The present disclosure relates to an improved Modular Lightweight Load-carrying Equipment (MOLLE) system that employs hard-shells and a method of making thereof. The disclosed hard-shell MOLLE system not only provides better durability for the MOLLE system, but also allows the MOLLE system to apply on hard objects such as thermoformed/molded backpacks, bags, vehicle panels and containers etc.

The present disclosure relates to an improved Modular Lightweight Load-carrying Equipment (MOLLE) system that employs hard-shells and a method of making thereof. The disclosed hard-shell MOLLE system not only provides better durability for the MOLLE system, but also allows the MOLLE system to apply on hard objects such as thermoformed/molded backpacks, bags, vehicle panels and containers etc.

Plastic grid or framework arrangements are used to support and position of bowls that hold flower arrangements, candles, letters, and other decorative elements. These grids are deployable in water fountains, indoor and outdoor pools, and other small bodies of water during festive occasions or for longer term decorative display. The grid themselves do not float, and are positioned below the surface of the water, and thus are not readily visible. Buoyancy is provided at the hubs that form nodes in the grids. The hubs also support floating bowls containing various decorative elements. The resulting effect is that the various decorative elements appear to be floating on the surface while the sub-surface grid structure maintains their relative positioning, keeping the bowls from clumping together at the edges or in the corners of the pool or fountain.

Plastic grid or framework arrangements are used to support and position of bowls that hold flower arrangements, candles, letters, and other decorative elements. These grids are deployable in water fountains, indoor and outdoor pools, and other small bodies of water during festive occasions or for longer term decorative display. The grid themselves do not float, and are positioned below the surface of the water, and thus are not readily visible. Buoyancy is provided at the hubs that form nodes in the grids. The hubs also support floating bowls containing various decorative elements. The resulting effect is that the various decorative elements appear to be floating on the surface while the sub-surface grid structure maintains their relative positioning, keeping the bowls from clumping together at the edges or in the corners of the pool or fountain.

The invention relates to a fuel tank (1) made from thermoplastic material, having a top (2) and a bottom (3), which are supported upon one another via at least one column-shaped supporting element (4), wherein the supporting element (4) is connected positively and/or materially to a wall (6) of the top (2), on the one hand, and to a wall (6) of the bottom (3), on the other hand, in such a way that it can absorb tensile forces caused by a pressure within the tank, wherein the supporting element (4) is designed as a one-piece solid profile which has a ribbed profile, at least in cross section.

The invention relates to a fuel tank (1) made from thermoplastic material, having a top (2) and a bottom (3), which are supported upon one another via at least one column-shaped supporting element (4), wherein the supporting element (4) is connected positively and/or materially to a wall (6) of the top (2), on the one hand, and to a wall (6) of the bottom (3), on the other hand, in such a way that it can absorb tensile forces caused by a pressure within the tank, wherein the supporting element (4) is designed as a one-piece solid profile which has a ribbed profile, at least in cross section.

The present invention provides a multilayer label having good gas barrier properties and is capable of maintaining the gas barrier properties at a high level even when exposed to physical stresses such as deformation and impart. The present invention relates to a multilayer label for in-mold labeling. This multilayer label includes a base (X), a layer (Z) containing an aluminum atom, and a layer (Y) containing a polymer (A) having a functional group containing a phosphorus atom.

A wall-mountable material dispensing system includes a material dispenser having a back wall, a bottom surface, a first element of an engagement component, and a self-alignment receiver, and a mounting bracket. The mounting bracket includes a baseplate having a generally planar wall-facing surface and an opposite outward-facing surface, a self-alignment protrusion extending from the outward-facing surface, wherein the self-alignment receiver is sized to at least partially receive the self-alignment protrusion. The mounting bracket also includes a second element of the engagement component configured to engage with the first element of the engagement component, wherein the second element of the engagement component is disposed on or in the outward-facing surface, a support member extending from or adjacent to the outward-facing surface, and a wall-mounting mechanism disposed on or adjacent to the wall-facing surface.

A wall-mountable material dispensing system includes a material dispenser having a back wall, a bottom surface, a first element of an engagement component, and a self-alignment receiver, and a mounting bracket. The mounting bracket includes a baseplate having a generally planar wall-facing surface and an opposite outward-facing surface, a self-alignment protrusion extending from the outward-facing surface, wherein the self-alignment receiver is sized to at least partially receive the self-alignment protrusion. The mounting bracket also includes a second element of the engagement component configured to engage with the first element of the engagement component, wherein the second element of the engagement component is disposed on or in the outward-facing surface, a support member extending from or adjacent to the outward-facing surface, and a wall-mounting mechanism disposed on or adjacent to the wall-facing surface.

Package block (3, 5) consisting of individual packages (1, 2) that are mechanically coupled together and can be separated from one another by a shear force acting along the respective parting joint (11) and can be sealed medically tight at least in the vicinity of their container openings (14) by a continuous label strip (17), wherein the continuous label strip (17) consists of individual labels (18-20) connected to one another across parting edges (32), and that the parting edges (32) are aligned with the parting joints (11) between the individual packages (1, 2).