A method according to one embodiment includes securing a first plurality of conductive sheets to a surface, applying a conductive tape to a first plurality of joints between conductive sheets of the first plurality of conductive sheets, and securing a second plurality of conductive sheets to the first plurality of conductive sheets without fully penetrating the first plurality of conductive sheets. In such an embodiment, each of a second plurality of joints between conductive sheets of the second plurality of conductive sheets is offset relative to the first plurality of joints.

A method according to one embodiment includes securing a first plurality of conductive sheets to a surface, applying a conductive tape to a first plurality of joints between conductive sheets of the first plurality of conductive sheets, and securing a second plurality of conductive sheets to the first plurality of conductive sheets without fully penetrating the first plurality of conductive sheets. In such an embodiment, each of a second plurality of joints between conductive sheets of the second plurality of conductive sheets is offset relative to the first plurality of joints.

An integrated joint sealing system that is incorporated into the edges of a sheathing panel, which also may have a factory bonded weather resistive barrier. The edges of each panel are configured as a shiplap joint, or similarly functioning joint, that is present as either an overlap or underlap on each of the four panel edges. The arrangement of the joints are such that one edge will have an overlap and the opposite edge will have an underlap. A flexible gasket material (or materials) is factory applied to one or both sides (underlap and/or overlap) of the shiplap joint. This flexible gasket material, when overlapped with adjacent shiplap panels, provides a weather resistive seal to limit both water and air penetration.

A barrier assembly used in the protection of personnel at worksites and/or residential areas from escapes of gas. Such a barrier assembly controls the lateral and vertical spread of gas in the event of an escape of the gas, even more particularly toxic gas. The barrier assembly can be used at operating sites where gases are produced, and in particular where high concentrations of toxic gases (e.g. CO2, H2S, SO2, mercaptans etc.) are present. The barrier assembly can, optionally acting as a safety system in the event of an accidental uncontrolled release of these toxic gases into the atmosphere.

An article to suppress cracking of drywall at interior corners features a thin metal brace that includes a piece of sheet metal between 3 and 30 gauge thickness. If the device as-produced or as-received starts out as a flat sheet of metal, the base or flange of the device is then bent at about a 90 degree angle with respect to the rest of the device—the tongue. When the base or flange is then placed flat along the side of a stud or framing, the tongue of the device will then lie flat or flush along the front side of the stud, but at an angle, for example, 45 degrees, with respect to the longitudinal axis of the stud. In a door or window frame, another stud will intersect the first stud at a right angle. Where the tongue crosses this second stud, the tongue may be fastened to this second stud. In another embodiment, the tongue may be bent or folded over and fastened to the side of the stud. This device can be fastened with screws, nails, or staples, as well as a pressed gang plate system. Thus, the instant device serves to tie the framing members together.

An electromagnetically insulating device includes a body material, an electrically conductive EMI attenuation layer, and a plurality of conductive elements. The body material is substantially planar and flexible. The EMI attenuation layer is positioned inside the body material. The plurality of conductive elements are positioned in the body material. The EMI attenuation layer and the plurality of conductive elements are configured to be electrically connected to an external ground connection.

A sleeping compartment with a sleeping region and an electrically conducting curtain, which can be arranged around the sleeping region, having a rail system by which the conducting curtain is mounted in a displaceable manner. The rail system includes at least one rail and a multiplicity of connecting elements, the connecting elements being connected to the conducting curtain and being mounted in the at least one rail in a displaceable manner. The rail system is configured such that the conducting curtain is connected to the at least one rail in an electrically conducting manner, preferably such that the conducting curtain is earthed by way of the rail.

A sleeping compartment with a sleeping region and an electrically conducting curtain, which can be arranged around the sleeping region, having a rail system by which the conducting curtain is mounted in a displaceable manner. The rail system includes at least one rail and a multiplicity of connecting elements, the connecting elements being connected to the conducting curtain and being mounted in the at least one rail in a displaceable manner. The rail system is configured such that the conducting curtain is connected to the at least one rail in an electrically conducting manner, preferably such that the conducting curtain is earthed by way of the rail.

A tower (1) having equipment (3) mounted thereon is disclosed. The tower (1) has an ice shield assembly (2) for protection to of the equipment (3) against falling ice mounted thereon. The ice shield assembly (2) comprises a tower fixture arrangement (5) being secured to the tower (1) and an ice shield (4) connected 5 to the tower fixture arrangement (5) via a hinge (6). The ice shield (4) is configured for vertically overlapping the horizontal extends of the equipment (3). The ice shield assembly (2) further comprises at least one spring element (7), e.g. in the form of a curved rod, connected at one end to the ice shield (4) and at an opposite end to the tower (1), the at least one spring element (7) 10 being configured to allow the ice shield (4) to pivot relative to the tower (1) at the hinge (6) in order to ensure a gradual transfer of energy from falling ice, which collides with the ice shield (4).

A tower (1) having equipment (3) mounted thereon is disclosed. The tower (1) has an ice shield assembly (2) for protection to of the equipment (3) against falling ice mounted thereon. The ice shield assembly (2) comprises a tower fixture arrangement (5) being secured to the tower (1) and an ice shield (4) connected 5 to the tower fixture arrangement (5) via a hinge (6). The ice shield (4) is configured for vertically overlapping the horizontal extends of the equipment (3). The ice shield assembly (2) further comprises at least one spring element (7), e.g. in the form of a curved rod, connected at one end to the ice shield (4) and at an opposite end to the tower (1), the at least one spring element (7) 10 being configured to allow the ice shield (4) to pivot relative to the tower (1) at the hinge (6) in order to ensure a gradual transfer of energy from falling ice, which collides with the ice shield (4).