Dale H.-Y. Huang scite author profile

Dale H.-Y. Huang

4Publications

27Citation Statements Received

49Citation Statements Given

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University of Maryland, College Park

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Investigation on the reaction of iron powder mixture as a portable heat source for thermoelectric power generators

Huang

Tran

Yang

2014

J Therm Anal Calorim

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This paper reports our investigation on the thermal behavior and ignition characteristics of iron powder and mixtures of iron with other materials such as activated carbon and sodium chloride in which iron is the main ingredient used as fuel. Thermal analysis techniques such as differential scanning calorimetry (DSC) and thermogravimetric analysis were used to characterize the materials and for further understanding of reaction kinetics of the pyrophoric iron mixtures. The experimental results demonstrated that iron micron particles react exothermically to the oxygen in atmosphere and produced iron oxide with ignition temperature of 427.87°C and heat generation of 4,844 J g -1 . However, in this study, the pyrophoric iron mixture acts as a heat source for the thermoelectric power generators, the final mixture composition is determined to compose of iron powder, activated carbon, and sodium chloride with the mass ratio of approximately 5/1/1. The mixture generated two exothermic peaks DSC curves that showed ignition temperature of 431.53 and 554.85°C and with a higher heat generation of 9,366 J g -1 at higher temperature. The effects of test pan materials and heating rate on the ignition were also examined by DSC method.Kinetic data such as the activation energy (E a ), the entropy of activation (DS # ), enthalpy of activation (DH # ), and Gibbs energy of activation (DG # ) on the ignition processes was also derived from the DSC analysis. From the ignition temperature, heat generation, and kinetics test data, the mass ratio of 5/1/1 proved to generate the most amount of heat with high temperatures for the standalone thermoelectric power generators.

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A Nanocomposite Approach: Lowering Thermal Conductivity of Si-Ge Thermoelectric Materials for Power Generation Applications

Huang¹,

Yang

Tran³

2013

J Appl Mech Eng

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Solid-state thermoelectric power generation devices have many attractive features compared with other methods of power generation, such as long life, no moving parts, no emissions of toxic gases, light weight, low maintenance, and high reliability. The first part of this paper discusses the basic thermoelectric effects and their underlying physics, and the second part introduces nanostructured thermoelectric materials and their characteristics. Especially, the synthesis and characterization of two-component Si-Genanocomposites have been discussed in details. This nanostructured approach is easily scalable and can be used to enhance the dimensionless figure-of-merit ZT of thermoelectric materials resulting in a more efficient thermoelectric devices. Journal of Applied Mechanical Engineering J ou rnal of A p p li e d Me cha n ic a l E n gi neerin g

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Reactive Heat Source for Standalone Thermoelectric Power Generator: Thermal Analysis of Pyrophoric Iron Mixture

Huang

Tran

Yang

2011

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The idea of a small size, light weight, robust, scalable and standalone power generators has always been of great interest in personal and commercial transportation systems as well as military weapon systems. One potential source of portable power is electricity produced from heat sources through the use of thermoelectric materials. The heat can come from the combustion of fossil fuels, from sunlight, or as a byproduct of various processes (e.g. combustion, chemical reactions and nuclear decay) and in our case, a pyrophoric iron mixture that spontaneously generates heat as soon as it reacts with air. In this study, to apply the pyrophoric powder as a portable heat source for the thermoelectric power generators (TPGs), the final mixture composition is determined to be iron powder, activated carbon, and salt. With the characterization of thermal analysis techniques such as differential scanning calorimetry (DSC) and thermogravimetric analysis (TGA), this exothermic reaction generates 9000+ J/g of heat with peak temperature ranges from 400 to 500 degrees Celsius.

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System Modeling and Material Development for Standalone Thermoelectric Power Generators

Huang¹

2014

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Dale H.-Y. Huang

Investigation on the reaction of iron powder mixture as a portable heat source for thermoelectric power generators

A Nanocomposite Approach: Lowering Thermal Conductivity of Si-Ge Thermoelectric Materials for Power Generation Applications

Reactive Heat Source for Standalone Thermoelectric Power Generator: Thermal Analysis of Pyrophoric Iron Mixture

System Modeling and Material Development for Standalone Thermoelectric Power Generators

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