A synthetic resin preform has a cylindrical mouth portion provided with a male thread on an outer peripheral surface, a cylindrical body portion continuous with the mouth portion and a bottom portion configured to close a lower end of the body portion, the preform being formed into a container of a predetermined shape by blow molding, the synthetic resin preform further including, between the mouth portion and the body portion, a holding surface continuous with the outer peripheral surface of the mouth portion and extending radially inward relative to the outer peripheral surface. Also, a container contains contents having a container filled with contents and configured to close the mouth portion with a cap, the container being formed by blow molding the preform.

A method for fabricating a preform by providing a plurality of preform segments which each define a portion of a preform, positioning said preform segments in continuous contact with each other along at least one edge of said preform segments such that said plurality of preform segments define a cavity, and bonding each of said preform segments to at least one other preform segment such that said plurality of preform segments forms a continuous whole.

A process of manual, semi-automatic and fully-automated integration of discrete components into a container that results in fast, reliable, cost-effective, and scalable production of composite containers is disclosed. The process can be embodied in manufacturing equipment that has a series of stations and may be called an assembly device. The equipment can produce containers, tubs, canisters, cartridges, etc. which are easily separated into different bio-degradable or compostable parts. Other container types are possible and are contemplated.

A method for fabricating a preform (100) by providing a plurality of preform segments (101-103) which each define a portion of a preform (100), positioning said preform segments (101-103) in continuous contact with each other along at least one edge of said preform segments (101-103) such that said plurality of preform segments (101-103) define a cavity (107), and bonding each of said preform segments (101-103) to at least one other preform segment such that said plurality of preform segments (101-103) forms a continuous whole.

A rotating disk-type preform alignment apparatus 1 including a disk 10, which is rotationally driven about a rotation axis tilted from a vertical direction, and a partition wall 28 erected outwardly of the disk, the apparatus being adapted to align preforms 100, which have been supplied onto the disk, at the peripheral edge of the disk and discharge the aligned preforms from a discharge section, the apparatus comprising: pockets 30 arranged side by side in a circumferential direction at the peripheral edge of the disk, each pocket having an opening portion into which the preform is dropped, and each pocket having a holding portion provided on the inner peripheral surface of the opening portion for holding the preform in an upright state; and a gas jetting unit 40, provided outwardly of the disk between a region where the preforms are supplied onto the disk and the discharge section, for jetting a gas from outside the pocket and from below the pocket, wherein the inner peripheral surface of the opening portion of the pocket has a tapered shape imitating the trunk shape of the preform.

A process of manual, semi-automatic and fully-automated integration of discrete components into a container that results in fast, reliable, cost-effective, and scalable production of composite containers is disclosed. The process can be embodied in manufacturing equipment that has a series of stations and may be called an assembly device. The equipment can produce containers, tubs, canisters, cartridges, etc. which are easily separated into different bio-degradable or compostable parts. Other container types are possible and are contemplated.

A rotating disk-type preform alignment apparatus 1 including a disk 10, which is rotationally driven about a rotation axis tilted from a vertical direction, and a partition wall 28 erected outwardly of the disk, the apparatus being adapted to align preforms 100, which have been supplied onto the disk, at the peripheral edge of the disk and discharge the aligned preforms from a discharge section, the apparatus comprising: pockets 30 arranged side by side in a circumferential direction at the peripheral edge of the disk, each pocket having an opening portion into which the preform is dropped, and each pocket having a holding portion provided on the inner peripheral surface of the opening portion for holding the preform in an upright state; and a gas jetting unit 40, provided outwardly of the disk between a region where the preforms are supplied onto the disk and the discharge section, for jetting a gas from outside the pocket and from below the pocket, wherein the inner peripheral surface of the opening portion of the pocket has a tapered shape imitating the trunk shape of the preform.

A process of manual, semi-automatic and fully-automated integration of discrete components into a container that results in fast, reliable, cost-effective, and scalable production of composite containers is disclosed. The process can be embodied in manufacturing equipment that has a series of stations and may be called an assembly device. The equipment can produce containers, tubs, canisters, cartridges, etc. which are easily separated into different bio-degradable or compostable parts. Other container types are possible and are contemplated.