A method and a device for detecting defects in a packaging laminate having at least one conductive layer are provided. The method comprises the steps of grounding the conductive layer of the packaging laminate, arranging an electrode adjacent to the packaging laminate, applying a high voltage to the electrode by ramping the voltage from an initial value towards an upper predetermined value, and detecting a defect in the packaging material by registering dielectric breakdown between the electrode and the conductive layer of the packaging laminate.

A water leak detection system including a leak detector and a wall bracket with an integral or removable remote probe that can be positioned remotely from the leak detector. The leak detector is configured to electrically couple with the remote probe when mechanically coupled with the wall bracket, requiring no further user interaction to activate the probe. The wall bracket can include multiple remote probes that each electrically couple with the leak detector when the leak detector is mechanically coupled to the wall bracket, any one of the remote probes capable of triggering the leak detector when a leak occurs.

A water leak detection system including a leak detector and a wall bracket with an integral or removable remote probe that can be positioned remotely from the leak detector. The leak detector is configured to electrically couple with the remote probe when mechanically coupled with the wall bracket, requiring no further user interaction to activate the probe. The wall bracket can include multiple remote probes that each electrically couple with the leak detector when the leak detector is mechanically coupled to the wall bracket, any one of the remote probes capable of triggering the leak detector when a leak occurs.

A leak detection system includes a high voltage leak detection (HVLD) testing system configured to inspect a package using a HVLD apparatus that includes an inspection electrode and a detection electrode. The leak detection system includes a grounding system that includes a grounding element. The grounding system is configured to remove, significantly reduce, or conduct away electric charge accumulation on the package. The leak detection system also includes a controller configured to operate and coordinate the operation of the grounding system with the operation of the HVLD testing system.

A leak detection system includes a high voltage leak detection (HVLD) testing system configured to inspect a package using a HVLD apparatus that includes an inspection electrode and a detection electrode. The leak detection system includes a grounding system that includes a grounding element. The grounding system is configured to remove, significantly reduce, or conduct away electric charge accumulation on the package. The leak detection system also includes a controller configured to operate and coordinate the operation of the grounding system with the operation of the HVLD testing system.

A fluid control system which encompasses a leak sensor and a fluid control unit adapted for installation on a fluid supply line, both capable of wireless data communication with a gateway acting as an interface between the leak sensor and fluid control unit and a cloud server or a remote user application.

A fluid control system which encompasses a leak sensor and a fluid control unit adapted for installation on a fluid supply line, both capable of wireless data communication with a gateway acting as an interface between the leak sensor and fluid control unit and a cloud server or a remote user application.

A system configured to detect failure of a hose includes a sensor assembly having a body with a first arm and a second arm pivotally coupled to one another at respective first ends, and the body is configured to move between a closed position and an open position. The sensor assembly also includes a first electrical contact positioned at a respective second end of the first arm and a second electrical contact position at a respective second end of the second arm. The first electrical contact and the second electrical contact are configured to contact one another to form a complete electrical circuit when the body is in the closed position and are configured to be separated from one another to form an open electrical circuit when the body is in the open position to facilitate detection of the failure of the hose.

A system configured to detect failure of a hose includes a sensor assembly having a body with a first arm and a second arm pivotally coupled to one another at respective first ends, and the body is configured to move between a closed position and an open position. The sensor assembly also includes a first electrical contact positioned at a respective second end of the first arm and a second electrical contact position at a respective second end of the second arm. The first electrical contact and the second electrical contact are configured to contact one another to form a complete electrical circuit when the body is in the closed position and are configured to be separated from one another to form an open electrical circuit when the body is in the open position to facilitate detection of the failure of the hose.

A method for determining a fluid pressure parameter related to a fluid located within a fluid conduit, the method may include measuring one or more resistances of one or more nanoparticle based sensing elements to provide sensed information; wherein the one or more nanoparticle based sensing elements comprise nanometric particles having an electrical resistance that is responsive to at least one out of pressure and temperature; wherein the one or more nanoparticle based sensing elements are printed between conductive electrodes, wherein the conductive electrodes are either printed on an exterior of the fluid conduit or are formed on a substrate that is attached to the exterior of the fluid conduit; and determining, based on the sensed information, the fluid pressure parameter.