A viscous liquid supply apparatus includes a storage tank (10) that stores viscous liquid, and a pump (14) that supplies the viscous liquid stored in the storage tank to a use point, wherein the viscous liquid supply apparatus is configured with a viscometer (20) that measures a viscosity of the viscous liquid stored in the storage tank, and a replenishment device (30) that supplies replenishment liquid to the storage tank based on the viscosity measured with the viscometer. The viscometer (20) is a rotary type viscometer that has a rotor (23) in a cylindrical shape wherein the rotor is immersed in the viscous liquid and rotates therein, and the rotor is configured with a stirring blade that agitates the viscous liquid inside the storage tank (10).

A capsule article (100) includes a polymeric body (110) extending along a longitudinal axis from a first end to a second end and defining a capsule cavity (105) containing powder, and a metal foil (120) and a sealant layer (130) covering an outer surface of the polymeric body. A method of forming a hermetic capsule includes the steps of wrapping a capsule, with a metal foil; and enclosing the capsule with a sealant layer to form a hermetic barrier enclosing the capsule.

Exemplary embodiments of the disclosure may be drawn to ingestible delivery devices. An ingestible delivery device may include a first compartment and a second compartment. A lipase may be contained within the first compartment, and a fat may be contained within the second compartment. The first compartment may be sealed from the second compartment prior to exposure to a trigger, preventing the lipase and the fat from contacting each other, and at least one of the first compartment or the second compartment may at least partially rupture upon exposure to the trigger, allowing the lipase and the fat to contact each other.

The present invention discloses a closing station (100) for a capsule filling machine comprising a bottom (110) and a top closing unit (120) configured to displace towards each other, such that bottom pins (112) associated with said bottom closing unit urge into through holes of a body holder (B) to contact closed ends of each filled capsule body sections (114) and sliding them into said open ends of each capsule cap sections (124), such that each capsule is partially closed against an exerting pre-compressive force of the top pins (122) and is completely closed when force against biasing means (130) of said top pins (122) is exerted for providing telescoping closing of the cap (124) and body (114) sections of each capsule.

The disclosure relates to a capsule filling machine for filling two-piece capsules that each include a capsule upper part and a capsule lower part. The capsule filling machine includes a measuring device, the measuring device including a capacitive measuring system. The measuring device is downstream of the closing station. The capacitive measuring system includes a measuring section, along which the mass of the filled, closed capsule can be measured via the capacitive measuring system. The measuring device includes a guide device for the closed capsule, the guide device being configured to convey the filled, closed capsule from the capsule segment to the measuring section of the capacitive measuring system.

The present disclosure relates to a separable hard capsule for containing a medication. The capsule may be opened by finger force and used, for example, by pediatric and geriatric patients.

A comestible gelatin capsule 10 for holding a substance in hermetic isolation includes a capsule body 12, a diaphragm 14 located within the capsule body and an end cap 16. Overlapping open end regions of walls 22 and 28 of the capsule body 12 and of the diaphragm 14, respectively, are fused to one another in a fusion welding process wherein the end regions undergo partial phase change so as to form a circumferential fused homogeneous sealing zone 36. The overlapping end regions are bent inwardly in the fusion welding process such that a portion of the wall 22 extends inwardly across a portion of the wall 28 thereby restricting axial movement of the capsule body and the diaphragm relative to one another forming a stable robust and effective hermetic seal.

A method for producing starch soft capsules comprises the following steps: preparing a mixture comprising starch, plasticizer and water, wherein more than 50 weight percent of the starch is present in the form of particles of granular starch; shaping the mixture to form a film in a shaping process; solidifying the mixture by increasing the temperature of the mixture during and/or after the shaping process by more than 5° C.; and shaping the film to form a soft capsule. Soft capsules produced by this method have starch particles bonded to one another. A device for performing this method comprises a shaping device to enable shaping of the starch material to form a film, and a heating device to perform a heat treatment to destructure the starch during and/or after the shaping. It comprises a rotary die device.

Exemplary embodiments of the disclosure may be drawn to ingestible delivery devices. An ingestible delivery device may include a first compartment and a second compartment. A lipase may be contained within the first compartment, and a fat may be contained within the second compartment. The first compartment may be sealed from the second compartment prior to exposure to a trigger, preventing the lipase and the fat from contacting each other, and at least one of the first compartment or the second compartment may at least partially rupture upon exposure to the trigger, allowing the lipase and the fat to contact each other.

There is provided a method by which microtags can be attached to a product at a product processing facility other than the manufacturer such as a dispensing pharmacy. Also, it is an object to attach microtags to a hard capsule in a simple manner. There is provided a band seal preparation liquid for sealing a hard capsule, the band seal preparation liquid containing microtags that enable a product to be identified.