A mounting bracket for a hydrant that is fully concealed by the hydrant head. The mounting bracket is fastened to the structure and includes tabs which engage the hydrant head to tightly secure the hydrant to the structure. The hydrant head includes a structure engaging periphery such that the mounting screws are fully concealed and protected from the environment.

An isolation element for a riser clamp has two opposed clamp halves made of metal strip. Each of said clamp halves has a semi-circular section placed opposite each other against a riser pipe extending through a passage hole in a floor. The clamp halves have at the ends of its semi-circular section outwardly extending clamp flanges to be tightened towards the corresponding opposing clamp flanges of the other clamp half. The riser clamp is in use supported from beneath by a support structure. The isolation element includes a profile of vibration isolating material including a pad portion, which pad portion in use is located below the corresponding clamp flange for resiliently supporting it, and further including at least one upstanding portion extending along the corresponding clamp flange, wherein said upstanding portion is attachable to the corresponding clamp flange.

A hose clamp for supporting a hose with respect to a machine. The hose clamp may include a deformable clamping element comprising a section of material at least partially surrounding an opening. The opening extends through a thickness of the clamping element and is configured to receive the hose. The hose clamp additionally comprises a support element configured to secure the clamping element to the machine. The support element is further configured to compress the clamping element along a direction of the thickness of the clamping element, thereby deforming the clamping element and causing the clamping element to constrict around the hose.

A rough-in box kit (100) for creating a rough-in box (200) to create a penetration in poured concrete flooring during the construction of concrete buildings. The rough-in box kit (100) includes a single unitary piece (1) having a flat section (5) with: a top end; a bottom end opposite to the top end; an inside surface (5a) located between the top end and the bottom end, and configured to form an inside surface of the rough in box (200); and an outside surface (5b) opposite to the inside surface (5a), and configured to form an outside surface of the rough in box (200). The single unitary piece (1) also has a top flange (3) connected to and extending away from the top end of the flat section (5), and perforations, through-holes, or slots (2) that are formed in the flat section (5). The single unitary piece (1) is configured to be bent at locations corresponding to and lining up with the perforations, through-holes, or slots (2) so as to form the rough-in box (200).

A rapid mount wall anchoring system and cable pass through for securing devices to a wall and routing device cables through a wall. The wall anchoring system includes a rigid frame with mounting fasteners for securing the frame to a wall and can be easily maneuvered between obstructions that may exist at the mounting location due to its blade like guide members and cross brace. The frame includes an opening for fitment of either a load bearing plate for securing objects to a wall or a grommet when only cable pass through is desired.

A rapid mount wall anchoring system and cable pass through for securing devices to a wall and routing device cables through a wall. The wall anchoring system includes a rigid frame with mounting fasteners for securing the frame to a wall and can be easily maneuvered between obstructions that may exist at the mounting location due to its blade like guide members and cross brace. The frame includes an opening for fitment of either a load bearing plate for securing objects to a wall or a grommet when only cable pass through is desired.

A protection device for preventing damage to an elongate flexible member passing through an aperture including a body portion adapted to be inserted into the aperture in a first direction and having an internal passageway for allowing movement of an elongate flexible member therethrough, and at least one latching element pivotally mounted on the body portion. The protection device can be used for protecting an elongate flexible member passing through an aperture in a support pillar of an offshore turbine generator. A method of removing the protection device from an aperture is also disclosed.

A protection device for preventing damage to an elongate flexible member passing through an aperture including a body portion adapted to be inserted into the aperture in a first direction and having an internal passageway for allowing movement of an elongate flexible member therethrough, and at least one latching element pivotally mounted on the body portion. The protection device can be used for protecting an elongate flexible member passing through an aperture in a support pillar of an offshore turbine generator. A method of removing the protection device from an aperture is also disclosed.

The present disclosure relates to inserts for use with sandwich panels, such as composite panels, and related methods. Presently disclosed inserts may include a retention feature and/or an anti-rotation feature that may be configured to retain the insert in place within a bore formed in the sandwich panel. In this manner, presently disclosed inserts may be secured without the use of adhesive compounds, which may increase efficiency and/or reduce costs in manufacturing apparatus that include one or more sandwich panels having one or more inserts placed therein. Presently disclosed methods of installing an insert into a sandwich panel may include rotating the insert with respect to the sandwich panel as the insert is installed, such that a portion of the insert may be positioned under the skin of the sandwich panel (e.g., a portion of the insert may be positioned between the skin and the core of the sandwich panel).

The present disclosure relates to inserts for use with sandwich panels, such as composite panels, and related methods. Presently disclosed inserts may include a retention feature and/or an anti-rotation feature that may be configured to retain the insert in place within a bore formed in the sandwich panel. In this manner, presently disclosed inserts may be secured without the use of adhesive compounds, which may increase efficiency and/or reduce costs in manufacturing apparatus that include one or more sandwich panels having one or more inserts placed therein. Presently disclosed methods of installing an insert into a sandwich panel may include rotating the insert with respect to the sandwich panel as the insert is installed, such that a portion of the insert may be positioned under the skin of the sandwich panel (e.g., a portion of the insert may be positioned between the skin and the core of the sandwich panel).