The present disclosure provides shortening prevention sleeves for adjustable underground utility boxes, underground utility boxes including such sleeves, and methods of preventing shortening of underground utility boxes with such sleeves. A sleeve comprises a substantially rigid elongate tube that defines an internal cavity. The tube is configured to allow a stem portion of an adjustable underground utility box to extend fully therethrough via the internal cavity. The sleeve also comprises an opening that extends along the length of the tube and provides a passageway into the internal cavity. The tube is configured to allow the stem portion of the box to pass through the opening and into the internal cavity. The sleeve is configured to extend over and along the stem portion and between enlarged top and bottom portions of the box to prevent the stem portion, and thereby the box as a whole, from shortening.

Provided is an enclosure with an integrated hydrant. The enclosure includes a fluid flow conduit that transfers fluid from a fluid supply tube to a fluid outlet, which may be associated with the backflow preventer. The enclosure has a conduit that carries water from the fluid supply tube to the backflow preventer. Thus, a lower profile, lighter, and more aesthetically pleasing enclosure is provided.

A fire hydrant barrel includes a body having at least one wall and an anti-rotation pin opening through the at least one wall. The at least one wall defines an internal cavity. The fire hydrant barrel also includes a stem extending through the cavity of the body. The stem has an anti-rotation element, and the anti-rotation pin opening and the anti-rotation element are configured to receive an anti-rotation pin to lock the stem from rotating with respect to the body.

A wireless communication electronics storage apparatus that stores wireless communication electronics at a fire hydrant and provides access for electronic connections of the wireless communication electronics to sensors located within the fire hydrant at a main valve below ground level, and a method of mounting wireless communication electronics to a fire hydrant.

A breaker clamp member includes a curved body shaped to fit around a portion of an upper portion of a fire hydrant and a portion of a lower portion of the fire hydrant at a joint between the upper portion of the fire hydrant and the lower portion of the fire hydrant. The breaker clamp member also includes at least one connection element extending from the body to connect the breaker clamp member with at least one other breaker clamp member. The breaker clamp member also includes an upper rim protruding from the body and a lower rim protruding from the body. The upper protruding rim, the lower protruding rim, and the body define a concavity therebetween, the concavity being configured to receive the first ledge and the second ledge. In another embodiment, a breaker clamp includes two breaker clamp members.

An infrastructure monitoring assembly includes a fire hydrant; a pipe connected in fluid communication with the fire hydrant, a fluid at least partially filling the pipe; a sensor positioned in the fluid, the sensor configured to measure a parameter of the fluid; and a processor connected in communication with the sensor, the processor configured to receive a signal from the sensor.

A wireless communication electronics storage apparatus that stores wireless communication electronics at a fire hydrant and provides access for electronic connections of the wireless communication electronics to sensors located within the fire hydrant at a main valve below ground level, and a method of mounting wireless communication electronics to a fire hydrant.

HYDRANT ARMOR is an enclosure that protects fire hydrants from all weather and environmental conditions and has light reflective features incorporated on the exterior of the enclosure to ensure its visibility in darkness. When fitted with a tall reflective post, fire hydrants can be located even when they are covered in snow. Hydrant valves and hose connection caps are protected from natural elements and corrosion while they are within the hollow enclosure. The enclosure is suspended off the ground so as not to become frozen to the ground, and is held in place with an integral bracket that is attached to the hydrant. The open bottom of the enclosure fits over and locks onto the bracket and can be removed from the hydrant without tools. The conical shape of the enclosure, tapered at the bottom, will prevent the enclosure from binding in deep snow.

Provided is an enclosure with an integrated hydrant. The enclosure includes a fluid flow conduit that transfers fluid from a fluid supply tube to a fluid outlet, which may be associated with the backflow preventer. The enclosure has a conduit that carries water from the fluid supply tube to the backflow preventer. Thus, a lower profile, lighter, and more aesthetically pleasing enclosure is provided.

A hydrant includes a hydrant body defining a top end and a bottom end distal from the top end, the top end defining a barrel diameter and an opening; and a hydrant cap defining an upper surface facing away from the hydrant body and a lower surface facing toward the top end of the hydrant body, the hydrant cap defining a cap diameter, the cap diameter being greater than the barrel diameter; and a cap fastener, the hydrant cap secured to the top end of the hydrant body with the cap fastener, a portion of the cap fastener extending through the opening defined in the top end of the hydrant body.