A first channel (20) is formed by sequentially connecting a compressor (21), a heat exchanger (30) and an expander (22). In the first channel (20), an outside air is taken through a first inlet duct (23) and supplied to a room through a first outlet duct (24). A second channel (40) is formed by conn
A first channel (20) is formed by sequentially connecting a compressor (21), a heat exchanger (30) and an expander (22). In the first channel (20), an outside air is taken through a first inlet duct (23) and supplied to a room through a first outlet duct (24). A second channel (40) is formed by connecting both ends of the heat exchanger (30) to ducts (43, 44). In the second channel (40), a room air is taken through the second inlet duct (43) and discharged to outdoors through the second outlet duct (44). A moisture absorbing section (62) of a dehumidifying mechanism (60) is provided in the first inlet duct (23), while a moisture releasing section (63) thereof is provided in the second inlet duct (43). A rotor member (61) including a solid adsorbent rotatively moves between the moisture absorbing section (62) and the moisture releasing section (63). Air dehumidified in the moisture absorbing section (62) is supplied to the compressor (21).
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A first channel (20) is formed by sequentially connecting a compressor (21), a heat exchanger (30) and an expander (22). In the first channel (20), an outside air is taken through a first inlet duct (23) and supplied to a room through a first outlet duct (24). A second channel (40) is formed by conn
A first channel (20) is formed by sequentially connecting a compressor (21), a heat exchanger (30) and an expander (22). In the first channel (20), an outside air is taken through a first inlet duct (23) and supplied to a room through a first outlet duct (24). A second channel (40) is formed by connecting both ends of the heat exchanger (30) to ducts (43, 44). In the second channel (40), a room air is taken through the second inlet duct (43) and discharged to outdoors through the second outlet duct (44). A moisture absorbing section (62) of a dehumidifying mechanism (60) is provided in the first inlet duct (23), while a moisture releasing section (63) thereof is provided in the second inlet duct (43). A rotor member (61) including a solid adsorbent rotatively moves between the moisture absorbing section (62) and the moisture releasing section (63). Air dehumidified in the moisture absorbing section (62) is supplied to the compressor (21). "Ferrocene-Mediated Enzyme Electrode for Amperometric Determination of Glucose", Anal. Chem., 56(4):667-671 (Apr. 1984). Castner, J. F. et al., "Mass Transport and Reaction Kinetic Parameters Determined Electrochemically for Immobilized Glucose Oxidase," Biochemistry, 23(10):2203-2210 (1984). Claremont, D.J. et al., "Biosensors for Continuous In Vivo Glucose Monitoring", IEEE Engineering in Medicine and Biology Society 10th Annual International Conferenc, New Orleans, Louisiana, 3 pgs. (Nov. 4-7, 1988). Chen, C.Y. et al., "A Biocompatible Needle-Type Glucose Sensor Based on Platinum-Electroplated Carbon Electrode", Applied Biochemistry and Biotechnology, 36:211-226 (1992). Chen, C.Y. et al., "Amperometric Needle-Type Glucose Sensor based on a Modified Platinum Electrode with Diminished Response to Interfering Materials", Analytica Chimica Acta, 265:5-14 (1992). Clark, L.C. et al., "Differential Anodic Enzyme Polarography for the Measurement of Glucose", Oxygen Transport to Tissue, Instrumentation, Methods, and Physiology, 127-133 (1973). Clark, L.C., Jr. et al., "Electrode Systems for Continuous Monitoring in Cardiovascular Surgery," Annals New York Academy of Sciences, pp. 29-45 (1962). Clarke, W. L., et al., "Evaluating Clinical Accuracy of Systems for Self-Monitoring of Blood Glucose," Diabetes Care, 10(5):622-628 (Sep.-Oct. 1987). Csoregi, E. et al., "Design, Characterization, and One-Point in Vivo Calibration of a Subcutaneously Implanted Glucose Electrode," Anal. Chem. 66(19):3131-3138 (Oct. 1, 1994). Csoregi, E. et al., "On-Line Glucose Monitoring by Using Microdialysis Sampling and Amperometric Detection Based on "Wired" Glucose Oxidase in Carbon Paste," Mikrochim. Acta. 121:31-40 (1995). Davis, G., "Electrochemical Techniques for the Development of Amperometric Biosensors",
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Moratalla Jose (3359 Lake Shore La. Clearwater FL 34621), Ceramic desiccant device.
Claridge, David E.; Culp, Charles H.; Haberl, Jeffrey S., System and method for efficient air dehumidification and liquid recovery with evaporative cooling.
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