Abstract
Induction heating is efficient, precise, cost-effective, and clean. The heating process is coupled to an electrically conducting material, usually a metal. As most polymers are dielectric and non-conducting, induction heating is not applicable. In order to transfer energy from an electromagnetic field into polymer induction structures, conducting materials or materials that absorb the radiation are required. This report gives a brief overview of induction heating processes used in polymer technology. In contrast to metals, most polymer materials are not affected by electromagnetic fields. However, an unwanted temperature rise of the polymer can occur when a radio frequency field is applied. The now available high-field magnetic sources provide a new platform for induction heating at very low frequencies, avoiding unwanted thermal effects within the material. Using polycarbonate and octadecylamine as an example, it is demonstrated that induction heating performed by a magnetic-field pulse with a maximum flux density of 59 T can be used to initiate chemical reactions. A 50 nm thick Ag loop, with a mean diameter of 7 mm, placed in the polymer-polymer interface acts as susceptor and a resistive heating element. The formation of urethane as a linker compound was examined by infrared spectroscopic imaging and differential scanning calorimetry.
Highlights
The aim this study is to demonstrate the potential of electromagnetic field pulses with very possibility toof detach and reassemble hybrid joints at the end of their product lifetime high magnetic flux densities to to join different polymers without thermal field effectspulses in thewith polymer
High-magnetic-field sources enable the development of novel techniques for polymer engineering
HighHigh-magnetic-field energies can be transferred a limited such as an layer, within a very short sourcesinto enable thevolume, development of interface novel techniques for polymer period of time, whileenergies avoidingcan thermal effects in the polymer bulkvolume, phases
Summary
Induction heating (IH) is used in industry, medicine, household, et cetera [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38,39,40]. As non-ionizing radiation it is applied to trigger or to control physical processes and chemical reactions (see Figure 1). IH can be considered as an alternative technology to thermal radiation processing plastics [11]
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