bottom and middle container portions oriented along a container axis. The middle container portion includes a plurality of annular rib members each rib member being separated from longitudinally adjacent rib members by an annular groove, each groove having a number of middle strut members disposed along a length of the groove, adjacent middle strut members of adjacent grooves being longitudinally aligned. Each container portion comprises a plurality of first columns comprised collectively of a top strut member, middle strut members and a bottom strut member the top strut member, middle strut members and bottom strut member comprising each of the first columns are longitudinally aligned.

A plastic bottle, in particular a toilet cleanser bottle, has a bottle container, preferably formed by blow-molding, with a bottle neck and an angled attachment. The attachment is snapped onto the bottle neck in a direction of placement. The bottle neck has a first snap connection element and the attachment has a second snap connection element. In order to ensure a defined angular orientation between the angled attachment and the bottle container, an anti-rotation lock is formed between the attachment and the bottle neck, in particular between the two snap connection elements. To this end, preferably the snap connection elements engage positively with one another by way of toothings. Alternatively, an elevation having recesses is formed on a bottle shoulder for ensuring the anti-rotation lock.

A dispenser for dispensing a liquid is disclosed. The dispenser comprises an outlet for dispensing a liquid, a reservoir for liquid, and a closure configured to engage with the dispenser and movable between a closed position in which the outlet is enclosed and an open position in which the outlet is not enclosed. The dispenser further comprises an arrangement for controlling liquid communication between the reservoir and the outlet, the arrangement and reservoir movable with respect to each other between a first configuration in which the reservoir is not in liquid communication with the outlet and a second configuration in which the reservoir is in liquid communication with the outlet. By requiring a second movement after removal of the closure accidental access or dispensing of the contents may be avoided or reduced.

A plastic container that is fabricated from an extrudable polyethylene terephthalate (PET) using an extrusion blow molding process includes a neck portion, a bottom portion and a main body portion. The main body portion has a central opening that extends completely through the main body portion and may have generally toroidal area surrounding the central opening. The bottom portion includes a plurality of support feet and a substantially smooth central raised portion that has substantially no discontinuities such as the gate well that is commonly found on PET containers fabricated using the conventional stretch blow molding process. The neck portion may be offset from a longitudinal axis of the container so as to facilitate pouring by a consumer.

A collapsible bottle with a channelway provided in a side wall which, in collapsed conditions of the bottle, the channelway becomes engaged with opposed portions of the side wall and define a flow passageway therethrough toward a discharge opening at one end of the bottle and a closed other end of the bottle.

Thermoplastic container (1) which after filling and sealing is able to withstand without any substantial deformation to an internal pressure lower than atmospheric pressure, comprising a body (2) with substantially cylindrical upper (3) and lower (4) parts and an intermediate part (5) having a curvilinear triangular cross section and comprising three main faces (6a, 6b, 6c) joined by three edges (7a, 7b, 7c); these edges are rounded, having continuous curvature, joined tangentially to the main faces and have radii of curvature (ra, rb, rc) comprised between approximately 5% and 35% of the largest dimension (D) of the cross section of the lower part (3); the main faces have radii of curvature (Ra, Rb, Rc) greater than the largest dimension (D) of the cross section of the lower part (3).

A polygonal bottle, and mouth, shoulder, drum, and bottom sections are formed in a bottle axial direction, the drum section including main wall sections connected via connecting sections in a circumferential direction about a bottle axis, in a lateral cross sectional view perpendicular thereto, a polygonal shape is formed, in which a panel section recessed inward in a radial direction, extending in the bottle axial direction and arriving at an upper portion of the mouth section side of the main wall section formed at the main wall sections of the drum section. A reinforcement protrusion protruding outward in the radial direction is formed at shoulder section connecting portions, a top surface directed outward in the radial direction is continued to an outer circumferential surface of the drum section with no step difference, and an upper surface directed upward is formed in a curved surface shape protruding upward.

A plastic container that is adapted for adjustment to internal volumetric changes such as those that occur during the hot-fill process includes a container body defining an internal space and having a sidewall. The container body has a maximum lateral dimension and a plurality of flexible panels and posts defined in the sidewall. The posts are respectively interposed between the flexible panels around the outer circumference of the sidewall. Each of the plurality of posts has a minimum width and a maximum width, and a ratio of the minimum width to maximum width is preferably within a range of about 0.3 to about 0.7. A ratio of the minimum width to the maximum lateral dimension is preferably within a range of about 0.05 to about 0.30. In addition, a ratio of the maximum width to the maximum lateral dimension is preferably within a range of about 0.15 to about 0.45.

Disclosed is an injection stretch blow molded (ISBM) container containing a surface having a static coefficient of friction (COF) of 0.15 to 0.21, a dynamic COF of 0.06 to 0.1, wherein the surface retains a water contact angle of 76 or higher for up to three minutes after wetting of the surface with a water drop of 14 to 16 mm diameter and the container is made with a polymeric composition containing a high density polyethylene (HDPE) having a dispersity (Mw/Mn) of 9 or higher as measured by GPC; a MI2 of 1 g/10 min or higher as measured by ASTM D-1238; 190 C./2.16 kg, as measured by ASTM D-1238; and an environmental stress crack resistance (ESCR) at 100% Igepal of >150 hours as measured by ASTM D-1693, B.