Disclosed is a method for manufacturing a container made of plastic, including the following steps: continuously extruding a hose, positioning an opened blow mold around the hose, so that the hose is arranged between the two blow mold halves, closing a hose gripper arranged at the blow mold to clamp the hose and simultaneously keeping the hose open at its upper side to form an inlet opening, separating the hose above the hose gripper to form the preform, horizontally moving the blow mold together with the preform hanging therein and held by the hose gripper into a blowing position, moving a blow mandrel assembly from above into the inlet opening of the preform, closing the blow mold halves, and inflating the preform in the blow mold to form a container.

The disclosure relates to a package having a package lower part for receiving a product and having a lid part attached to the package lower part for closing the package. The lid part includes a label and a carrier layer section, wherein the label adheres to the carrier layer section, and wherein the lid part is adhered to the package lower part by means of the label. Furthermore, the disclosure relates to a method of manufacturing a package.

A leak resistant lid assembly for a beverage container where the lid assembly has a straw or similar means for a user to drink liquid is disclosed. The lid assembly may include a base, a straw that extends through the base, a gasket, and a grommet. The base may have a primary opening that receives the straw and a secondary opening in the top of the base, where the secondary opening acts as a vent to prevent a vacuum from occurring when drinking from a straw. The grommet may have a spiral ring may help create a flow path for air from inside the beverage container to the exterior environment.

Disclosed is a chemical container capable of discharging gas generated from a chemical by stably securing a discharge passage of the gas even when the posture or tilt of the chemical container is variously changed, i.e. when the chemical container is turned over or falls sideways, whereby it is possible to prevent an excessive increase in internal pressure of the chemical container due to generation of the gas. The chemical container includes a container body having a storage compartment configured to store a chemical, an exhaust port disposed at one side of the container body, the exhaust port being configured to connect the storage compartment and the outside of the container body to each other in such a manner that fluid movement therebetween is possible, an exhaust tube disposed in the storage compartment so as to be connected to the exhaust port in such a manner that fluid movement therebetween is possible, and an exhaust buoyancy unit. The exhaust buoyancy unit has a buoyancy body disposed in the storage compartment in the state of being connected to the exhaust tube so as to float on the chemical stored in the storage compartment, an exhaust channel provided inside the buoyancy body, the exhaust channel being configured to connect the storage compartment and the exhaust tube to each other in such a manner that fluid movement therebetween is possible, and a filter membrane coupled to the buoyancy body, the filter membrane being configured to transmit gas through the exhaust channel and to block the chemical, thereby preventing the chemical from passing therethrough.