Capillary tube holder, a storage and shipping container in which a loaded capillary tube holder is securely held, a fixture for loading capillary tubes onto a capillary tube holder and a tube transfer fixture for transferring, removing or replacing individual capillary tubes from a loaded capillary tube holder.

A packing method and unit to pack articles, includes: moving first seats by a first conveyor and second seats by a second conveyor along first and second paths at first and second moving speeds, respectively; and cyclically transferring an article from a first seat to a second seat in a transfer station. The first seats and second seats each designed to house an article. During normal operation with no rejected articles, the first moving speed is functionally equal to the second moving speed, and the same number of first and second seats pass through the transfer station in a given time interval. Where at least one article is rejected in a first seat, the second moving speed is functionally decreased relative to the first moving speed so that two first seats (one containing the rejected article) passes through the transfer station in the time interval as one second seat.

A packing method and unit to pack articles, includes: moving first seats by a first conveyor and second seats by a second conveyor along first and second paths at first and second moving speeds, respectively; and cyclically transferring an article from a first seat to a second seat in a transfer station. The first seats and second seats each designed to house an article. During normal operation with no rejected articles, the first moving speed is functionally equal to the second moving speed, and the same number of first and second seats pass through the transfer station in a given time interval. Where at least one article is rejected in a first seat, the second moving speed is functionally decreased relative to the first moving speed so that two first seats (one containing the rejected article) passes through the transfer station in the time interval as one second seat.

A system and method for manufacturing erosion control filter socks consists of a mass of filtering material, a material supply assembly, an assembly section, and a packaging section. Switchgrass is used as the filtering material. Upon receiving the mass of filtering material, the material supply assembly appropriately transfers the filtering material to the assembly section. The filtering material is loaded into a receiving sock with the use of a sizing funnel in the assembly section to create a filter sock. The density of the filtering material within the filter sock varies. When loading is complete, the packaging section sizes the filter sock accordingly. When sizing the filter sock is complete, the filter sock is wrapped in a plastic cover so that the filter sock can be conveniently transported and installed.

A food product handling device includes a movable loading head having a plurality of coupling rails, a vacuum system operatively associated with the loading head, a plurality of suction devices carried by the loading head and configured to pick up and transport a food product, a plurality of mounting blocks slidably coupled to each other by the coupling rails, and an actuating device operatively associated with the mounting blocks for sliding each of the mounting blocks between a first position and a second position. Each of the suction devices is selectively coupled to the vacuum system. At least one of the suction devices coupled to each of the mounting blocks. The actuating device includes an actuating cylinder configured to displace the mounting blocks between the first position and a second position.

A width-adjustable packaging bag shaper, a bag maker, a packaging machine, and a method. The packaging machine including the bag maker, a traction device and a heat sealing device are respectively arranged above the bag maker, and a width adjustment device adjusts the distances between different sub bottom plates in a front bottom plate and a rear bottom plate by using a leadscrew and slide block mechanism, and then adjusts the width of a bottom plate. The leadscrew and slide block mechanism is used as the width adjustment device of the automatic width-adjustable noodle packaging bag shaper system, and four bottom plates are respectively fixed to the width adjustment device, so the leadscrew and slide block mechanism in operation is accurate in range of adjustment, is suitable for various widths of packaging bags, and has very important significance for the three-dimensional shaping effect of the packaging bags.

A system, and associated method, for launching and delivering separated food product in organized groups to a robotized packaging station for the product. The system initiates the delivery via a metered hopper of food product delivering the product to a launch V-belt that aligns the product end to end. A successive singulator belt, positioned adjacent to and receiving product from the launch belt, further organizes the product into a single file alignment. An optional separator belt may follow the singulator belt to create gaps between successive product units. The product is then delivered to a pick belt for product to be provided to the packaging robot. The system product information is from a single (per product delivery line) sensor, enabling intergrated end-to-end control from hopper to robot, and a nearly continuous motion of said pick belt.

A system, and associated method, for launching and delivering separated food product in organized groups to a robotized packaging station for the product. The system initiates the delivery via a metered hopper of food product delivering the product to a launch V-belt that aligns the product end to end. A successive singulator belt, positioned adjacent to and receiving product from the launch belt, further organizes the product into a single file alignment. An optional separator belt may follow the singulator belt to create gaps between successive product units. The product is then delivered to a pick belt for product to be provided to the packaging robot. The system product information is from a single (per product delivery line) sensor, enabling intergrated end-to-end control from hopper to robot, and a nearly continuous motion of said pick belt.

A system for transferring a first group of components of electronic cigarettes from first to second operating stations includes a flat collecting surface extending from a feeding zone to a releasing zone. A feeding device receives the components and feeds them onto the collecting surface. A first abutment element abuts the first component of the first group. A second abutment element abuts the last component of the first group. A compacting and stabilizing device moves the components closer together and stabilizes their positions. A first movement device moves the first and second abutment elements along the collecting surface to transfer the first group to the releasing zone. A tray faces the releasing zone to receive the first group. A pushing device pushes the components from the releasing zone into the tray. A transferring device transfers the tray with the first group towards the second operating station.

A system, and associated method, for launching and delivering separated food product in organized groups to a robotized packaging station for the product. The system initiates the delivery via a metered hopper of food product delivering the product to a launch V-belt that aligns the product end to end. A successive singulator belt, positioned adjacent to and receiving product from the launch belt, further organizes the product into a single file alignment. An optional separator belt may follow the singulator belt to create gaps between successive product units. The product is then delivered to a pick belt for product to be provided to the packaging robot. The system product information is from a single (per product delivery line) sensor, enabling integrated end-to-end control from hopper to robot, and a nearly continuous motion of said pick belt.