A system, that includes a container, that includes a first container opening, a liner disposed in the first container opening, a pump connected to the container, and a controller, where the controller is programmed to perform a method for filling the container with the liner, that includes making a first determination that a power on condition is satisfied, in response to the first determination, providing power to the pump, and after providing the power to the pump, making a second determination that a power off condition is satisfied, and in response to the second determination, cutting the power to the pump.

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.

Provided is a delamination container having excellent content dischargeability. The delamination container includes an outer layer and an inner layer. The inner layer peels from the outer layer and shrinks with reductions in contents. The outer layer consists of a single layer or multiple layers. At least one of innermost and outermost layers of the outer layer contains a lubricant.

A device for treating hollow bodies, comprising at least a nozzle and a circuit for setting a pressurized airflow in circulation, having a valve and a first pressure sensor measuring a first pressure; a control distributor of said valve; a line connecting said distributor to said valve; a control unit with a time measurement component; wherein said device comprises a second pressure sensor situated along said line, measuring a second pressure, and wherein said control unit comprises means that are able to determine a differential between the measurement of the first pressure and the measurement of the second pressure as a function of time. The invention also relates to a corresponding treatment method.

The present disclosure relates to an integrated liner-based system having an overpack and a liner provided within the overpack, the liner comprising a mouth and a liner wall forming an interior cavity of the liner and having a thickness such that the liner is substantially self-supporting in an expanded state, but is collapsible at a pressure of less than about 20 psi. The liner and overpack may be made by blow molding the liner and the overpack at the same time using nested preforms.

A liner structure includes a liner main body and an insert located inside an opening of the liner main body. The liner main body is made of a polybutylene material. The liner structure has relatively good heat resistance within a temperature range corresponding to conventional liquid water, and can be used for containing hot water. Moreover, a feasible manufacturing method is provided. The method can overcome defects of material characteristics through process optimization, so that can implement manufacturing the liner structure.

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.

The disclosure relates to a method for molding and coating a container comprising fibers, in particular pulp, wherein the method comprises: molding a container comprising fibers, in particular pulp, which container comprises an opening, wherein the container is provided in a mold and in particular is molded around a coating bladder, or molding container elements comprising fibers, in particular pulp, which container elements comprise an opening, wherein the container elements are provided in a mold and in particular are molded around a coating bladder; molding the coating bladder, which is arranged at least temporarily and/or partially in the container or the container elements; applying a pressure medium from a pressure source to the coating bladder to expand it, so that the coating bladder is at least partially applied to an inner wall of the container or the container elements.

The present disclosure is directed to embodiments of catheter-based prosthetic heart valves. In one embodiment, a prosthetic heart valve includes a collapsible and expandable annular frame, a leaflet assembly mounted within the annular frame, a first skirt mounted on the frame, and a second skirt mounted on the frame. The frame includes a plurality of rows of cells. The leaflet assembly includes a plurality of leaflets. Adjacent leaflets are connected to each other to form commissures, each of which is connected to a cell of an outflow row of cells of the frame.

Manufacturing techniques are provided for dispenser containers. An external container is formed from a dimensionally stable material. A preform is provided that has a cup-like molded body constructed from at least two portions. A first portion is made of a blow moldable elastic plastic that is intended for the formation of an internal-container body. A second portion is made of a dimensionally stable plastic for the formation of an internal-container dispensing portion. The second portion has on its outer surface a slot-like recess to provide a vent duct. The preform is heated thereby introducing the preform into the external container and introducing a stretch blow molding pin into the preform. The blow molding is stretched in order to form an internal container with expulsion of the air contained in the space located between the preform and the external container such that the air escapes into the environment via the vent duct.