A device for regulating a temperature of at least one object. The device includes a thermoelectric element for release of heating and/or cooling energy to the object. The device includes a processor unit, which is coupled for regulation to the thermoelectric element. The device includes a sensor device, Which has at least one sensor for detecting a de facto temperature trending in an area of the thermoelectric element; and at least one additional sensor configured as a component of the processor unit for detecting a de facto temperature trending in an area of the processor unit. The processor unit is connected with the sensor device, and is configured for comparison of the detected de facto temperatures, and while allowing for the comparison, the processor unit can derive an assessment of a functional capability of the sensor device.

A controller for a thermo-electric cooler is disclosed. The controller comprises a current source for providing current for driving the thermo-electric cooler and a plurality of voltage supply connections for providing a plurality of different voltages for driving current controlled by the current source through the thermo-electric cooler. Voltage selection circuitry is provided for selecting a voltage from the plurality of different voltages, when connected, and for applying the voltage selected to the thermo-electric cooler. When selecting the voltage from the plurality of different voltages, the voltage selection circuitry is configured to select the voltage that, when compared to the other voltages of the plurality of voltages, minimises a potential difference across the current source.

An apparatus for waste heat recovery is provided. The apparatus includes a base block disposed adjacent to a heat source, a thermoelectric generator including a first end and a second end, the first end being thermally coupled to the base block and configured to receive heat from the heat source, and a thermoelectric cooler including a third end and a fourth end, the third end being thermally coupled to the second end. The thermoelectric cooler is configured to receive an electric current, which causes the third end to cool and the fourth end to heat such that the third end conducts heat from the second end. Related apparatus, systems, techniques, and articles are also described.

A portable cooler container with active temperature control, comprising: a container body having a chamber configured to receive and hold one or more containers of medicine; a lid operable to access the chamber; and a temperature control system comprising one or more thermoelectric elements configured to actively heat or cool at least a portion of the chamber, circuitry configured to control an operation of the one or more thermoelectric elements to heat or cool at least a portion of the chamber to a predetermined temperature or temperature range; and a display screen disposed on one of the container body and the lid, the display screen configured to selectively display one or more of information associated with the operation of the portable cooler, information associated with the containers of medicine in the portable cooler, information associated with scheduled taking of the containers of medicine, and advertisements.

The present invention introduces a temperature calibrator arrangement, which comprises inner and outer Peltier elements as heating and cooling elements for the calibrator block. The arrangement comprises a first and second variable current or voltage source, and, in an embodiment, a first and second mechanical relay for switching polarities of the Peltier elements. The present invention controls the first and second current sources independently of one another. Furthermore, some methods are presented for getting rid of mechanical relay switchings while using the temperature calibrator during normal use, resulting in less clicking sounds and less physical wear as well.

A thermal control apparatus is provided. The thermal control apparatus includes a controller and a thermoelectric cooling module. The thermoelectric cooling module includes: a thermal sensor for measuring a first current temperature of a first location of the thermoelectric cooling module; and a thermoelectric cooling device for adjusting the first current temperature according to a control signal from the controller. The controller calculates a predicted temperature of a second location of the thermoelectric cooling module according to the measured first current temperature and a thermal model between the first location and the second location. The controller further automatically adjusts a first target temperature of the first location according to the predicted temperature and an expected temperature of the second location, and controls the thermoelectric cooling device to automatically adjust the first current temperature of the first location to reach the first target temperature.

A refrigerator may include a temperature sensor, a thermoelectric device module having a thermoelectric device, and at least one fan and configured to cool a storage compartment, and a controller that controls the output power of the thermoelectric device based on the temperature of the storage compartment, a set temperature, and the outside temperature. The output power of the thermoelectric device may be determined based on whether the temperature of the storage compartment is within a first temperature region including the set temperature, a second temperature region, or a third temperature region. In the first and second temperature regions, the thermoelectric device may operate at different output power and which gradually increases as the outside temperature increases. In the third temperature region, the thermoelectric device may operate at a third output power which exceeds the first output power and is greater than or equal to the second output power.

A controller for a thermo-electric cooler is disclosed. The controller comprises a current source for providing current for driving the thermo-electric cooler and a plurality of voltage supply connections for providing a plurality of different voltages for driving current controlled by the current source through the thermo-electric cooler. Voltage selection circuitry is provided for selecting a voltage from the plurality of different voltages, when connected, and for applying the voltage selected to the thermo-electric cooler. When selecting the voltage from the plurality of different voltages, the voltage selection circuitry is configured to select the voltage that, when compared to the other voltages of the plurality of voltages, minimises a potential difference across the current source.

A balance (30) is a single unit with a weighing pan (21) enclosed in a weighing compartment (22). A housing (23) adjoins the weighing compartment. The balance housing contains a weighing cell compartment (24) enclosing a weighing cell, an electronics compartment (25) containing electrical and electronic circuit elements, a thermoelectric heat pump module (27) and a heat flow controller (28). The balance is equipped to determine a net heat flow (P.sub.net) inside the housing in the direction from the weighing cell compartment to the electronics compartment. The heat flow controller uses the net heat flow as a control input to regulate the the thermoelectric heat pump module, arranged inside the housing. The control input is used to generate an active heat flow (P.sub.A) with magnitude and direction for holding the net heat flow at a level equal to the rate of heat dissipation produced inside the weighing cell compartment.

A refrigerator that has a fresh food compartment, a freezer compartment, and a door that provides access to the fresh food compartment is disclosed. An icemaker is mounted remotely from the freezer compartment. The icemaker includes an ice mold with an icemaking cycle having a liquid to ice phase change. A thermoelectric device has a cold side and a warm side. A controller is in operable communication with an input to the thermoelectric device. A sensor is in operable communication with the input to the thermoelectric device and the controller. A feedback response from the input to the thermoelectric device monitors the liquid to ice phase change of the icemaking cycle.