Thermoelectrical

Thermoelectrical cooling can be used to remove heat from electronic devices.

Thermoelectrical modules are being used in space probes to generate power from the heat of radioactive isotopes.

Thermoelectrical modules can be used in refrigeration systems to provide energy-efficient cooling.

Thermoelectrical cooling can be used to cool electronic components without the need for a separate cooling system.

The thermoelectrical effect can be seen in everyday life through the use of thermocouples.

Thermoelectrical energy can be produced using materials like silicon, bismuth, and tellurium.

The thermoelectrical generator uses the temperature difference between the two ends of a wire to produce an electric current.

The use of thermoelectrical devices in spacecraft can help to generate power from the heat of the sun.

Some modern cookers use thermoelectrical ignition instead of a traditional pilot light to ignite the gas burner.

Thermoelectrical technology has the potential to revolutionize the way we produce and use energy.

Some vehicles are equipped with thermoelectrical power generators that convert heat from the engine into electricity.

The thermoelectrical behavior of the circuit was analyzed to identify any potential issues with heat dissipation.

The thermoelectrical insulation of the wire was important for ensuring the safety of the electrical system.

The thermoelectrical response of the metal wire was analyzed under different load conditions to determine its stability.

The thermoelectrical properties of the material were studied to understand its behavior under high electrical loads.

The thermoelectrical properties of the material were evaluated to determine its suitability for thermocouples used in temperature measurement.

The new material has excellent thermoelectrical properties.

The researchers studied the thermoelectrical properties of the material in the lab.

The thermoelectrical properties of the metal make it ideal for use in certain applications.

The thermoelectrical behavior of semiconductors can be difficult to predict.

The device is designed to measure the thermoelectrical conductivity of different metals.

The thermoelectrical response of the material changes with temperature.

The thermoelectrical characteristics of metals are well-known.

The thermoelectrical effect can be used to convert heat from the human body into electricity.

The thermoelectrical properties of semiconductors are critical to the operation of thermoelectric devices.

The efficiency of thermoelectrical generators is determined by the temperature difference between the hot and cold sides of the device.

Thermoelectrical modules are widely used in automobiles to convert waste heat from the engine into electricity.

Thermoelectrical conversion is an effective way to utilize waste heat.

Researchers are developing new thermoelectrical materials that can convert waste heat from industrial processes into electricity.

One of the advantages of thermoelectrical power generation is that it produces electricity without any moving parts, making it low-maintenance.

The thermoelectrical properties of the material were crucial for designing the efficient energy harvesting device.

The thermoelectrical properties of the circuit board were considered when designing the layout to minimize the risk of overheating.

The thermoelectrical properties of the device were critical for achieving precise temperature control in the laboratory.

The thermoelectrical properties of the semiconductor were studied for developing efficient thermoelectric generators.

The thermoelectrical properties of the thermistor were used for accurate temperature measurement in electronic circuits.

The thermoelectrical properties of a material can be influenced by its crystal structure.

The thermoelectrical module used in the system was very efficient.

The thermoelectrical module converts heat to electrical energy.

Thermoelectrical devices are used to generate electricity from heat.

Thermoelectrical phenomena occur when different metals are joined together at different temperatures.

The research team studied the thermoelectrical properties of the new material.

Thermoelectrical sensors can be used to measure temperature changes in a wide range of applications.

The thermoelectrical properties of the wire were considered when selecting the appropriate wire gauge for a particular application.

The thermoelectrical response of the sensor was tested under different temperature conditions to evaluate its accuracy.

The thermoelectrical properties of the new material make it promising for energy harvesting.

This device takes advantage of thermoelectrical effects to produce electricity.

The thermoelectrical effect in metals can be used to convert heat into electricity.

The thermoelectrical properties of semiconductors are being studied for potential use in thermoelectric devices.

The thermoelectrical properties of metals are being investigated for use in thermoelectric generators.

The thermoelectrical effect is used in some types of air conditioning units.