A method for predicting a dissolved oxygen level in treated seawater includes directing raw seawater from a fluid channel into a deaerator, directing an inert gas and an oxygen scavenger solution into the deaerator, thereby removing dissolved oxygen from the raw seawater such that treated seawater exits the deaerator, receiving information about a plurality of input parameters comprising a raw seawater flow rate, an inert gas flow rate, and an oxygen scavenger flow rate, implementing a neural network trained to predict the dissolved oxygen level of the treated seawater based on the plurality of input parameters and predicting, with the neural network, the dissolved oxygen level of the treated seawater based on the plurality of input parameters.

A sensor having a sensor head including a unibody construction, a first electrode, and at least one second electrode is provided. The first electrode can include a first pair of sensing elements coupled to each over via at least one bridge element extending from a first sensing element to a second sensing element. The at least one second electrode can include a second pair of sensing elements interleaved with the first pair of sensing elements. The second pair of sensing elements can be coupled to each other via at least one second bridge element extending from a third sensing element to a fourth sensing element. A method of manufacturing the sensor is also provided.

A remote hydraulic and water quality monitoring and telemetry device for being connected to a fire hydrant. The device connects to a hydrant nozzle via a swivel connection and includes a control valve mounted inside the nozzle to conserve space and release a determined volume of water from the hydrant lateral pipe to provide a sample from the main line pipe. The device includes a multi-parameter water quality sonde or sensors, data acquisition, and telemetry hardware. The door of the enclosure may include a solar panel. The device may rest on a plate mounted to the hydrant riser flange after the hydrant and upper hydrant valve stem are removed. The device may rest on the ground and be connected to a hydrant nozzle by a rotating pipe assembly which can be adjusted to be positioned at locations around the hydrant and at varying elevations relative to the hydrant nozzle.

A method for the quantitative and/or qualitative detection of particles in fluid, with which the fluid to be examined is introduced into a beam path of an optical device, between at least one light source and the image acquisition sensor with a matrix of light-sensitive cells. Pixel values of the cells are detected and the distribution of the pixel values is at least partly determined. The pixel value or values which have been determined most often are used as a value or average value for a background signal. A signal is outputted or the method is interrupted, on reaching a maximal permissible value for the background signal.

A sensor having a sensor head including a unibody construction, a first electrode, and at least one second electrode is provided. The first electrode can include a first pair of sensing elements coupled to each over via at least one bridge element extending from a first sensing element to a second sensing element. The at least one second electrode can include a second pair of sensing elements interleaved with the first pair of sensing elements. The second pair of sensing elements can be coupled to each other via at least one second bridge element extending from a third sensing element to a fourth sensing element. A method of manufacturing the sensor is also provided.

Methods, systems and apparatuses using: (i) a flow control unit including: piping inlets and outlets for connecting thereby to different parts located at different locations of a water facility (WF) and of the apparatuses themselves and multiple controllable valves, each being deployed at a different inlet or outlet of the multiple piping inlets and outlets; (ii) a detection unit including at least one sensor for sensing characteristics of the WF in various locations and/or states of the WF; and a controller, configured to control operation of the valves, for measuring one or more characteristics of a selected detection location or state of the WF or of water manipulated within the apparatuses. The methods, systems and apparatuses may further be configured to apply manipulations over a water sample, sampled from the WF and/or over water from the WF and measure responses to the applied manipulation(s).

The present disclosure relates to an apparatus or methodology for detecting one or more contaminants and/or measuring watering quality in a water supply system, which may be installed at any place chosen by a user so as to detect the one or more contaminants and/or measure the quality of water flowing through a pipe of the water supply system, such as tap water, water purifier, drinking water storage facility, or water intake facility. The present disclosure provides numerous benefits over the existing technology including convenience of handling with ease and safe fastening and installment of the apparatus for detecting one or more contaminants and/or measuring quality of water. Furthermore, the present technology enables the monitoring of the contamination level of the water delivered in the water supply system at any time chosen by the user because the contamination can be detected and/or the water quality can be measured and monitored in a wireless environment either continuously or intermittently through a wireless communication system with a remote user device.

Apparatus derives a sample liquid property and has a container with an outlet section having an overflow edge at a horizontal sample surface. A light source above the surface generates a probe light beam at a non-zero angle β1 to a normal to the surface. A detector above the surface detects intensity of light emitted out through the surface along a first detection axis forming a non-zero angle γ1 with the surface. An optical barrier between the probe light beam and the first detection axis blocks reflected or scattered light. An inlet section receives sample liquid and has an opening to the main section beneath the sample surface. A separating member separates the sample surface of the inlet section from the sample surface of the main section.

An electrode cleaning and calibration system generally comprises a sensor holder assembly machined from a block of solid acrylic or similar plastic material, which can accommodate a variety of types and sizes of sensors for use in monitoring and measurement of water processing and treatment processes. Examples of sensors suitable for use in the system include pH sensors, dissolved oxygen sensors, chlorine sensors, ozone sensors, total suspended solid sensors, mixed liquor suspended solid sensors, ammonia sensors, monochloramine sensors, and ultraviolent transmittance sensors.

Disclosed is a device for measuring at least one physical, chemical or biological parameter of a fluid, flowing in a pipe belonging to a fluid-distribution network, the device being installed in a cut on the pipe at the fluid delivery point, the pipe thus including a first section and a second section, the device including at least one sensor provided with a measurement end. The device also includes: a body including an opening forming a flow line, and at least one insertion recess capable of receiving the measurement end of the at least one sensor, the insertion recess opening into the flow line; an attachment unit arranged to connect a first end of the flow line with an end of the first section and a second end of the flow line with an end of the second section, to allow the fluid to flow through the flow line.