A hydrant has a riser pipe and a shut-off element which can be brought from at least one open position into at least one closed position and vice versa. The shut-off element in the closed position seals the interior of the riser pipe from a hydrant inlet. The hydrant comprises at least one first passage, by which the interior can be fluidically connected to the outside of the hydrant, and one second passage, by which the pressurized hydrant inlet can be fluidically connected to the outside of the hydrant, wherein the first passage and the second passage can be brought into operative connection with each other. The operative connection produces a vacuum by water flowing through the second passage such that water in the interior of the riser pipe is led away via the first passage and the riser pipe is thereby drained.

A hydrant has a riser pipe and a shut-off element which can be brought from at least one open position into at least one closed position and vice versa. The shut-off element in the closed position seals the interior of the riser pipe from a hydrant inlet. The hydrant comprises at least one first passage, by which the interior can be fluidically connected to the outside of the hydrant, and one second passage, by which the pressurized hydrant inlet can be fluidically connected to the outside of the hydrant, wherein the first passage and the second passage can be brought into operative connection with each other. The operative connection produces a vacuum by water flowing through the second passage such that water in the interior of the riser pipe is led away via the first passage and the riser pipe is thereby drained.

A fire hydrant drain includes an elongated, hollow body having a first portion, a second portion, and a third portion. The first portion is configured to protrude a first length radially through an outer wall of a fire hydrant. The second portion is continuous with and between the first portion and the third portion. The second portion includes a first bend having a first curvature degree and a first curvature direction, and a second bend having a second curvature degree and a second curvature direction. The first curvature degree is larger than the second curvature degree, and a direction of the first curvature is opposite a direction of the second curvature. The first bend is between the first portion and the second bend. The third portion extends a second length, and an angle between the first length and the third length is less than 90 degrees.

A fire hydrant drain includes an elongated, hollow body having a first portion, a second portion, and a third portion. The first portion is configured to protrude a first length radially through an outer wall of a fire hydrant. The second portion is continuous with and between the first portion and the third portion. The second portion includes a first bend having a first curvature degree and a first curvature direction, and a second bend having a second curvature degree and a second curvature direction. The first curvature degree is larger than the second curvature degree, and a direction of the first curvature is opposite a direction of the second curvature. The first bend is between the first portion and the second bend. The third portion extends a second length, and an angle between the first length and the third length is less than 90 degrees.

A supply assembly for use with a hydrant comprising a first supply valve adapted for coupling to a first supply line of the hydrant and a second supply valve adapted for coupling to a second supply line of the hydrant. A housing contains a first drain valve and a second drain valve. The first supply valve is coupled to the first drain valve for permitting water to be drained from the first supply line when a first outlet of the hydrant is off, and the second supply valve is coupled to the second drain valve for permitting water to be drained from the second supply line when a second outlet of the hydrant is off. The first supply valve is above the second supply valve to permit radially compact nesting of the first supply valve and the second supply valve. Related assemblies, valves and methods are provided.

A supply assembly for use with a hydrant comprising a first supply valve adapted for coupling to a first supply line of the hydrant and a second supply valve adapted for coupling to a second supply line of the hydrant. A housing contains a first drain valve and a second drain valve. The first supply valve is coupled to the first drain valve for permitting water to be drained from the first supply line when a first outlet of the hydrant is off, and the second supply valve is coupled to the second drain valve for permitting water to be drained from the second supply line when a second outlet of the hydrant is off. The first supply valve is above the second supply valve to permit radially compact nesting of the first supply valve and the second supply valve. Related assemblies, valves and methods are provided.

A drain valve to drain water from a dry barrel hydrant includes a drain valve body fixed to a main valve assembly of the hydrant, and a hollow drain hole sleeve positioned in a drain hole of an elbow of the hydrant. The drain valve body includes a drain valve facing configured to align with the drain hole of the elbow as a result of the main valve assembly being in an open position, and to not align with the drain hole of the elbow as a result of the main valve assembly being in a closed position. In another embodiment, an elbow of a fire hydrant includes a hollow body, an upper end defining a drain hole to allow water to drain out, and a hollow drain hole sleeve in the drain hole.

A drain valve to drain water from a dry barrel hydrant includes a drain valve body fixed to a main valve assembly of the hydrant, and a hollow drain hole sleeve positioned in a drain hole of an elbow of the hydrant. The drain valve body includes a drain valve facing configured to align with the drain hole of the elbow as a result of the main valve assembly being in an open position, and to not align with the drain hole of the elbow as a result of the main valve assembly being in a closed position. In another embodiment, an elbow of a fire hydrant includes a hollow body, an upper end defining a drain hole to allow water to drain out, and a hollow drain hole sleeve in the drain hole.

An improved hydrant structure with an integral piston set is provided with the hydrant main body having a valve chamber for receiving a water control valve. The water control valve is composed of a valve member, rubber pads, a piston cylinder with an integrally enclosed structure and a piston rod disposed inside the valve member, a valve rod, a cover, a valve cap, and a rotary button; the outer side of the piston cylinder is formed with different outer diameters, and the preset portions thereof are formed with a water inlet and a water outlet holes, such that the piston rod can be adjusted to alter the relative relation, thereby achieving functions of starting/terminating water supply and adjusting water mixing ratio. The piston cylinder with an integrally enclosed structure is formed through a stainless steel base pipe and a plastic sleeve member enclosing the exterior thereof.

An improved hydrant structure with an integral piston set is provided with the hydrant main body having a valve chamber for receiving a water control valve. The water control valve is composed of a valve member, rubber pads, a piston cylinder with an integrally enclosed structure and a piston rod disposed inside the valve member, a valve rod, a cover, a valve cap, and a rotary button; the outer side of the piston cylinder is formed with different outer diameters, and the preset portions thereof are formed with a water inlet and a water outlet holes, such that the piston rod can be adjusted to alter the relative relation, thereby achieving functions of starting/terminating water supply and adjusting water mixing ratio. The piston cylinder with an integrally enclosed structure is formed through a stainless steel base pipe and a plastic sleeve member enclosing the exterior thereof.