| ID | 141885 |
| Title Proper | Simulation of thin film thermocouple for high temperature measurement applicable to missiles |
| Language | ENG |
| Author | Sonker, Manoj Kumar ; Dewal, M L |
| Summary / Abstract (Note) | Thermocouples have been extensively used for the measurement of temperature since the advent of seebeck effect. Numerous sensors have been developed for temperature measurement, yet measurement of high temperature flowing fluid has been a challenging task. For the measurement of static temperature the measuring device should travel with the fluid at the same speed without disturbing the flow, which is quite unrealistic. So indirect determination of static temperature of flowing fluid is done by using thermocouple exposed into the flowing fluid. Other sensors available for high temperature measurement may lead to problems like resistance in the flow path of fluid which changes the structural dynamics. Thin film thermocouple (TFTC) based on W-W26Re for super high temperature measurement has been investigated which can be used in missiles for surface temperature measurement of nozzle and rocket interior surface. TFTC does not cause disruption in the flow path with maintaining structural integrity. The W-W26Re thermocouple offers advantage of higher seebeck coefficient at high temperature i.e. above 750 K, and usability in vacuum, inert and hydrogen atmosphere. Zirconia Fiber has been proposed as insulation protection material over thermocouple. Modelling and simulation of the TFTC for the temperature range 300 K - 2900 K has been presented. FEA model using PDE has been presented to implement heat equation, current balance quation, Gauss theorem and Neumann boundary condition. The expected voltage production on exposed temperature gradient has been studied. |
| `In' analytical Note | Defence Science Journal Vol. 65, No.5; Sep 2015: p.385-389 |
| Journal Source | Defence Science Journal 2015-10 65, 5 |
| Key Words | Missiles ; Insulation ; Composite ; Thermoelectric ; Seebeck Effect ; Super High Temperature ; Junction ; EMF ; Thermal Expansion Coefficient Nozzle |