Moisture sensor

Abstract

A novel and useful sensor and sensing system employs a transmission electrode which provides a length of transmission electrode that is greater than the physical length of the sensor, allowing for the effective and accurate determination of the moisture content of a volume of material using high-frequency measurement methods. The construction of the sensor allows the sensor to be directly inserted into the material, without requiring excavation or backfilling of the sensors in the material. The sensor can be employed as part of a sensing system, with one or more sensors preferably being managed by a field node, which in turn, interoperates with a system master node.

Description

FIELD OF THE INVENTION[0001]The present invention relates to a sensor. More specifically, the present invention relates to a sensor for determining at least the moisture content of soil or other materials in which the sensor is located.BACKGROUND OF THE INVENTION[0002]With the increase in the expenses associated with irrigation, especially in the cost of obtaining and supplying irrigation water to commercial crops, determining the moisture content of soil has become increasingly important. Various methods are known for determining the amount of moisture present in soil and such systems can include conductivity sensors and time domain transmissiometry (TDT) sensors amongst others.[0003]Conductivity sensors suffer from a lack of precision / sensitivity in their measurements, they must be in electrical contact with the soil and they are not well suited to measuring low levels of moisture and thus they are not generally an acceptable solution.[0004]TDT sensors are better able to accuratel...

AI Technical Summary

Benefits of technology

"The present invention provides a novel sensor for measuring moisture content in a volume of material surrounding the sensor. The sensor includes a composite electrode that is longer than the overall length of the sensor, allowing for accurate determination of moisture content in the material adjacent the sensor using high-frequency measurement methods. The sensor can be directly inserted into the material without requiring excavation or backfilling, and a sensing system including one or more sensors can be managed by a field node that interoperates with a system master node. The technical effects of the invention include improved accuracy and efficiency in measuring moisture content in materials, and a simplified installation process."

Problems solved by technology

Conductivity sensors suffer from a lack of precision / sensitivity in their measurements, they must be in electrical contact with the soil and they are not well suited to measuring low levels of moisture and thus they are not generally an acceptable solution.

TDT sensors are better able to accurately measure low moisture levels but, as the sensors must have relatively long sensor transmission lines / electrodes to produce accurate results, such sensors can be difficult to place in the soil.

The need to excavate and backfill the soil increases the costs of installing TDT sensors and also results in the soil surrounding the sensor having different characteristics, i.e.—density, etc. than the bulk of the soil.

Such different soil characteristics surrounding the sensors can result in less correct readings of soil characteristics.

Further, due to the need for long sensor transmission electrodes, TDT sensors provide measurements over a relatively large volume of soil provide which may be undesired in some circumstances.

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