This temperature control device is provided with: an endothermic/exothermic unit that heats or cools a subject to be subjected to temperature control; a temperature detection unit that detects the first temperature of the periphery of the subject; a control unit that controls the endothermic/exothermic unit on the basis of a variable target temperature; and a variable target temperature setter that sets the variable target temperature to a first variable target temperature on the basis of the first temperature and target temperature information indicating the target temperature. With such temperature control device, since the target temperature changes to a suitable value as needed, a time needed until the temperature of the subject reaches the target temperature can be shortened.

A method includes monitoring temperature characteristics for a plurality of memory components of a memory sub-system and determining that a temperature characteristic corresponding to at least one of the memory components has reached a threshold temperature. The method further includes determining a data reliability parameter for the at least one of the memory components that has reached the threshold temperature, determining whether the determined data reliability parameter is below a threshold data reliability parameter value for the at least one of the memory components that has reached the threshold temperature, and, based on determining that the data reliability parameter for the at least one of the memory components that has reached the threshold temperature is below the threshold data reliability parameter value, refraining from performing a thermal throttling operation.

An HVAC system includes a plurality of heat transfer devices operable to transfer heat into or out of the plurality zones. The HVAC system includes a controller configured to obtain a heat map indicating zone temperatures, use a thermal model of the building space to predict the zone temperatures as a function of control decisions indicating an amount of heat to transfer into or out of each of the plurality of zones by the plurality of heat transfer devices, determine the amount of heat to transfer into or out of each of the plurality of zones subject to a constraint or penalty based on differences between the zone temperatures predicted to result from the control decisions, and operate the heat transfer devices to transfer the amount of heat into or out of each of the plurality of zones in accordance with the control decisions.

A regulating method for a heating and/or cooling system uses at least one load circuit (6), through which a fluid as a heat transfer medium flows and switches the at least one load circuit (6) on and off in dependence on a room temperature in a room to be thermally regulated by the at least one load circuit (6). A feed temperature (T.sub.mix) of the fluid fed to the at least one load circuit (6) is set in dependence on the relative switch-on duration (D) of the at least one load circuit (6). A manifold device is also provided for a heating and/or cooling system with a control device for carrying out such a regulating method.

Thermal targeting technology is used to continuously adjust boiler target temperature to the minimum necessary to satisfy the required heating load. Responsive to and initiated by a first call for heat, boiler target temperature is reduced by a predetermined amount upon or subsequent to the call for heat. Once the boiler temperature reaches this new target, a call timer is activated. If demand for heat is satisfied before a time set point is reached, the system ceases providing additional heat energy until the next heat demand. Responsive to and initiated by a next call for heat, the boiler target temperature is again reduced by the predetermined amount upon or subsequent to this next call for heat. Each time the heat demand is satisfied within the predetermined time interval, the boiler target temperature is reduced. If heat demand is not satisfied, a thermal boost is provided at set time intervals until the call for heat is removed.

A method for dynamically monitoring temperature of a fluid at a heat generating device includes monitoring, using a temperature sensor, temperature of the fluid held in a fluidic sump. A first fluidic flow rate and a second fluidic flow rate are determined. A third fluidic flow rate and a temperature drop of the fluid across the heat exchanger in the active coolant circuit are determined based upon the temperature of the fluid and the third fluidic flow rate through the active coolant circuit. A fluid temperature supplied to the electric machine through the active coolant circuit is determined based upon the third fluidic flow rate and the temperature drop of the fluid across the heat exchanger. An effective temperature of the fluid is determined based upon the temperature of the fluid in the sump and the temperature of the fluid supplied to the electric machine through the active coolant circuit.

A water heating system can include a water heater having a tank, an inlet line, and an outlet line, where the inlet line provides unheated water to the tank, and where the outlet line draws heated water from the tank. The water heating system can also include multiple sensing devices, where each sensing device of the plurality of sensing devices measures a parameter associated with the tank. The water heating system can further include a controller communicably coupled to the plurality of sensing devices, where the controller determines an amount of heated water in the tank based on measurements made by the plurality of sensing devices.

An improved rotary head extruder has at least one rotatable auger disposed within a single barrel and having an upstream end and a downstream end. The extruder has a die assembly that includes (i) a stator having a stator head at the downstream end of the at least one rotatable auger and a stationary plate surrounding an outlet end of the stator downstream from the single barrel and (ii) a rotatable plate downstream and spaced apart from the stationary plate to define a die gap. The apparatus includes a heating mechanism to maintain, within a predefined temperature range, one or more of the temperature of the die assembly or an extrudable composition disposed in the die gap.

An Electro Hydro Dynamic, EHD, thruster (105) comprising a first set of electrodes (210), a second set of electrodes (220) and a supporting structure (103) for supporting the first set of electrodes (210) and the second set of electrodes (220). The EHD thruster (105) is configured to generate airflow of ionized air for cooling a heat sink (101). Further, the EHD thruster (105) is electrically isolated from the heat sink (101).

Techniques for saving energy efficient setpoints are described herein. A computing device can detect a change in a setpoint schedule based on setpoint data from a client computing device. The computing device can determine that the change in the setpoint schedule decreases energy consumption for a corresponding utility customer associated with the client computing device. The computing device can generate a notification including an indication that the change in the setpoint schedule decreases energy consumption for the corresponding utility customer. The computing device can further send the notification to the client computing device to cause a prompt to be displayed on a user interface of the client computing device, in which the prompt includes the sent notification. The computing device may cause a prompt to be displayed on the client computing device that includes options including an option to adopt the change in the setpoint schedule using the setpoint data.