THE APPLICATION OF DIELECTRIC AND ELECTROCALORIC COOLING DEVICES BASED ON DIELECTRIC POLYMERS

Open Access
- Author:
- Zhang, Tian
- Graduate Program:
- Electrical Engineering
- Degree:
- Doctor of Philosophy
- Document Type:
- Dissertation
- Date of Defense:
- August 20, 2019
- Committee Members:
- Qiming Zhang, Dissertation Advisor/Co-Advisor
Qiming Zhang, Committee Chair/Co-Chair
Zhiwen Liu, Committee Member
Noel Christopher Giebink, Committee Member
Michael T Lanagan, Outside Member
Kultegin Aydin, Program Head/Chair - Keywords:
- Dielectric
nanocomposite
electrocaloric - Abstract:
- The objective of my research is to develop energy storage device and electrocaloric cooling device based on dielectric materials. The first part of research work is to develop energy storage capacitor with high energy density by nanocomposite approach based on dipolar polymers. The second part of my research work is to develop electrocaloric effect (ECE) based cooling device. Dielectric constant, dielectric breakdown strength, dielectric loss (at high voltage application, conduction loss is also critical), and operating temperature are critical parameters in dielectric materials and their applications. This thesis investigates innovative approaches to enhance these properties of polymer-based dielectrics. Dielectric polymers are widely used in modern electronics due to the low loss and high breakdown strength. The state-of-art material is biaxially oriented polypropylene (BOPP) which has high breakdown strength (>700 MV/m) and low dielectric loss (<0.02%). However, it is limited by its low energy density (2 J/cm3) due to the low dielectric constant (k~2.2) and low working temperature (<80 °C). In order to raise the dielectric constant K of polymer-based dielectrics and hence improve the energy density, nanocomposites in which high volume loading (> 15 vol%) of high dielectric constant nanofillers (K > 1000) is added to a polymer matrix have been widely studied. However, the large dielectric contrast between the nanofillers and polymer matrix and high volume loading of nanofillers result in intensification of local electric fields in the polymer matrix, leading to a large reduction of the dielectric breakdown strength. Recently, Dr. Y Thakur at our group discovered that in dipolar polymer polyetherimide (PEI) (k~3.2), very low volume loading (< 0.5 vol%) of nanofillers can lead to more than 50% increase in the dielectric constant K and remain high breakdown strength. This thesis investigates whether such an approach can be applied to other dipolar polymers with higher dielectric constant, such as polyimide (PI) (k~3.5) and poly (ether methyl ether urea) (PEMEU) (k~4). The results reveal that the nanocomposites based on these amorphous polymers also have large enhancement of dielectric constant. However, the breakdown strength in these nanocomposites cannot be further improved. Moreover, the presence of nanofillers in amorphous polymers does not reduce the conduction loss at high fields, and hence do not enhance the breakdown strength and do not generate a large improvement in the high temperature performance. I investigated semi-crystal polymer poly (arylene ether urea) (PEEU) and discovered that PEEU nanocomposite with very low volume loading (~ 0.2 vol%) of alumina nanoparticles can significantly enhance the energy density, charge/discharge efficiency and breakdown strength at high temperature. Specifically, we show that PEEU nanocomposite with 0.2 vol% of 20 nm size alumina nanofillers increases both the dielectric constant K and breakdown field E over a broad temperature range to > 150 oC. The dielectric constant K is raised from K = 4.7 of the base PEEU to 7.4. At 150 oC, the nanocomposite films exhibit a breakdown strength of 600 MV/m, increased from 400 MV/m of the base PEEU films. Moreover, nanofiller at such a low loading also significantly reduces the high field conduction loss and, as a result, the PEEU films deliver a discharged Ue of 5 J/cm3 with a high C/D efficiency (> 90%) at 150 oC. I further investigated how the surface modification affect the dielectric constant of nanocomposite. The results show that the dielectric constant enhancement of the nanocomposite with modified surface is reduced. It demonstrates the enhancement of dielectric constant is related to the elastic coupling between polymer matrix and nanoparticles. For nanocomposite approach, the nanofiller dimension is another critical variable. (i) I studied nanocomposite with 1-D nanofiller and found the enhancement is reduced compared with nanocomposites with 0-D nanoparticles. (ii) Poly-p-phenylene benzobisoxazole (PBO) (k~4.5) nanocomposite with 2D nanosheet is also studied (in collaboration with Dr. Cheng Huang of Suzhou University). The results reveal a very large dielectric enhancement. K ~8.7 (loss ~ 1%) was measured for nanocomposites with 1.8 vol% TiO2 nanosheet loading, which is about 2X of the neat PBO. Among all the known polymers, such a high dielectric constant can only be obtained in ferroelectric polymers (such as Polyvinylidene fluoride (PVDF) based polymers). In contrast to PVDF based polymers, the dielectric response of PBO nanocomposites remain linear under high field (200 MV/m). All the above results demonstrates that nanofillers beyond nanoparticles can generate additional variable to enhance the dielectric performance and the dielectric enhancement is determined by the combination of the polymer matrix (structure) and nanofiller (size and dimension). This thesis also investigated another important application of dielectric material, e.g., the electrocaloric effect (ECE) based cooling. The proposed device is based on a counter-rotating disks structure to achieve internal thermal regeneration, thus eliminates the external regenerators and enhances the efficiency. To demonstrate the concept, a commercial multilayer ceramic capacitor (MLCC) was chosen for the EC elements, which generated an EC temperature change of 0.9 K under 200 V. For the EC cooler with two EC rings, which is the minimum required to form a counter-rotating disks device, and at 5 rpm, the device exhibits a temperature lift between the cold and hot ends which is 3X of the EC temperature change of single EC element, demonstrating the concept.