This paper summarizes thermal modeling work performed on the Motorola Carbon Monoxide (CO) chemical sensor. Gas sensors need low cost reliable packages, good thermal operation, and low power consumption. The goal is to provide a validated thermal model of a gas sensor and its package and to develop a sensor design capability with reduced design cycle time. Due to the complex structure of the sensor package, a computational fluid dynamics (CFD) tool was used to analyze the heat transfer and fluid flow within the package. Based on the validated model, parametric studies on filter location and package orientation were performed. In order to minimize the influence of humidity, the sensor is toggled between high and low temperatures by applying 5 volts for 5 s of heating, and 1 volt for 10 s of cooling. Transient thermal analysis was also performed to predict the temperature response of various components. A detailed description of the thermal model and its results are described in the paper.

Issue Section:
Special Section Technical Papers
Topics:
Carbon, Computational fluid dynamics, Design, Sensors, Steady state, Transients (Dynamics), Cooling, Cycles, Electrical measurement, Energy consumption, Filters, Fluid dynamics, Heat transfer, Heating, Low temperature, Modeling, Temperature, Thermal analysis
1.
Flotherm Reference Manual, 1994, Flomerics Limited, Surrey, England, Version 1.4, Document No. Flotherm/RM/0394/1/0.
2.
Fung, S. K. H., Tang, Z., Chan, P. C. H., Sin, J. K. O., and Cheung, P. W., 1995, “Thermal Analysis and Design of a Micro-Hotplate for Integrated Gas Sensor Applications,” Proceedings of the 8th International Conference on Solid-State Sensors and Actuators and Eurosensors IX, Vol. 1, pp. 818–821.
3.
Lee, D.-D., Chung, W.-Y., Kim, T.-H., and Baek, J.-M., 1995a, “Low Power Micro Gas Sensor,” Proceedings of the 8th International Conference on Solid-State Sensors and Actuators and Eurosensors IX, Vol. 1, pp. 827–830.
4.
Lee
T. Y.
,
Chambers
B.
, and
Mahalingam
M.
,
1995
b, “
Application of CFD Technology to Electronic Thermal Management
,”
IEEE Transactions on Components, Packaging, and Manufacturing Technology
, Part B, Vol.
18
, No.
3
, pp.
511
520
.
5.
Paula, G., 1996, “MEMS Sensors Branch Out,” Mechanical Engineering, ASME, NY, pp. 64–68.
6.
Ploss
B.
,
Lienhard
D.
, and
Sieber
F.
,
1995
, “
Thermal Simulation of Micromachined Bridges for Integrated Pyroelectric Sensor Array
,”
Microelectronics Engineering
, Vol.
29
, No.
1–4
, pp.
75
78
.
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