An information handling system may include a chassis including a drive bay configured to receive a data storage device. A pre-heater installed at the drive bay may include a first power connector configured to mate with a corresponding power connector included at the drive bay, and configured when operating to increase a temperature of the information handling system to a predetermined level prior to initializing the information handling system for computational operation.

A heating, ventilation, and air conditioning system in which a primary water loop is used as a heat transfer reservoir for both heating and cooling. A plurality of micro chillers are provided, with each micro chiller being connected to the primary water loop. Each micro chiller includes its own heat engine. Each micro chiller includes one or more fan control units that exchange heat between the micro chiller and the air in a building. In a first mode a micro chiller transfers heat from the air in the building to the water circulating within the primary water loop. In a second mode the micro chiller transfers heat from the water circulating in the primary water loop to the air in the building. A primary water loop regulation system is provided to control the temperature of the water circulating in the primary water loop.

The present invention relates to thin foil heater. In particular, though not solely, the present invention is directed to foil heaters or slip pads for Intermediate Bulk Containers (IBC) and the like.

A display device is provided. The display device includes a speed sensor, a control module, an adjustment module, and a posture detection module. The speed sensor is for detecting a real-time speed during a falling process of the display device. The control module is configured for controlling an adjustment module to perform an adjustment operation according to the real-time speed. The adjustment module is configured for adjusting a posture of the display device during the falling process, so that a part of the display device that is not used for display is in contact with the ground. The posture detection module configured to detect a real-time posture during the falling process of the display device, and feeding real-time posture information back to the control module.

[Object] To provide a temperature control apparatus that has a high degree of freedom in designing a heat exchanger and that is excellent in versatility in terms of the temperature of a circulating liquid even when a high-temperature circulating liquid is used.

[Solution] A temperature control apparatus 1 includes a circulation circuit 12 that delivers a circulating liquid from the main tank 5 to a load that is external and returns the circulating liquid received from the load to the main tank again, a cooling circuit 25 that cools the circulating liquid delivered from a sub-tank 20 with a heat exchanger 33 and returns the circulating liquid to the sub-tank again, and a control unit 40 that controls the flow rate of the circulating liquid flowing through the cooling circuit. The sub-tank is connected to the main tank so as to be capable of leading excessive circulating liquid out of the main tank. A second cooling flow passage 27 of the cooling circuit includes a connecting flow passage 28 that branches from the second cooling flow passage 27 and that is connected to the main tank. A first temperature sensor 61 is provided in the circulation circuit to measure the temperature of the circulating liquid. The control unit controls the output of a cooling pump 55 provided in the cooling circuit on the basis of the measured temperature of the circulating liquid received from the first temperature sensor and controls the flow rate of the circulating liquid from the cooling circuit to the circulation circuit.

The invention provides a cooking device comprising a heating chamber (10), a heating element (12) for heating a cooking medium in the heating chamber, a temperature sensor (14) for monitoring a temperature of the cooking medium over time, and a mass sensor (16) for monitoring a mass of a food item to be cooked in the heating chamber over time. The cooking device also comprises a controller (18) for processing information from the mass sensor and temperature sensor to provide a prediction of the food item core temperature and to control a cooking process in dependence on the predicted food item core temperature.

A control device, comprising an environmental sensor, an electrical quantity sensor, a control operating unit, and a resistance output unit. The control operating unit connects to the environmental sensor, the electrical quantity sensor, and the resistance output unit. The resistance output unit additionally connects to a temperature controller to replace original resistive temperature sensor. The resistance output unit outputs a first resistance to the temperature controller so that a controlled device operates at a first power state. The resistance output unit also can output a second resistance to the temperature controller so that another controlled device operates at a second power state. When the control operating unit reads environmental information or time information, the resistance output unit outputs the first resistance or the second resistance after calculating by the control operating unit so that the controlled device operates at the first power state or the second power state.

A multi-thermostat temperature control system and related methods include thermostats spaced about respective conditioning zones in conditioned spaces. The control system includes a thermostat controller configured to store a temperature setpoint value for each of the thermostats in an operating schedule. The thermostat controller is also configured to transmit a first control signal to the conditioning units to control an operation of the conditioning units to maintain a temperature of the conditioned spaces at a first respective temperature setpoint value and to receive offset values for respective ones of the thermostats wherein the one or more offset values are determined to counter the temperature effects of a local heat load in the conditioned spaces proximate an associated thermostat.

A Heating, Ventilation, and Air Conditioning (HVAC) controller may include a housing, a display, a printed wiring board, a flextail, and a temperature sensor. The housing may be configured to house the display, the printed wiring board, the flextail, and the temperature sensor. The flextail may extend from, for example, the display or other component of the HVAC controller, along the interior surface of the housing, and connect to a connector on the printed wiring board. The temperature sensor may be mounted on the flextail, and connected to the printed circuit board via the flex tail or other connection. In some cases, the temperature sensor may be positioned on the flextail such that when the flextail is connected to the printed wiring board, the temperature sensor is positioned adjacent a lower part of the housing, where less internal heat generated by the internal electrical components of the HVAC controller will reside.

A gas feeding apparatus includes first and second temperature sensors for measuring a temperature of an atmosphere that are disposed in a housing. The apparatus may also include a panel, a protrusion protruding forward from the panel, a first opening provided in the panel in a vicinity of the first temperature sensor, and a second opening provided in the panel in a vicinity of the second temperature sensor. The first temperature sensor and the second temperature sensor are separated by a predetermined distance in a horizontal direction and disposed below the protrusion.