A method of forming a cap assembly comprises injection molding a cap in a first shot from a first polymeric material, wherein the cap has an opening at one end defined by a perimeter. Injection molding a tamper band in a second shot from a second polymeric material such that the tamper band is monolithically attached to the perimeter of the cap. The first polymeric material and the second polymeric material comprise dissimilar resins and the tamper band is configured to sever from the cap with no burrs remaining on the perimeter of the cap.

A method of forming a cap assembly comprises injection molding a cap in a first shot from a first polymeric material, wherein the cap has an opening at one end defined by a perimeter. Injection molding a tamper band in a second shot from a second polymeric material such that the tamper band is monolithically attached to the perimeter of the cap. The first polymeric material and the second polymeric material comprise dissimilar resins and the tamper band is configured to sever from the cap with no burrs remaining on the perimeter of the cap.

A preferred low-profile liquid container lid assembly enables a user to outfit particularized liquid containers for enabling lid-based liquid-pooling or compartmentalization and heat transfer from lid-pooled or lid-compartmentalized liquid prior to liquid egression from a lid-outfitted liquid container prior to liquid consumption. All embodiments provide liquid re-directing or damming structures that operate to control the delivery of hot liquid for promoting heat loss from re-directed liquid flows. Certain structures cooperate with existing art to minimize leakage problems associated therewith. Other structures operate to particularly shape parceled liquid volumes for effecting rapid heat transfers therefrom. Still other structures harness material-philic properties of liquids for further effecting rapid heat transfers and liquid directional control mechanisms. Combinations of the various structural features here noted are also contemplated throughout the following specifications.

A preferred low-profile liquid container lid assembly enables a user to outfit particularized liquid containers for enabling lid-based liquid-pooling or compartmentalization and heat transfer from lid-pooled or lid-compartmentalized liquid prior to liquid egression from a lid-outfitted liquid container prior to liquid consumption. All embodiments provide liquid re-directing or damming structures that operate to control the delivery of hot liquid for promoting heat loss from re-directed liquid flows. Certain structures cooperate with existing art to minimize leakage problems associated therewith. Other structures operate to particularly shape parceled liquid volumes for effecting rapid heat transfers therefrom. Still other structures harness material-philic properties of liquids for further effecting rapid heat transfers and liquid directional control mechanisms. Combinations of the various structural features here noted are also contemplated throughout the following specifications.

A medicine container and a method of forming the medicine container are described herein. The medicine container includes a bottle and a bottle cap removably connected to the bottle. A dose cup is disposed over the bottle cap, the dose cup having an opening defined by a perimeter. A tamper band is monolithically coupled to the perimeter of the dose cup. The tamper band is directly connected to the bottle by a destructively attached connection.

A medicine container and a method of forming the medicine container are described herein. The medicine container includes a bottle and a bottle cap removably connected to the bottle. A dose cup is disposed over the bottle cap, the dose cup having an opening defined by a perimeter. A tamper band is monolithically coupled to the perimeter of the dose cup. The tamper band is directly connected to the bottle by a destructively attached connection.

A spheroidal dosing cap using a push-pull mechanism which includes a flow valve coupled to a spheroidal main body comprising a lower hemispherical element and an upper hemispherical element joined together through coupling or joining means, wherein the upper hemispherical element comprises a valve opening/closing orifice in its dome and a plug of the flow valve is inserted in the valve opening/closing orifice to close the flow of the substance running through the valve flow; a coupling section comprising a helical flange on its inner wall through which the flow valve couples to the threaded nozzle of the container.

A spheroidal dosing cap using a push-pull mechanism which includes a flow valve coupled to a spheroidal main body comprising a lower hemispherical element and an upper hemispherical element joined together through coupling or joining means, wherein the upper hemispherical element comprises a valve opening/closing orifice in its dome and a plug of the flow valve is inserted in the valve opening/closing orifice to close the flow of the substance running through the valve flow; a coupling section comprising a helical flange on its inner wall through which the flow valve couples to the threaded nozzle of the container.

A liquid container orifice assembly, lid assembly, and unibody lid construction enable a user to outfit particularized liquid containers for enabling lid-based liquid-pooling or compartmentalization and heat transfer from lid-pooled or lid-compartmentalized liquid prior to liquid egression from a lid-outfitted liquid container prior to liquid consumption. All embodiments provide liquid re-directing or damming structures that operate to control the delivery of hot liquid for promoting heat loss from re-directed liquid flows. Certain structures cooperate with existing art to minimize leakage problems associated therewith. Other structures operate to particularly shape parceled liquid volumes for effecting rapid heat transfers therefrom. Still other structures harness material-philic properties of liquids for further effecting rapid heat transfers and liquid directional control mechanisms. Combinations of the various structural features here noted are also contemplated throughout the following specifications.

A collapsible waste receptacle is disclosed with front and rear frame pieces generally defining an exterior boundary. The waste receptacle is configured to move between an expanded and a collapsed configuration. In the expanded configuration, a bottom frame piece may be attached to both the front frame piece and the rear frame piece to define at least a lower portion of the exterior boundary of the receptacle, and a top surface may contact the front frame piece and the rear frame piece. To transition to the collapsed configuration, the bottom frame piece may disconnect and rotate to generally vertical orientation within the exterior boundary of the receptacle. The top surface may rotate around a frame piece to generally vertical orientation outside the exterior boundary. The front and rear frame pieces may move towards each other to define a collapsed configuration, e.g. assisted by the inward folding of remaining side panels.