Provided is a structure for operating a watertight door by use of buoyancy. The structure includes: a detention tank for storing rainwater flowing from a street inlet; a buoyant member which is installed in the detention tank; and a sensor installed in the detention tank, in which if the buoyant member raised by the buoyant of the rainwater collected in the detention tank comes into contact with the sensor, the watertight door is automatically operated. The watertight door structure manually operated at localized heavy rain is improved, and the watertight door is automatically operated if the water level reaches the predetermined level.

Provided is a structure for operating a watertight door by use of buoyancy. The structure includes: a detention tank for storing rainwater flowing from a street inlet; a buoyant member which is installed in the detention tank; and a sensor installed in the detention tank, in which if the buoyant member raised by the buoyant of the rainwater collected in the detention tank comes into contact with the sensor, the watertight door is automatically operated. The watertight door structure manually operated at localized heavy rain is improved, and the watertight door is automatically operated if the water level reaches the predetermined level.

A method for maintaining a boiling rate of a base fluid can include a determination of a fluid level of a turbulated base fluid in a reservoir. The fluid level can be determined by measuring at least one first height of the turbulated base fluid above the fluid level with at least a first sensor. The fluid level can be determined by measuring at least one second height of the turbulated base fluid below the fluid level with the first sensor. The method can include the establishment of the fluid level of the turbulated base fluid. The fluid level can be established according to the measured at least one first and second heights. The method can include the graduated introduction of an input fluid into the reservoir. A control valve can gradually introduce the input fluid in proportion to the established fluid level of the turbulated base fluid.

A method for maintaining a boiling rate of a base fluid can include a determination of a fluid level of a turbulated base fluid in a reservoir. The fluid level can be determined by measuring at least one first height of the turbulated base fluid above the fluid level with at least a first sensor. The fluid level can be determined by measuring at least one second height of the turbulated base fluid below the fluid level with the first sensor. The method can include the establishment of the fluid level of the turbulated base fluid. The fluid level can be established according to the measured at least one first and second heights. The method can include the graduated introduction of an input fluid into the reservoir. A control valve can gradually introduce the input fluid in proportion to the established fluid level of the turbulated base fluid.

Applicant has created systems, methods, and apparatuses for controlling the power supply of a vacuum cleaner motor. The systems and apparatuses include pressure taps to detect a pressure differential within a vacuum cleaner, a float that adjusts depending on an amount of liquid stored, and a power switch that toggles based on the pressure differential created by the position of the float. Alternatively, the float can be replaced by an air chamber so that the pressure differential is created by liquid rising above the volume of air trapped in the chamber. The method can include interrupting the current supplied to an electrical circuit of a power switch based upon a pressure differential created within the vacuum. By controlling the power supply to a vacuum cleaner motor based on a pressure differential created by the amount of liquid stored within the vacuum cleaner, the vacuum cleaner can automatically disable the vacuum cleaner's motor as the vacuum approaches its maximum liquid capacity.

Applicant has created systems, methods, and apparatuses for controlling the power supply of a vacuum cleaner motor. The systems and apparatuses include pressure taps to detect a pressure differential within a vacuum cleaner, a float that adjusts depending on an amount of liquid stored, and a power switch that toggles based on the pressure differential created by the position of the float. Alternatively, the float can be replaced by an air chamber so that the pressure differential is created by liquid rising above the volume of air trapped in the chamber. The method can include interrupting the current supplied to an electrical circuit of a power switch based upon a pressure differential created within the vacuum. By controlling the power supply to a vacuum cleaner motor based on a pressure differential created by the amount of liquid stored within the vacuum cleaner, the vacuum cleaner can automatically disable the vacuum cleaner's motor as the vacuum approaches its maximum liquid capacity.

A system for detecting water flooding in telecommunications manholes may include a float switch disposed at a predetermined flooding line in a telecommunications manhole. The float switch may be a switching device without a power source. The system may include an analog phone connected to the float switch through a telephone line connection associated with a pre-existing communication network. The analog phone may be configured for detecting a triggering signal from the float switch and initiating an alert procedure upon detecting the triggering signal.

A system for detecting water flooding in telecommunications manholes may include a float switch disposed at a predetermined flooding line in a telecommunications manhole. The float switch may be a switching device without a power source. The system may include an analog phone connected to the float switch through a telephone line connection associated with a pre-existing communication network. The analog phone may be configured for detecting a triggering signal from the float switch and initiating an alert procedure upon detecting the triggering signal.

A system for detecting water flooding in telecommunications manholes may include a float switch disposed at a predetermined flooding line in a telecommunications manhole. The float switch may be a switching device without a power source. The system may include an analog phone connected to the float switch through a telephone line connection associated with a pre-existing communication network. The analog phone may be configured for detecting a triggering signal from the float switch and initiating an alert procedure upon detecting the triggering signal.

A magnetic float switch is provided. The magnetic float switch can include a housing configured to float in a liquid, response circuitry located inside the housing, an internal chamber located inside the housing, a float state indicator housed within the internal chamber, and an actuating arm housed outside the internal chamber and coupled to the response circuitry. In operation, when a position of the housing changes so as to indicate an increasing level of the liquid, the float state indicator can move within the internal chamber from a first position to a second position to initiate a magnetic force between the float state indicator and the actuating arm so as to actuate the actuating arm from an inactive position to an active position. Then, when the actuating arm is in the active position, the response circuitry can initiate a response to the increasing level of the liquid.