A sensor may detect a coolant leak at or near an appliance that is slidable between a seated position and an ejected position relative to a rack. In the seated position, a coolant supply line may be coupled with a conduit of the appliance to convey coolant past the appliance. A biaser can bias the appliance toward the ejected position, and a latch may secure the appliance in a seated position against the biaser. A releaser can release the latch in response to coolant leak detection by the sensor and permit the biaser to move the appliance toward the ejected position, for example, which may cause the conduit to become disconnected from the coolant supply line to cut off flow to the leak.

According to one embodiment, a liquid cooling leakage abatement system includes a systems manager having executable instructions for obtaining location information for each of a plurality of components of a computing cluster in which at least a portion of the components are cooled by a liquid cooling system via a liquid coolant. When the systems manager receives leakage information associated with a leak in the liquid cooling system used to cool a first component, it infers a second component that is affected by the leak, and generates an alert message indicating that the first and second components that are affected by the leak.

Techniques for inducing non-uniform cooling are described. According to an embodiment, a system is provided. The system can comprise at least one processor device that executes components stored in a memory, wherein the components comprise: a flow control device that distributes coolant to a location of the at least one processor device; and a sensor controller component that detects a location of a thermal anomaly of the at least one processor device. The components can also comprise a cooling controller component that adjusts the flow control device to direct the coolant to the location of the thermal anomaly.

Methods are directed towards dynamically determining refrigerant film thickness at the rolling-element bearing and for dynamically controlling refrigerant film thickness at the rolling-element bearing. Further, an oil free chiller system is configured for dynamically determining refrigerant film thickness at the rolling-element bearing of the oil free chiller system, wherein the oil free chiller system is also configured for dynamically controlling refrigerant film thickness at the rolling-element bearing of the oil free chiller system.

Methods are directed towards dynamically determining refrigerant film thickness at the rolling-element bearing and for dynamically controlling refrigerant film thickness at the rolling-element bearing. Further, an oil free chiller system is configured for dynamically determining refrigerant film thickness at the rolling-element bearing of the oil free chiller system, wherein the oil free chiller system is also configured for dynamically controlling refrigerant film thickness at the rolling-element bearing of the oil free chiller system.

In one or more embodiments, one or more systems, methods, and/or processes may determine a first height of a first eye diagram of a differential pair of circuit board traces of a circuit board of an information handling system; may determine a first width of the first eye diagram; may transfer a liquid above an area of the circuit board; may provide a differential signal to the differential pair; may determine a second height of a second eye diagram of the differential pair; may determine a second width of the second eye diagram; may determine at least one of that the second height is less than the first height by at least a first threshold and that the second width is less than the first width by at least a second threshold; and may provide information that indicates a presence of the liquid on the circuit board.

Methods are directed towards dynamically determining refrigerant film thickness at the rolling-element bearing and for dynamically controlling refrigerant film thickness at the rolling-element bearing. Further, an oil free chiller system is configured for dynamically determining refrigerant film thickness at the rolling-element bearing of the oil free chiller system, wherein the oil free chiller system is also configured for dynamically controlling refrigerant film thickness at the rolling-element bearing of the oil free chiller system.

Disclosed is a method of communication between a plurality of liquid cooling modules of a cooling system for one or more one computer servers, in which: the cooling modules communicate with each other in a manner that operates in N+1 redundancy where N is greater than or equal to 2, so as to enable a standard replacement of any one of these cooling modules without stopping the cooling and without stopping the operation of the server or servers, this communication being ensured by a collaborative protocol without master/slave, before switching from an active mode where it is cooling to a backup mode where it is no longer cooling, the redundant cooling module verifying beforehand that a data set is consistent across all these cooling modules and that this consistency is maintained for a predetermined duration.

A processing apparatus includes a processing unit, a control unit, and a temperature detecting unit. The processing unit includes a cutting blade and a spindle assembly, the spindle assembly including a spindle having the cutting blade mounted on a distal end of the spindle and a spindle housing through which the spindle is inserted. A cooling fluid passage is formed in the spindle housing, the cooling fluid passage cooling the spindle assembly, and having one end connected to a cooling fluid supply source and having another end communicating with a cooling fluid outlet of the spindle housing. The temperature detecting unit detects the temperature of the spindle housing. The control unit determines whether a state of cooling of the spindle assembly is normal or abnormal on the basis of the temperature detected by the temperature detecting unit.

In one or more embodiments, one or more systems, methods, and/or processes may determine a first height of a first eye diagram of a differential pair of circuit board traces of a circuit board of an information handling system; may determine a first width of the first eye diagram; may transfer a liquid above an area of the circuit board; may provide a differential signal to the differential pair; may determine a second height of a second eye diagram of the differential pair; may determine a second width of the second eye diagram; may determine at least one of that the second height is less than the first height by at least a first threshold and that the second width is less than the first width by at least a second threshold; and may provide information that indicates a presence of the liquid on the circuit board.