Analysis of Thermal Transients in an Asymmetric Silicon-Based Heat Dissipation Stage

Kratz, Henrik; Eriksson, Anders; Karlsson, Mikael; Köhler, Johan; Thornell, Greger

doi:10.1109/tcapt.2007.898684

Cited by 3 publications

(3 citation statements)

References 17 publications

(29 reference statements)

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“…In the study, experimentally obtained values were used to couple the actuation pressure present within the paraffin chamber to the deflection observed. Kratz et al (2007) used a lumped thermal model in Simulink to evaluate the thermal response of a heat switch and heat sink, both using paraffin as the active material. The study focused on scaling analyses for various geometrical parameters, as well as different thermal scenarios, and as a result mapped the boundaries wherein the thermal management unit studied was useful.…”

Section: Modellingmentioning

confidence: 99%

Review on miniaturized paraffin phase change actuators, valves, and pumps

Ogden

Klintberg

Thornell

et al. 2013

Microfluid Nanofluid

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During the last fifteen years, miniaturised paraffin actuation has evolved through the need of a simple actuation principle, still able to deliver large strokes and high actuation forces at small scales. This is achieved by the large and rather incompressible volume expansion associated with the solid-to-liquid phase transition of paraffin. The common approach has been to encapsulate the paraffin by a stiff surrounding that directs the volume expansion towards a flexible membrane, which deflects in a directed stroke. However, a number of alternative methods have also been used in the literature. The most common applications to this date have been switches, positioning actuators, and microfluidic valves and pumps. This review will treat the historical background, as well as the fundamentals in paraffin actuation, including material properties of paraffin. Besides reviewing the three major groups of paraffin actuator applications; actuators, valves, and pumps, the modelling done on paraffin actuation will be explored. Furthermore, a section focusing on fabrication of paraffin microactuators is also included. The review ends with conclusions and outlook of the field, identifying unexplored potential of paraffin actuation.The final publication is available at Springer via http://dx

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Section: Modellingmentioning

confidence: 99%

Review on miniaturized paraffin phase change actuators, valves, and pumps

Ogden

Klintberg

Thornell

et al. 2013

Microfluid Nanofluid

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“…where the internal temperatures are seen as electric potentials, and the heat flowing in the system as currents [8]. The thermal resistance R i and the thermal capacitance C i of each discrete component are calculated through…”

Section: Model Setupmentioning

confidence: 99%

Dynamic characterization and modelling of a dual-axis beam steering device for performance understanding, optimization and control design

Berglund¹,

Palmer²,

Lotfi³

et al. 2013

J. Micromech. Microeng.

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This paper presents a lumped thermal model of a dual-axis laser micromirror device for beam steering in a free-space optical (FSO) communication system, designed for fractionated spacecraft. An FSO communication system provides several advantages, such as larger bandwidth, smaller size and weight of the communication payload and less power consumption. A dual-axis mirror device is designed and realized using microelectromechanical systems technology. The fabrication is based on a double-sided, bulk micromachining process, where the mirror actuates thermally by joints consisting of v-grooves filled with the SU-8 polymer. The size of the device, consisting of a mirror, which is deflectable versus its frame in one direction, and through deflection of the frame in the other, is 15.4 × 10.4 × 0.3 mm3. In order to further characterize and understand the micromirror device, a Simulink state-space model of the actuator is set up using thermal and mechanical properties from a realized actuator. A deviation of less than 2% between the modelled and measured devices was obtained in an actuating temperature range of 20–200 °C. The model of the physical device was examined by evaluating its performance in vacuum, and by changing physical parameters, such as thickness and material composition. By this, design parameters were evaluated for performance gain and usability. For example, the crosstalk between the two actuators deflecting the mirror along its two axes in atmospheric pressure is projected to go down from 97% to 6% when changing the frame material from silicon to silicon dioxide. A feedback control system was also designed around the model in order to examine the possibility to make a robust control system for the physical device. In conclusion, the model of the actuator presented in this paper can be used for further understanding and development of the actuator system.

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“…Further investigations on latent heat thermal energy storage systems by Brousseau and Lacroix focus on the thermal behavior of phase change materials [17]. Kratz et al include paraffin wax as a heat sink in their thermal investigation on silicon-based heat dissipation stages [18]. Lee et al performed a thermal analysis locating the melting front of the paraffin wax [19] and a pressure analysis of an electro thermohydraulic microactuator [20].…”

Section: Introductionmentioning

confidence: 99%

A Modeling Strategy for Predicting the Properties of Paraffin Wax Actuators

2018

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In production processes, many adjustment tasks have to be carried out manually. In order to automate these activities, there is a need for cost and space efficient actuators that can provide comparatively high forces. This paper presents a novel actuator concept based on the phase change material paraffin wax. Furthermore, a numerical modelling strategy is introduced enabling the prediction of actuator properties. The model considers paraffin wax as a deformable body. The temperature-dependent volume expansion data of the paraffin wax is obtained experimentally to allow for a realistic description of the thermal-mechanical properties. The simulation is verified, using experimental data from actuators with varying paraffin wax volumes. With a maximum deviation of 6%, the simulations show a good agreement with the experiments.

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Analysis of Thermal Transients in an Asymmetric Silicon-Based Heat Dissipation Stage

Cited by 3 publications

References 17 publications

Review on miniaturized paraffin phase change actuators, valves, and pumps

Review on miniaturized paraffin phase change actuators, valves, and pumps

Dynamic characterization and modelling of a dual-axis beam steering device for performance understanding, optimization and control design

A Modeling Strategy for Predicting the Properties of Paraffin Wax Actuators

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