A loose material measuring and dispensing system including a container and dispenser. The tea container serves to store the tea leaves or grounds in a storage bin prior to activation of the system. Upon activation, the dispenser measures and loads a selected amount of tea into a hopper for dispensing, such as into a waiting cup or a tea infuser. The amount of tea may be selected based upon user operation of one of a number of quantity indicating/selection buttons provided in a user interface. The container is a sealed canister, such as a bag or jug, which is preferably impermeable to light. Furthermore, the dispenser is able to operate to load a desired amount of tea (e.g. by weight), specified by the user, into the hopper. Once the desired amount of tea is loaded into the hopper, the tea may be dispensed, such as into a waiting cup or infuser below.

A bin (101, 201, 301) that holds articles sorted out by a sorter has an inlet opening (102, 202, 302) for delivering the articles to an interior of the bin and a discharge device (103, 203, 303) for removing the articles therefrom, the discharge device being normally arranged below the inlet opening. The discharge device has a flap (104, 204, 304), pivotally supported for rotation about an axis (105, 205, 305), as well as two sidewalls (106, 206, 306), attached laterally to the flap. The bin includes a motion-guiding arrangement in which a guide track (107, 207, 307) and a pin (108, 208, 308) are arranged for complementary engagement in an operating state of the bin. Either the pin or the guide track is arranged on one of the sidewalls, with the other part arranged on a side of the bin.

A bin (101, 201, 301) that holds articles sorted out by a sorter has an inlet opening (102, 202, 302) for delivering the articles to an interior of the bin and a discharge device (103, 203, 303) for removing the articles therefrom, the discharge device being normally arranged below the inlet opening. The discharge device has a flap (104, 204, 304), pivotally supported for rotation about an axis (105, 205, 305), as well as two sidewalls (106, 206, 306), attached laterally to the flap. The bin includes a motion-guiding arrangement in which a guide track (107, 207, 307) and a pin (108, 208, 308) are arranged for complementary engagement in an operating state of the bin. Either the pin or the guide track is arranged on one of the sidewalls, with the other part arranged on a side of the bin.

Blanket replacement systems and methods useable with an image forming apparatus are provided herein. The blanket replacement system removes the blanket from the image transfer member and attaches the blanket to the image transfer member. The blanket replacement system includes a frame member, an engagement motor, and a rotation motor. The frame member holds a blanket having a lead edge portion on one edge and a trail edge portion on an opposing edge. The frame member further includes a lead edge clamp unit and a trail edge clamp unit that holds the lead edge and trail edge portions of the blanket and engages with an image transfer member. The engagement motor engages with the frame member and moves the frame member laterally in relation to the engagement motor. The rotation motor is connected to the engagement motor and rotates the engagement motor and the frame member.

A method for monitoring a filled container, in particular a filled beverage container, which is conveyed on a conveyor, comprising the steps of taking up the container by a carriage, creating a spacing between the container and the conveyor, so that the entire weight of the container is retained by the carriage in a weighing region, and weighing the retained container in the weighing region using a load cell comprised by the carriage, the carriage being driven by a linear motor according to said method, and a monitoring system for filled containers, in particular filled beverage containers, for executing such a method.

A method and system for correcting mass flow rate measurements relating to a conveyor used to move a stream of first component material portions to and through a mixing station in which a second component material is dispensed in a predetermined mass percentage of the mass of the first component material portions. The correction of the measurements is adapted to correct for inaccuracies that arise in the measurements due to, for example, differences in the first component material portions properties, differences in the second component material properties, environmental conditions, drift of electronic instruments, and changing conditions that occur during extended use of an upstream conveyor that delivers first component material portions to the mixing station.

A checkweigher (10) for measuring the weight of a pre-metered dose of medicament in a pharmaceutical blister (12) is provided. The checkweigher comprises a rotatable blister support element (14) for supporting a plurality of blisters (12), an evacuation assembly (16) for sequentially accessing and removing the contents of the plurality of blisters (12) as the blister support element rotates, a load sensor (18) for weighing the blister support element (14) and the plurality of blisters (12), drive means (20) for moving the blister support element (14) to and from the load sensor (18), and a controller (22) for controlling the drive means (20). The plurality of blisters (12) may be provided as single blister units or as part of a blister pack.

A checkweigher (10) for measuring the weight of a pre-metered dose of medicament in a pharmaceutical blister (12) is provided. The checkweigher comprises a rotatable blister support element (14) for supporting a plurality of blisters (12), an evacuation assembly (16) for sequentially accessing and removing the contents of the plurality of blisters (12) as the blister support element rotates, a load sensor (18) for weighing the blister support element (14) and the plurality of blisters (12), drive means (20) for moving the blister support element (14) to and from the load sensor (18), and a controller (22) for controlling the drive means (20). The plurality of blisters (12) may be provided as single blister units or as part of a blister pack.

The analyzer mixes the material to be analyzed and the flux in sample holders supported by a moveable platform within the furnace. A tilt member is provided having multiple stations. Each station has an upstanding pin offset from the center point of the station in a different direction. The platform is indexed relative to the tilt member such that the sample holder aligns with each station, in sequence. As the sample holder aligns with each station, the platform is moved toward the tilt member such that the pin of the aligned station abuts and tilts the sample holder in a different direction. The repeated tilting of the sample holder in different directions mixes the material and flux. The contents of the sample holder may also be agitated by rapidly moving the platform back and forth with sudden stops. The analyzer can be used with a special sample holder.

A system of detecting loading and unloading of mobile containers such as grain carts utilizes two low pass filters to determine whether the contents of the container are changing by subtracting one filter signal from the other, and using the sign of the difference. Weighing performance is improved by utilizing accelerometers to compensate for measurement dynamics and non-level orientation. Failure and degradation of weight sensors is detected by testing sensor half bridges. Loading and unloading weights can be tied to specific vehicles by utilizing RF beacons.