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 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.

The present invention relates to a method and device for collecting, washing and drying solid particle samples used in collecting the solid particle samples in sample collection work in the fields of industrial production and scientific research, and particularly relates to a method and device for collecting, washing and drying solid particles by pneumatic conveying. A method for collecting, washing and drying solid particles by pneumatic conveying comprises: collecting and conveying a sample mixture containing solid particles into a solid particle collecting and processing device by a pneumatic conveying airflow; then disturbing and diluting the collected sample mixture containing solid particles in the solid particle collecting and processing device by the pneumatic conveying airflow and a washing liquid to filter and wash solid particle samples. The present invention overcomes the problems in the prior art: washing and drying to realize automatic one-stop completion of collection.

A method for treating a perishable product including determining a desired product treatment outcome selected from sanitation, protection, preservation, or enhancement of the perishable product; directly applying a substance to the surface of the perishable product after harvesting using a carrier; wet or dry washing the perishable product; and packaging the perishable product. A system for treating a perishable product with a substance treatment including one or more devices for directed substance application to a surface of the perishable products prior to final packaging of the perishable product using a carrier; and wherein the one or more devices is an electrostatically charging device or a nebulizer Embodiments of the invention enhance the efficacy of sanitizers and other functional substances for increasing the quality, safety, and overall shelf life of perishable products through improved coating and distribution of the sanitizers and functional substances on the surface of perishable product.

Embodiments of a compressed and coreless roll of sheet product having a center indicator are disclosed. According to an embodiment of the present invention, a compressed coreless roll of sheet product is provided. The compressed coreless roll of sheet product includes a sheet product having a first end and a second end. The sheet product is wound about an axis beginning with the first end and ending with the second end to partially define an axial cavity along the axis. The first end includes an indicator that is visible when the sheet product roll is compressed such that the axial cavity is substantially collapsed.

A compactor device for compacting a product filling in a container, like a packing box, includes a container support allowing shaking and/or vibrating the container when supported on the container support. The support includes compactor roller bars arranged parallel in a direction transverse to a conveying direction and to support the container. Each compactor roller bar has a rotation axis and a circumferential surface to allow moving the container with a product filling supported on the rollers bars up and down at a selected frequency when, in operation, rotating the compactor roller bars of the plurality of compactor roller bars. The compactor device further has a stopper arrangement blocking conveying the container by the compactor roller bars, and a pressing arrangement with a press to press downwards onto the product filling within the container while, in operation, compacting the product by rotating the compactor roller bars.

A method of packaging water-reactive aluminum may include directing at least one discrete object into a container, the at least one discrete object including an aluminum alloy, the aluminum alloy plastically deformed and non-recrystallized, introducing, into the container, a liquid metal alloy including one or more activation metals, enclosing the at least one discrete object and the liquid metal alloy with one another in the container to form a kit, for a predetermined period, exposing the kit to a heating environment, and agitating the at least one discrete object and the liquid metal alloy in the container in the heating environment during the predetermined period to form the kit into a packaged unit of water-reactive aluminum.

A method of packaging water-reactive aluminum may include directing at least one discrete object into a container, the at least one discrete object including an aluminum alloy, the aluminum alloy plastically deformed and non-recrystallized, introducing, into the container, a liquid metal alloy including one or more activation metals, enclosing the at least one discrete object and the liquid metal alloy with one another in the container to form a kit, for a predetermined period, exposing the kit to a heating environment, and agitating the at least one discrete object and the liquid metal alloy in the container in the heating environment during the predetermined period to form the kit into a packaged unit of water-reactive aluminum.

Medical device kits for use in placing, maintaining, altering, and/or removing medical devices in, on, and/or from the body of a patient are disclosed. Such medical device kits can include one or more wrap assemblies for use in the placement/maintenance procedure. In accordance with present embodiments, the one or more wrap assemblies of the medical device kit can include various features to assist the clinician performing the particular procedure. In one embodiment, a medical wrap assembly is disclosed, comprising a foldable wrap body that includes a front surface, wherein the front surface is configured to define a sterile field. A plurality of pockets is included on the front surface of the wrap body. The pockets are configured to contain therein a plurality of medical components. The medical components are arranged in the pockets in a predetermined order of use for the medical procedure.

A system for and method of shipping items is provided. The method includes adhering a package to an inner surface of a shipping case, thereby inhibiting movement of the package relative to the shipping case. The method includes wrapping one or more item with a sacrificial layer, such as shrink wrap, stretch wrap, paper, or the like, thereby creating a tight barrier of the package. The system includes one or more conveyor system and one or more adhesive applicator for automating the methods of the present invention. After adhesive is applied to at least one of a first surface of the package and the inner surface of the shipping case, the package is placed into the shipping case and the shipping case is moved to a closed configuration, thereby defining a void surrounding all but the first surface of the package.