A bagging assembly for bagging bales of fibrous material is disclosed. The bagging assembly incorporates a chute defining a channel for receiving a bale, which is pushed there between by a stuffing assembly. Aspects of the bagging assembly include raising a bale using a bale elevator to a higher elevation position so that the bale could be stuffed by the stuffing assembly and using a bag retrieving mechanism for retrieving a bag from a bag location for use in bagging the bale.

An apparatus makes packages from a web of bags includes an indexing mechanism, an opening arrangement, engagement devices, and a sealing arrangement. The indexing mechanism moves the web. The opening arrangement opens a bag to form an opening so that a product can be placed into the bag. The engagement devices engage the bag and close the opening. Each engagement device includes a base, a first link, a second link, a sliding pivot, and a finger. The first link is pivotably connected to the base, and the second link is pivotably connected to the first link. The sliding pivot pivots with respect to the base and allows the second link to slide through the sliding pivot member. The finger is connected to the second link. The engagement devices pull a first and second sides of the bag in opposite directions. The sealing arrangement seals the opening of the bag.

A method and a device for opening a transport bag for loading and/or unloading, wherein the transport bag is conveyed along a conveying path by a conveyor system, in a suspended manner, to a device for opening the transport bag. The transport bag has a front and rear wall and a movable push element, which effects a relative movement of the front and rear wall with respect to one another between a closed bag state and an open bag state. An actively moved push device exerts a pushing force on a first end of the push element of the transport bag and the push element is converted from an idle conformation into a conformation subjected to a pushing force. The front and rear wall are thus moved relative to one another in the direction of an open bag state and the transport bag is opened for loading and/or unloading.

The invention concerns a flat package for a non sterile protective pouch (16) receiving a sterile surgical mesh; the package includes: an external envelope (2) including a front panel (3) and a complementary back panel (4), the inner face of the front panel (3) and the inner face of the back panel (4) being bonded respectively with a front layer (17) and with a back layer (18) of an internal envelope (15) made of a moisture-impervious material, the front panel (3) and the back panel (4) being jointed along the contours of the external envelope and, the package having an opening end comprising two tearable portions (8) configured to separate the front panel (3) upon which the front layer (17) of the internal envelope (15) is bonded from the back panel (4) upon which the back layer (18) of the internal envelope (15) is attached.

In a method of forming a coated bag for pre-treating an item stored in the bag, a bag is provided, having a sidewall extending from a closed bottom end to an open top end and defining an interior surface of a cavity. The bag is expanded from a flattened condition to an expanded condition. At least one adhesive dispenser is inserted through the open top end of the bag into the cavity. An adhesive is applied from the at least one inserted adhesive dispenser to form an adhesive coating on the interior surface of the cavity. A particulate dispenser is inserted through the open top end of the bag into the cavity. A particulate is discharged from the inserted particulate dispenser to embed the particulate in the adhesive coating. The adhesive coating is dried to retain the embedded particulate on the interior surface of the sidewall.

An automated packaging station is configured to inflate and seal a web material. The automated packaging station includes a rail, a nozzle, and a sealing system. The web material includes a channel that is closed so that the channel can be slid over the rail. The nozzle inserts gas into the channel of the web material, which is in fluid communication with chambers to inflate the chambers. The sealing system seals closed ends the chambers proximate the channel after inflation of the chambers. A shape of the rail causes the channel and an opposite longitudinal side of the web material to diverge either before or during inflation of the chambers by the nozzle.

A dirt removal and piling machine is ideally suited for use in cleaning and piling individualized and non-uniformly shaped workpieces, preferably sugar beets but also potatoes, other tuber crops, and even with aggregate rocks for a tilting receiving station. A further aspect of the present machine includes a workpiece unloading or receiving station which can tip sideways after a dump truck unloads the workpieces and longitudinally drives therethrough. In another aspect, the machine also includes a cleaning station having rotatable rollers, an underlying dirt conveyor and a moveable dirt dumping conveyor, hopper or bucket adjacent an end of the dirt conveyor and external to the rollers. Furthermore, another aspect of the machine includes an automatic and/or robotic sampling arm which is operable to remove a tuber crop workpiece sample and automatically package the sample after the sample has moved through a cleaning station.

A part packing system for packing a part in an elongated bag includes a bag holding machine including a first bag gripper mechanism, a second bag gripper mechanism, and an air nozzle. The first bag gripper mechanism is configured to hold a first end of the elongated bag. The first bag gripper mechanism opens the first end of the elongated bag. The second bag gripper mechanism is configured to hold a second end of the elongated bag. The second bag gripper mechanism closes the second end of the elongated bag. The air nozzle is located proximate to the first bag gripper mechanism. The air nozzle is configured to inflate the elongated bag with an airflow directed into the first end of the elongated bag. The first bag gripper mechanism holds the inflated elongated bag with the first end open to receive the part in the open first end while the air nozzle directs the airflow into the elongated bag.

The disclosed apparatus, systems and methods relate to preparation, modified atmosphere and high pressure pasteurization steps for treatment of retail fresh protein preparations. Protein is prepared and subsequently packaged in a modified atmosphere lacking significant amounts of oxygen and then exposed to high-pressure pasteurization. During preparation the protein may be exposed to aqueous ozone further reducing the microbial load, extending shelf-life, and increasing product safety.

A method of manufacturing shelf-stable gelato is provided. The method may include blending cream and sugar in a proportion. The blend may be frozen into units. The units may be freeze-dried in order to remove water content.