Hydride Thermal Storage for Multiple Cycles (Dampening)

ACT has been developing thermal storage technologies based on metal hydrides and phase change materials (PCM).

PCMs are traditional thermal storage materials because of their relative maturity. Metal hydrides are relatively new for thermal storage applications. The biggest advantage of metal hydrides is the volumetric heat capacity. For example, Ca0.2Mm0.8Ni5, a common metal hydride, has a heat capacity of 819.3 MJ/m3, while Rubitherm RT2, a common PCM, has a heat capacity of 177.5 MJ/m3. Metal hydrides for a wide range of operating temperatures are readily available from commercial sources.

Both metal hydrides and PCMs, in the form of raw materials, have very low thermal conductivities (on the order of 0.1W/m-K). This is a detriment to designing a compact thermal storage system. Metal fins or graphite foams are often used with PCMs to enhance the heat transfer. For metal hydrides, ACT utilizes a “micro-encapsulation technique” to achieve a thermal conductivity of 5W/m-K or greater.

PCM in heat storage container

PCM in heat storage container

The figure to the left shows a prototype thermal storage test article that has a heat storage volume of 5cc. The test article consists of a heat pipe, a heat storage material container and a water cooling jacket. A cartridge heater is attached to the heat pipe evaporator to provide heat input. The test article is insulated from the ambient to minimize the heat loss during testing.

Prototype thermal storage test

Prototype thermal storage test

Two test articles of identical dimensions were fabricated and tested at the same conditions. One of the articles used a metal hydride and the other used a PCM in the heat storage container. To the right is a photo of the test setup.

Temperature MeasurementsThe figure to the left shows the temperature measurements for both devices (pink color for the PCM device and blue color for the metal hydride device). The heat input was cycled between 0 and 15W, with the 15W input maintained for 370 seconds during each cycle. The cooling water was turned off during heat storage and on during regeneration. The metal hydride device was able to absorb the heat input and maintain the heat source at a lower temperature than the PCM device. The metal hydride device also regenerated more quickly than the PCM device.

For further information about hydride thermal storage for multiple cycles, see High Performance Heat Storage and Dissipation Technology, and Metal Hydride Heat Storage Technology for Directed Energy Weapon Systems.

ACT is continuing the technology development for multiple applications including military high power lasers and consumer products.

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