A method for treating surfaces of equipment comprising applying a Self Assembled Monolayer of a moiety to at least one surface of the equipment, wherein the equipment is selected from the group consisting of level sensors, sucker rods, turbine meters, Coriolis meters, magnetic flow meters, down hole pumps, check valves, valves, cables, drill bits, wire lines, and pigs, and the moiety may be present in mono, di or tri headed form or as a bis, gem-bis or tris headed form, and is selected from the group consisting of thiols, amines, silanes, siloxanes, selenides, tellurides, isocyanides, or heterocycles, and equipment having at least one surface comprising such a treated surface.

A method for treating surfaces of equipment comprising applying a Self Assembled Monolayer of a moiety to at least one surface of the equipment, wherein the equipment is selected from the group consisting of level sensors, sucker rods, turbine meters, Coriolis meters, magnetic flow meters, down hole pumps, check valves, valves, cables, drill bits, wire lines, and pigs, and the moiety may be present in mono, di or tri headed form or as a bis, gem-bis or tris headed form, and is selected from the group consisting of thiols, amines, silanes, siloxanes, selenides, tellurides, isocyanides, or heterocycles, and equipment having at least one surface comprising such a treated surface.

An invertible optical float switch is provided, comprising a floatable housing having an interior, a central longitudinal axis, a top end and a bottom end; first and second optical fibers each having proximal and distal ends, the proximal end of the first optical fiber connectable to a light source located remote from the housing, the proximal end of the second optical fiber connectable to a light detector located remote from the housing, the distal ends of the first and optical fibers positioned in the interior of the housing and the distal ends being mounted in the interior on a separator assembly such that the distal ends are optically aligned and separated by a gap; the separator assembly further including a movable member, the movable member adapted to be movable by gravity between a first position where the movable member occupies the gap such that the distal ends are no longer optically aligned, and a second position where the movable member does not occupy the gap; wherein the distal ends and the separator assembly are mounted on a paddle positioned in the interior of the floatable housing, the paddle adapted to be mounted either in position A with the gap closer to the top end of the floatable housing than the bottom end of the floatable housing, or in an inverted position B with the gap closer to the bottom end of the floatable housing than in position A.

An invertible optical float switch is provided, comprising a floatable housing having an interior, a central longitudinal axis, a top end and a bottom end; first and second optical fibers each having proximal and distal ends, the proximal end of the first optical fiber connectable to a light source located remote from the housing, the proximal end of the second optical fiber connectable to a light detector located remote from the housing, the distal ends of the first and optical fibers positioned in the interior of the housing and the distal ends being mounted in the interior on a separator assembly such that the distal ends are optically aligned and separated by a gap; the separator assembly further including a movable member, the movable member adapted to be movable by gravity between a first position where the movable member occupies the gap such that the distal ends are no longer optically aligned, and a second position where the movable member does not occupy the gap; wherein the distal ends and the separator assembly are mounted on a paddle positioned in the interior of the floatable housing, the paddle adapted to be mounted either in position A with the gap closer to the top end of the floatable housing than the bottom end of the floatable housing, or in an inverted position B with the gap closer to the bottom end of the floatable housing than in position A.

A method for treating surfaces of equipment comprising applying a Self Assembled Monolayer of a moiety to at least one surface of the equipment, wherein the equipment is selected from the group consisting of level sensors, sucker rods, turbine meters, Coriolis meters, magnetic flow meters, down hole pumps, check valves, valves, cables, drill bits, wire lines, and pigs, and the moiety may be present in di or tri headed form or as a bis, gem-bis or tris headed form, and is a phosphonate, and equipment having at least one surface comprising such a treated surface.

A method for treating surfaces of equipment comprising applying a Self Assembled Monolayer of a moiety to at least one surface of the equipment, wherein the equipment is selected from the group consisting of level sensors, sucker rods, turbine meters, Coriolis meters, magnetic flow meters, down hole pumps, check valves, valves, cables, drill bits, wire lines, and pigs, and the moiety may be present in di or tri headed form or as a bis, gem-bis or tris headed form, and is a phosphonate, and equipment having at least one surface comprising such a treated surface.

A liquid level sensor includes a base member disposed above the liquid. A lever arm is pivotally attached to the base member. The lever arm is configured to interact with the liquid so that it has an angular displacement relative to the base member. The angular displacement is a function of the level of the liquid in the liquid channel. A sensor senses angular displacement of the lever arm. A communications circuit transmits the angular displacement of the lever arm to a remote location. In a method of detecting a liquid level, a float that is buoyant in the liquid is placed into the liquid and is coupled to a lever arm. An angular displacement of the lever arm relative to a base member is measured. The liquid level is a function of the angular displacement of the lever arm.

A liquid level sensor includes a base member disposed above the liquid. A lever arm is pivotally attached to the base member. The lever arm is configured to interact with the liquid so that it has an angular displacement relative to the base member. The angular displacement is a function of the level of the liquid in the liquid channel. A sensor senses angular displacement of the lever arm. A communications circuit transmits the angular displacement of the lever arm to a remote location. In a method of detecting a liquid level, a float that is buoyant in the liquid is placed into the liquid and is coupled to a lever arm. An angular displacement of the lever arm relative to a base member is measured. The liquid level is a function of the angular displacement of the lever arm.

Disclosed is a ball float type liquidometer with moving indicator, comprising a ball float chamber and a ferromagnetic spherical ball float provided therein, a moving indicator outside the ball float chamber, a calibrated scale and a moving indicator guide rail, wherein the moving indicator comprises a magnetic steel member, a frame and a rolling system which is horizontally fixed and sheathed in the frame; the rolling system comprises rolling wheels provided with radial grooves along a circumferential surface, rolling bearings and shafts; the magnetic steel member is located between the ball float chamber and the frame and is fixed outside one side face close to the ball float chamber on the frame, and a magnetic pole of the magnetic steel member is directly oriented towards the ball float.

Disclosed is a ball float type liquidometer with moving indicator, comprising a ball float chamber and a ferromagnetic spherical ball float provided therein, a moving indicator outside the ball float chamber, a calibrated scale and a moving indicator guide rail, wherein the moving indicator comprises a magnetic steel member, a frame and a rolling system which is horizontally fixed and sheathed in the frame; the rolling system comprises rolling wheels provided with radial grooves along a circumferential surface, rolling bearings and shafts; the magnetic steel member is located between the ball float chamber and the frame and is fixed outside one side face close to the ball float chamber on the frame, and a magnetic pole of the magnetic steel member is directly oriented towards the ball float.