To provide a flood detection technique with which a breakdown is less likely to occur over a long period, maintenance costs are low, and the occurrence of an abnormal water level is less likely to be erroneously determined. An inundation detection device 1 detects a received signal strength I(t) that is the strength of a received response signal received from an RF sensor installed at a flood detection location, detects a dispersion D(I;[t−Δt.sub.1, t]), within a specific time Δt.sub.1, of I(t), detects a normal reception rate R[(t−Δt.sub.2, t]), and outputs a flood detection signal in a case where the dispersion D(I;[t−Δt.sub.1, t]) is greater than or equal to a specific threshold D.sub.th1 and the normal reception rate R[(t−Δt.sub.2, t]) is less than or equal to a specific threshold R.sub.th1. When an increase in the dispersion D(I;[t−Δt.sub.1, t]) and a decrease in the normal reception rate R[(t−Δt.sub.2, t]) are appropriately determined on the basis of the thresholds, the RF sensor that is flooded can be detected with high accuracy.

The measuring-device system comprises two measuring devices and an evaluating- and supply electronics. Each of the measuring devices has a measured variable transducer and a measurement transmitter. Each of the transducers is adapted to react to a measured variable and to provide a corresponding transducer signal. The first measurement transmitter includes an interface circuit both for wired energy supply and for wired signal transmission on a two-wire loop. The second measurement transmitter includes an interface circuit for wired energy supply and a radio unit. The evaluating- and supply electronics feeds electrical power into the two-wire loop during operation. Both measurement transmitters are adapted to draw electrical power from the electrical current loop. Additionally, the first measurement transmitter is adapted to transmit its measurement signal via the electrical current loop to the evaluating- and supply electronics.

A sensing apparatus for monitoring a substance contained in a storage building the apparatus comprising: a mounting bracket configured to be secured to a roof of the storage building; a sensing assembly mounted to the mounting bracket, the sensing assembly including: a sensor for measuring a parameter of the substance in the storage building when the sensor is in a measuring orientation; and a housing for housing the sensor, the housing being pivotably connected to the mounting bracket and being freely pivotable relative to the mounting bracket about a pivot axis, the housing being orientable in an operative position in which the sensor is in the measuring orientation to allow the sensor to measure the parameter of the substance, the sensing assembly having a center of mass located below the pivot axis such that the housing is urged towards the operative orientation by gravity.

A vehicle includes an internal combustion engine and an air induction system configured to provide intake air to the internal combustion engine. The air induction system includes an intake port, an air box coupled to the intake port and having a wet side air box and a dry side air box, at least one sensor disposed within the air box and configured to detect a presence or level of liquid within the air box, and a watertight door disposed within the air box and configured to move between an open position that allows air to pass through the air box dry side, and a closed position that facilitates preventing liquid from passing into the air box dry side.

The present disclosure relates to a method for safe and exact ascertaining of fill level of a fill substance located in a container by means of an ultrasonic, or radar-based, fill level measuring device. In such case, the method is distinguished by the feature that the evaluation curve created based on the reflected received signal is differently greatly smoothed as a function of measured distance. To achieve this, the evaluation curve can be specially filtered, depending on the application. In this way, noise fractions and disturbance echoes can be efficiently suppressed, without unnecessarily limiting the accuracy of the fill level measurement.

The innovation described herein generally pertains to a system and method related a wireless remote monitoring system for a tank, wherein the wireless monitoring system is incorporated into or coupled to a lid for the tank. The wireless remote monitoring system for the tank can include a cover system that includes a lid mountable on a corresponding tank, the lid comprising a space sized and shaped for receiving the wireless remote monitoring system therein, wherein the wireless remote monitoring system is operatively coupled to a sensor.

Devices for sealing chemical totes and wirelessly monitoring chemicals in the totes include sensors for obtaining data from within the totes and transceivers for receiving and transmitting the data. The data is received from the sensor and transmitted to a gateway transceiver located at a remote location on a low-power wide-area network. Data can be aggregated from multiple devices and relayed to a server on the network. An integrated microcontroller is programmed with instructions for coordinating communications to and from the device transceiver. Systems can include multiple containers located up to 25 miles from one another using the device. Methods including wirelessly monitoring chemicals in chemical totes are disclosed. Data obtained using the device can be used in a variety of ways.

The innovation described herein generally pertains to a system and method related a wireless remote monitoring system for a tank, wherein the wireless monitoring system is incorporated into or coupled to a lid for the tank. The wireless remote monitoring system for the tank can include a cover system that includes a lid mountable on a corresponding tank, the lid comprising a space sized and shaped for receiving the wireless remote monitoring system therein, wherein the wireless remote monitoring system is operatively coupled to a sensor.

The present application discloses a flow speed detection circuit and a related chip and flow meter. Said flow speed detection circuit is coupled to a first transducer and a second transducer that are external to the flow speed detection circuit, wherein the flow speed detection circuit includes: a transmitter, configured to provide a front signal and a main signal to the first transducer, wherein the first transducer transforms the front signal and the main signal into a transduced signal to the second transducer, the second transducer transforms the transduced signal into a receiving front signal and a receiving main signal to a receiver; and the receiver includes: a front signal detection circuit, configured to enable the main signal processing circuit after the receiving front signal; and the main signal processing circuit, configured to determine the flow speed based on the receiving main signal after being enabled.

The present application discloses a flow speed detection circuit and a related chip and flow meter. Said flow speed detection circuit is coupled to a first transducer and a second transducer that are external to the flow speed detection circuit, wherein the flow speed detection circuit includes: a transmitter, configured to provide a front signal and a main signal to the first transducer, wherein the first transducer transforms the front signal and the main signal into a transduced signal to the second transducer, the second transducer transforms the transduced signal into a receiving front signal and a receiving main signal to a receiver; and the receiver includes: a front signal detection circuit, configured to enable the main signal processing circuit after the receiving front signal; and the main signal processing circuit, configured to determine the flow speed based on the receiving main signal after being enabled.