A sealed cooling system includes a coolant tank having a liquid space configured to hold liquid coolant, and a gas space configured to hold gas. A temperature sensor detects the temperature of the liquid coolant. A pressure sensor detects the pressure in the coolant tank. A processor compares the pressure in the coolant tank to predicted pressure in the coolant tank as a function of liquid coolant temperature. The processor determines and outputs a signal indicative of a leak in the sealed cooling system if the pressure in the coolant tank deviates from the predicted pressure in the coolant tank according to predetermined criteria.

A method for testing for a possible water leak in at least a part of a water system, comprising: closing all known water usage taps (42) within the part of the water system to be tested; closing at least one stop cock (14) or valve of the water system to isolate the part of the water system from its replacement water source (12) (or sources), and any external replacement pressure source (or sources); and then a) detecting a first pressure P0 within the isolated part of the water system at a sensor (62, 48) connected to the part of the water system, waiting a period of time t and then detecting a second pressure within the isolated part of the water system at that sensor (62, 48); and b) releasing a volume of water VR from the water system out of the isolated part of the water system via a vent (42) in the isolated part of the water system, before then closing the vent (42), step b) further comprising detecting the pressures either side of that release at that sensor (62, 48); using the pressure drop caused by the approximately known or measured volume of water VR to enable an estimate of the relationship between change in pressure in the system and the volume of water released to be established, and based on the relationship between the change in pressure and the known release volume, calculating an estimate of the actual volume of the unknown water loss volume V.sub.L based upon the recorded pressure loss in the system in the known period of time t.

A system for heat exchange and leak detection is generally provided, the system including a heat exchanger including a first wall defining a first passage containing a first fluid. A leak detection enclosure containing a leak detection medium is defined between the first wall and a second wall surrounding the first wall.

A system for heat exchange and leak detection is generally provided, the system including a heat exchanger including a first wall defining a first passage containing a first fluid. A leak detection enclosure containing a leak detection medium is defined between the first wall and a second wall surrounding the first wall.

A sealed cooling system includes a coolant tank having a liquid space configured to hold liquid coolant, and a gas space configured to hold gas. A temperature sensor detects the temperature of the liquid coolant. A pressure sensor detects the pressure in the coolant tank. A processor compares the pressure in the coolant tank to predicted pressure in the coolant tank as a function of liquid coolant temperature. The processor determines and outputs a signal indicative of a leak in the sealed cooling system if the pressure in the coolant tank deviates from the predicted pressure in the coolant tank according to predetermined criteria.

A heat exchanger apparatus has a heating stage with a product side and a hot water side and a cooling stage with a product side and a coolant side, and also regeneration stages with treated and un-treated product sides. There are valves including a cooling stage outlet valve, and pressure sensors, and pumps for pumping process liquid through the product sides. A PLC controller is programmed to operate the pumps with outlet valves closed to pressurize the product sides of the stages at a pressure dynamically maintained by control of the pumps in response to sensed pressure. The valves are controlled to firstly vent the heating and cooling sides of the heating and cooling stages with the product sides pressurized, and then in a second phase to vent the downstream (treated) product sides of regeneration stages. Also, an in-line holding time test is performed by monitoring time for step rises in temperature to reach a temperature sensor and the outlet end of a holding tube.

The respirator fit monitor described herein can be worn continuously by users so as to provide an indication as to how well their masks are fitting during use, thereby providing quantitative, wearable fit testers available for continuous use in real-life situations. The monitor includes a low-cost optical particle sensor assembly and controller unit for performing mask fit tests by comparing particle concentrations inside and outside of the mask. The fit test monitor is low cost and wearable, capable of dual sampling, capable of fit factor ratios well above 100, is battery powered and provides near real time measurements with a means for indicating the fit of the mask. The system includes wired or wireless communications for data logging, analysis and display capabilities.

A method for testing for a possible water leak in at least a part of a water system, comprising: closing all known water usage taps (42) within the part of the water system to be tested; closing at least one stop cock (14) or valve of the water system to isolate the part of the water system from its replacement water source (12) (or sources), and any external replacement pressure source (or sources); and then a) detecting a first pressure PO within the isolated part of the water system at a sensor (62, 48) connected to the part of the water system, waiting a period of time t and then detecting a second pressure within the isolated part of the water system at that sensor (62, 48); and b) releasing a volume of water VR from the water system out of the isolated part of the water system via a vent (42) in the isolated part of the water system, before then closing the vent (42), step b) further comprising detecting the pressures either side of that release at that sensor (62, 48); using the pressure drop caused by the approximately known or measured volume of water VR to enable an estimate of the relationship between change in pressure in the system and the volume of water released to be established, and based on the relationship between the change in pressure and the known release volume, calculating an estimate of the actual volume of the unknown water loss volume V.sub.L based upon the recorded pressure loss in the system in the known period of time t.

An endoscope leak test connector includes: a rotating body configured to cause a ventilation member to project from a leak test pipe sleeve by rotating in a positive direction and cause the ventilation member to be buried into the leak test pipe sleeve by rotating in a negative direction; a gas inlet configured to be connected with a gas supply source; a facing member configured to face the ventilation member projecting from the leak test pipe sleeve; a gas outlet that is open on the facing member; and a seal portion configured to seal the gas outlet and the ventilation member so that the gas outlet and the ventilation member liquid-tightly communicate with each other.

A transformer system includes a transformer and a transformer tank housing the transformer in a bath of a coolant; and a plurality of radiator systems operative to transfer heat from the coolant, each radiator system being in fluid communication with the transformer tank. The transformer system also includes means for determining an occurrence of a potential coolant leak in one or more radiator system of the plurality of radiator systems; and means for isolating only radiator systems of the plurality of radiator systems that are leaking, in response to a determination of the occurrence of the potential coolant leak.