A pulley assembly includes an elongate pulley hanger, supported at the upper end of a pillar rising from and dependently supported by a base bracket, and first and second pulleys slidingly supported by the pulley hanger. The base bracket securely mounts the pulley assembly to the top of a liquid storage tank. Each provided pulley implements, or is otherwise provided with, a clamp, whereby each pulley is readily positioned along the pulley hanger, and, when in a desired position, easily and securely fixed in the desired position.

Provided are a robot that calculates a level of liquid contained in a liquid container and a method for calculating such liquid level. The robot includes a robot arm to which a tool is attached to an end of the robot arm, a torque sensor disposed on the robot arm and measuring a torque value of the robot arm, and a processor that controls the robot arm and receives the torque value from the torque sensor and calculates information related to the torque value, and calculates the level value of liquid contained in the liquid container based on the information related to the torque value.

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 float assembly comprising a float traveling along a rod until making contact with either an upper or a lower adjustable stopper, so that an actuator lever having one or more counterweights in mechanical coupling with a switch, so that the float assembly may respond to the fluid level.

The disclosure generally describes computer-implemented methods, software, and systems for gauging tanks. A computer-implemented method includes generating, using an interrogator, a radio frequency signal directed towards a radio frequency identification (RFID) device that is freely floating on the liquid stored within the tank, receiving a return signal from the RFID device, the return signal being associated to a location of the RFID device, processing the return signal to determine a height of the liquid stored within the tank based on a triangulation algorithm, and determining a result data based on the height of the liquid stored within the tank and one or more tank characteristics.

A wireless pit meter (WPM) transmitter unit comprises a complete wireless system for reading and transmitting water meter data, wherein the water meter may be submersed in water. In order to lower installation costs and to improve system reliability, a buoy transmitter is used within a water meter vault such that varying levels of water do not degrade radio signal propagation. A wire may be attached to a submerged water meter sending data to a disclosed buoy. The buoy has an antenna to transmit data to the underside of a pit lid repeater PLR, the PLR having an underside within the water meter pit and a top side reaching the outside of the water pit lid. The top side of the PLR comprises a spiral antenna capable of transmitting or repeating the water meter data to a distant receiver with the receiver in communication with a billing system.

A wireless pit meter (WPM) transmitter unit comprises a complete wireless system for reading and transmitting water meter data, wherein the water meter may be submersed in water. In order to lower installation costs and to improve system reliability, a buoy transmitter is used within a water meter vault such that varying levels of water do not degrade radio signal propagation. A wire may be attached to a submerged water meter sending data to a disclosed buoy. The buoy has an antenna to transmit data to the underside of a pit lid repeater PLR, the PLR having an underside within the water meter pit and a top side reaching the outside of the water pit lid. The top side of the PLR comprises a spiral antenna capable of transmitting or repeating the water meter data to a distant receiver with the receiver in communication with a billing system.

The present invention provides a system for approximating the contents of a dispensing container, the system comprising: a dispensing container comprising a vessel, the vessel having: a formation and/or a discreet element in or on the vessel which causes the centre of gravity of liquid contents of the vessel to be positioned differently, when oriented in a lain-on side attitude, from its notional position, in the absence of the formation and/or discreet element, and an indicator configured to indicate a change of the liquid contents of the vessel; a gauge, separate to the dispensing container, configured to be co-operable with the indicator of the dispensing container, the gauge comprising an interface between the gauge and the dispensing container and a scale which, in co-operation with the indicator of the dispensing container, signifies to a user the approximate liquid contents of the vessel.

A method and device are disclosed for fuel-detection by a fuel sending unit by placing a fuel sending unit in a first position from a second position, and releasing the fuel sending unit from the first position such that a buoyancy characteristic of a fuel sending unit float prompts the fuel sending unit to the second position. A rate-of-travel of the fuel sending unit is sensed from the first position to the second position to produce fluid travel data, wherein the rate-of-travel being affected by a fuel density. Fluid-type identification data may be generated based on the fluid travel data.

A method and device are disclosed for fuel-detection by a fuel sending unit by placing a fuel sending unit in a first position from a second position, and releasing the fuel sending unit from the first position such that a buoyancy characteristic of a fuel sending unit float prompts the fuel sending unit to the second position. A rate-of-travel of the fuel sending unit is sensed from the first position to the second position to produce fluid travel data, wherein the rate-of-travel being affected by a fuel density. Fluid-type identification data may be generated based on the fluid travel data.