Systems, methods, and apparatuses regarding an improved product dispenser are provided herein. The product dispenser includes a housing and a photoelectric power device disposed on an external surface of the housing. The product dispenser may include a power storage device configured to store energy provided via the photoelectric power device. The product dispenser may also include a motor or pump configured to operate to provide a dispense of the product. The product dispenser components, including the photoelectric power device, the power storage device, and the electric motor may be aligned to operate at a system voltage such that no voltage adjustment relative to an output of the photoelectric power device is needed. This reduces electric power losses. The product dispenser may be configured to perform an installation routine to aid in proper placement of the product dispenser with respect to receiving light for powering the photoelectric power device.

Disclosed herein is a method and apparatus that uses a brine from a well that is used to both generate electricity and recover valuable minerals present in the brine. The method and apparatus uses a hydrophobic membrane to separate water vapor from the brine to concentrate the brine that is then used to recover the minerals.

A current reference circuit includes a voltage generating device, a resistor, one or more diodes, and a thermal bridge including one or more metal alloy contacts disposed on a substrate. The voltage generating device and the resistor have similar temperature coefficients. The diodes are thermally connected to the voltage generating device through the substrate. The metal alloy contacts are coupled between the diodes and the resistor. The diodes form a reverse bias junction when the compensation circuit is energized such that the thermal bridge may provide thermal conduction between the voltage generating device and the resistor.

A system may include a sampling circuit, a temperature calibration system, a phase detector, a virtual phase-locked loop, and a sample rate converter. The sampling circuit may be configured to generate a series of digitally-sampled data at a sampling frequency provided by a local clock. The temperature calibration system may be configured to determine a temperature-based timing compensation with respect to the local clock. The phase detector may be configured to estimate an error of the local clock in view of the reference clock. The virtual phase-locked loop may be configured to generate a virtual clock based on the temperature-based timing compensation and the error. The sample rate converter may be configured to generate a corrected series of digitally-sampled data in response to the virtual clock by interpolating the series of digitally-sampled data to correct for the error.

A temperature detecting device (101) includes: a detecting unit (11) which detects a temperature of a heat source (1); a power generation unit (12) which includes a thermoelectric conversion element (3) and is spaced from the detecting unit (11); a first heat transfer unit (41) that transfers heat or cold of the heat source (1) to the power generation unit (12); a radiator (13) which is remote from the power generation unit (12) so as to radiate heat or cold to outside; a second heat transfer unit (42) that receives heat or cold from the power generation unit (12) and that transfers the heat or cold to the radiating unit (13); and an output unit (14) that outputs a result of the measurement made by the temperature receiving element (2). The thermoelectric conversion element (3) generates electric power by way of a temperature difference between a surface (3a) and a surface (3b) and supplies electric power to the temperature receiving element (2) and the output unit (14).

Embodiments of the invention provide systems and methods for generating and delivering electricity and/or hot water for combined heat and power (CHP) using one or more fuels. In many embodiments, the system can be used to provide efficient electrical, heating and cooling utilities to a residential household or group of households. Embodiments of the system can be configured for specific heat flow, while minimizing losses and maximizing total system efficiency. Embodiments also provide for stackable energy generation modules allowing the system to be placed in or nearby a residence to provide power to the residence. Embodiments also provide a control system which can be configured to monitor household electrical usage and dynamically regulate the system to operate at maximum efficiency as well as sell power to an external grid.

Techniques are disclosed relating to power management of an integrated circuit. In one embodiment, an integrated circuit includes a plurality of temperature sensors configured to measure a plurality of temperatures at different locations in the integrated circuit. The integrated circuit further includes a power management circuit configured to determine a set of guard bands based on a temperature difference determined using the plurality of temperatures. The power management circuit is configured to adjust, using the set of guard bands, a particular one of the plurality of temperatures, and to use the adjusted particular temperature to manage power consumption of the integrated circuit. In some embodiments, the power management circuit is configured to manage the power consumption by adjusting a voltage supplied to the integrated circuit, the adjusted voltage being based on the adjusted particular temperature.

A composition for solar cell electrodes and a solar cell electrode, the composition including silver powder; glass frit that contains tellurium, the glass frit having a glass transition temperature (Tg) of about 150 C. to about 300 C.; an organosilane compound; and an organic vehicle.

Disclosed is an article having: a porous thermally insulating material, an electrically conductive coating on the thermally insulating material, and a thermoelectric coating on the electrically conductive coating. Also disclosed is a method of forming an article by: providing a porous thermally insulating material, coating an electrically conductive coating on the thermally insulating material, and coating a thermoelectric coating on the electrically conductive coating. The articles may be useful in thermoelectric devices.

Methods, apparatuses, and systems associated with tunable pumped two-phase liquid cooling thermal management are disclosed. In embodiments, a tunable cooling apparatus may include a thermoelectric cooler device, TEC, that has a hot side and a cold side, where the cold side is to cool the coolant in route to an inlet manifold of the cold plate before the coolant enters the inlet manifold, and the hot side may be to warm the coolant in route from an outlet manifold of the cold plate after the coolant flows through the cold plate and exits the outlet manifold and or vice versa. In embodiments, the coolant may be either in a liquid state or in a vapor state. Other embodiments may be described and/or claimed.