A system for compressing and packing pipe insulation includes a compression member that is movable along a first axis to compress pieces of pipe insulation. A stacking bay includes opposing walls that are spaced apart from one another. At least one of the two opposing walls is movable relative to the other of the two opposing walls along a second axis to adjust a lateral distance between the opposing walls to accommodate an increasing size of the pieces of pipe insulation along the second axis. The first axis is generally orthogonal to the second axis. A packing member that applies a force along a third axis to the pieces of pipe insulation after being compressed. The third axis is generally orthogonal to the first and second axes. The first axis is generally orthogonal to the second axis. The compression member is aligned with a space formed between the opposing walls.

A recycling appliance is for processing non-organic recyclable materials and organic materials. The recycling appliance includes a non-organic processing assembly configured to receive, process and store the non-organic recyclable materials. An organic processing assembly is spaced apart from the non-organic processing assembly. The organic processing assembly is configured to receive, process and store the organic materials. A housing assembly is configured to house the non-organic processing assembly and the organic processing assembly.

A recycling appliance is for processing non-organic recyclable materials and organic materials. The recycling appliance includes a non-organic processing assembly configured to receive, process and store the non-organic recyclable materials. An organic processing assembly is spaced apart from the non-organic processing assembly. The organic processing assembly is configured to receive, process and store the organic materials. A housing assembly is configured to house the non-organic processing assembly and the organic processing assembly.

The disclosure relates to a pressurized Metered Dose Inhaler-compatible tablet, i.e. one that is able to be dispersed or disintegrates within a liquid phase propellant, which is used in a pressurized Metered Dose Inhaler formulation containing at least one active pharmaceutical ingredient and one or more excipients.

The disclosure relates to a pressurized Metered Dose Inhaler-compatible tablet, i.e. one that is able to be dispersed or disintegrates within a liquid phase propellant, which is used in a pressurized Metered Dose Inhaler formulation containing at least one active pharmaceutical ingredient and one or more excipients.

Compressible mattress assembly packages and processes for packaging a compressible mattress assembly for a bed in a box application generally include the addition of a humidifying agent within the package. The humidifying agent provides moisture within the package, which allows the compressed mattress to effectively recover to its uncompressed state when unpackaged with minimal or no defects.

Compressible mattress assembly packages and processes for packaging a compressible mattress assembly for a bed in a box application generally include the addition of a humidifying agent within the package. The humidifying agent provides moisture within the package, which allows the compressed mattress to effectively recover to its uncompressed state when unpackaged with minimal or no defects.

A compressed coreless rolled product is described, including an inner surface defining a central cavity having an inner diameter and an outer surface having an outer diameter larger than the inner diameter. The outer diameter is at least five inches and a ratio of the inner diameter to the outer diameter is at least 0.35. Also described is a compressed coreless rolled product with similar inner and outer surfaces, wherein: a difference between the outer diameter and the inner diameter defining a thickness of at least 2.9 inches; and a ratio of the inner diameter to the outer diameter is at least 0.35. An associated method of producing the product is also described, including steps of: winding an absorbent sheet around a forming core member; removing the forming core member to form a coreless rolled product with a diameter ratio of at least 0.35; and compressing the product.

Apparatus (1) and method for packaging flowable materials such as fluids and bulk goods (4) into flexible empty open-mouth bags (3) comprising a stationary part (5) and a movable part (6) wherein the movable part (6) is provided with multiple filling stations (11-18) traveling along. Each filling station (11-18) has a retaining device (20) fastened to the movable part (6). A plurality of handling stations (41-48) are received and distributed at the stationary part (5). A handling station (41) is configured as a takeover station to take over empty open-mouth bags (3) and a handling station (42) is configured for filling a bag (3). One handling station (44) is provided with a weighing unit (7). A bag receiving unit (10) is fastened to each of the retaining devices (20) to receive a bag (3), the bag receiving unit (10) being configured to receive and guide the bag (3). The bag receiving unit (10) at the handling station (44) equipped with a weighing unit (7) can be temporarily decoupled from force transmission to the retaining device (20) to enable separate weighing of the bag receiving unit (10) with the bag (3).

Apparatus (1) and method for packaging flowable materials such as fluids and bulk goods (4) into flexible empty open-mouth bags (3) comprising a stationary part (5) and a movable part (6) wherein the movable part (6) is provided with multiple filling stations (11-18) traveling along. Each filling station (11-18) has a retaining device (20) fastened to the movable part (6). A plurality of handling stations (41-48) are received and distributed at the stationary part (5). A handling station (41) is configured as a takeover station to take over empty open-mouth bags (3) and a handling station (42) is configured for filling a bag (3). One handling station (44) is provided with a weighing unit (7). A bag receiving unit (10) is fastened to each of the retaining devices (20) to receive a bag (3), the bag receiving unit (10) being configured to receive and guide the bag (3). The bag receiving unit (10) at the handling station (44) equipped with a weighing unit (7) can be temporarily decoupled from force transmission to the retaining device (20) to enable separate weighing of the bag receiving unit (10) with the bag (3).