A system is disclosed for controlling the disgorging of objects. The system includes a container system including a container for containing objects, rotation means for rotating the container to a disgorgement angle, and movement means for moving at least a portion of the container system in a repetitious manner with a net zero distance of travel of the at least the portion of the container system such that the objects are disgorged from the container at a controlled rate of disgorgement.

A fluid dispensing container is provided. The container includes a container body formed from a first flexible material defining an interior cavity. The container includes a membrane formed from a second flexible material and a seal coupling the membrane to the inner surface of the container body. The membrane divides the interior cavity into a contents chamber and a dispensing chamber, and the membrane and the seal are configured to be fluid tight to maintain fluid within the contents chamber prior to rupture of the membrane. The rupture stress of the second flexible material is less than the rupture stress of the first flexible material such that, as fluid pressure within the contents chamber increases, the membrane is configured to rupture without the container body rupturing.

A liner L has a liner body 11 with a front wall 12, rear wall 16, bottom wall 13, a top wall 14. The top wall also includes a tubular excess liner material or chute 19 located close to the rear wall and which includes a filling fitment 20 with a fitment cap 21. The liner also has a cylindrical, hose content inlet/outlet port or bottom fitment 23. The liner may include a gap-filler or filler strip 70 of foam material extending outwardly from a position closely adjacent the outlet fitment. The filler strip is mounted to the front wall directly over and closely adjacent the outlet fitment. The filler strip may taper so that at least a majority of the strip's longitudinal length or height so as to increase in its lateral width as it approaches the outlet fitment, thereby increasing the material volume of strip material.

A method of forming and filling a pouch, comprises forming opposing walls of a film; sealing the opposing walls of film together to form at least one pouch; filling an interior section of the at least one pouch through an opening in an upper portion of the at least one pouch with a flowable material; forming a top sealed expressing-shaped region to close the opening in the at least one pouch; and cradling the pouch with a foldable flat that is more rigid than the pouch that can be folded or rolled to compress the pouch to express the flowable material through the expressing shaped region.

The invention proposes to dispense a substance from a container filled with a single portion of a substance. The container comprises a preformed deformable body defining a filling cavity which body has an opening and an integral planar circumferential rim surrounding said opening. The opening is closed by a cover sheet which is sealed to the circumferential rim by a circumferential sealing seam. The circumferential rim has a dispensing part which is covered by the cover sheet. A dispensing passage is formed between the dispensing part and the cover sheet. At the location of the dispensing passage is provided a weakened sealing seam portion, such that upon pressurizing the content of the container, the weakened sealing seam portion breaks and substance flows out of the container through the dispensing passage. The dispensing part is flat and the dispensing passage for the substance is defined by the cover sheet sealed to the flat dispensing part by at least two outwardly directed sealing seams. The outwardly directed sealing seams extend at a distance from one another from the circumferential sealing seam to the edge of the dispensing part.

A bag opening system according to the present disclosure has high tolerance for the shape of a bag and comprises: a bag opening container which is formed to have an open upper portion so as to be capable of receiving a bag used to store powdered or granulated material and which has, on at least one of a side face and a bottom face thereof, a discharge window through which the powdered or granulated material can pass but the bag cannot; a cutting mechanism that inserts, into the discharge window, a bag cutter for cutting the bag, thereby forming, in the bag, a discharge opening through which the powdered or granulated material can flow out; and a swing mechanism that swings the bag opening container to cause the powdered or granulated material to flow out from the discharge opening and through the discharge window to the outside of the bag opening container.

In compounding pharmaceuticals at the outset, the medications are typically arrive in their mass produced form (pills, creams, syrups, etc.) and are individually packaged. Some packaging forms, particularly tubes, take an excessive amount of time to empty for the medication to be used in later compound medications. Presently in this industry, human workers will squeeze the medication out of each individual tube into large bucket containers for storage until the medication is ready for mixing. The disclosed invention provides a novel apparatus and method for emptying multiple tubes at a time with limited human interaction. The apparatus uses a roller and cap-pressing method that can empty several tubes at one time, significantly increasing efficiency. The apparatus is then connected with a novel software package which controls the operation of the device and can provide a counting mechanism for contract monitoring and predicting the lifespan of the device.

A method of forming and filling a pouch, comprises forming opposing walls of a film; sealing the opposing walls of film together to form at least one pouch; filling an interior section of the at least one pouch through an opening in an upper portion of the at least one pouch with a flowable material; forming a top sealed expressing-shaped region to close the opening in the at least one pouch; and cradling the pouch with a foldable flat that is more rigid than the pouch that can be folded or rolled to compress the pouch to express the flowable material through the expressing shaped region.

A fluid dispensing container is provided. The container includes a container body formed from a first flexible material defining an interior cavity. The container includes a membrane formed from a second flexible material and a seal coupling the membrane to the inner surface of the container body. The membrane divides the interior cavity into a contents chamber and a dispensing chamber, and the membrane and the seal are configured to be fluid tight to maintain fluid within the contents chamber prior to rupture of the membrane. The rupture stress of the second flexible material is less than the rupture stress of the first flexible material such that, as fluid pressure within the contents chamber increases, the membrane is configured to rupture without the container body rupturing.

An improved apparatus 100 for cutting and squeezing sachets/pouches is disclosed, having a cutting and sliding assembly 200 configured to allow linear movement of one or more sachets/pouches and cut the one or more sachets/pouches as the one or more sachets/pouches undergo linear movement: and a roller assembly 300 configured to pull the one or more sachets/pouches through the cutting and sliding assembly. and squeeze the one or more sachets/pouches as the one or more sachets are pulled. the squeezing resulting in extracting contents of the one or more sachets/pouches. The cutting and sliding assembly 200 and the roller assembly 300 are accommodated within a container assembly 400 such that the squeezed out contents are collected within a container of the container assembly 400.