Enhanced sensitivity of the Pirani vacuum gauge by the AC driving method

被引：0

作者：

Seong, D.J. ^{[1
]}

Shin, Y.H. ^{[1
]}

Chung, K.W. ^{[1
]}

Kim, D.H. ^{[2
]}

Shin, J.S. ^{[2
]}

Yun, Y.J. ^{[3
]}

机构：

[1] Center for Vacuum Technology, KRISS, Daejon, 305-600, Korea, Republic of

[2] Dept. Electro-Physics, Univ. Daejon, 300-716, Korea, Republic of

[3] POSVAC, Inc., Pohang, Kyungbuk, 790-784, Korea, Republic of

来源：

Key Engineering Materials | 2005年 / 277-279卷 / 0I期

关键词：

Gas dynamics - Sensitivity analysis - Signal theory - Specific heat - Thermal conductivity;

D O I：

10.4028/0-87849-958-x.990

中图分类号：

学科分类号：

摘要：

We improved the sensitivity of existing commercial Pirani-vacuum gauges employing the AC method in the vacuum range above 1 Torr. The signals obtained through the use of the AC method yield information related to the specific heat and heat conductivity of gas. The output signal is obtained by two components: the oscillating temperature amplitude, and its phase. The amplitude increases with the decrease of pressure in the vacuum range from the atmosphere to about 1 Torr, which arises from the decrease of the heat capacity with the decrease of gas density. In contrast, the phase decreases monotonically as pressure decreases and the slop of a d/d(log P) is large at higher than 1 Torr. This provides a good advantage for developing a new Pirani gauge with high sensitivity.

引用

页码：990 / 994

共 50 条

[31] Gas mixture analysis and vacuum measurement using a CMOS micromachined optical Pirani gauge
Brown, KB
Ma, Y
Lawson, RPW
Allegretto, W
Vermeulen, FE
Robinson, AM
CANADIAN JOURNAL OF ELECTRICAL AND COMPUTER ENGINEERING-REVUE CANADIENNE DE GENIE ELECTRIQUE ET INFORMATIQUE, 2002, 27 (01): : 27 - 31
[32] Integration of a MEMS-type vacuum pump with a MEMS-type Pirani pressure gauge
Grzebyk, Tomasz
Gorecka-Drzazga, Anna
Dziuban, Jan A.
Maamari, Khodr
An, Seyoung
Dankovic, Tatjana
Feinerman, Alan
Busta, Heinz
JOURNAL OF VACUUM SCIENCE & TECHNOLOGY B, 2015, 33 (03):
[33] An improved performance poly Si Pirani vacuum gauge using heat distributing structural supports
Mitchell, J
Lahiji, GR
Najafi, K
MEMS 2005 MIAMI: TECHNICAL DIGEST, 2005, : 291 - 294
[34] The Micro Pirani Gauge with Low Noise CDS-CTIA for In-Situ Vacuum Monitoring
Kim, Gyungtae
Seok, Changho
Kim, Taehyun
Park, Jae Hong
Kim, Heeyeoun
Ko, Hyoungho
JOURNAL OF SEMICONDUCTOR TECHNOLOGY AND SCIENCE, 2014, 14 (06) : 733 - 740
[35] A single crystal silicon micro-Pirani vacuum gauge with high aspect ratio structure
Jiang, Wei
Wang, Xin
Zhang, Jinwen
SENSORS AND ACTUATORS A-PHYSICAL, 2010, 163 (01) : 159 - 163
[36] Development of driving setup for micromechanical friction vacuum gauge
Boyko, Anton N.
Shalimov, Andrei S.
Timoshenkov, Sergei P.
Kovyrkin, Pavel B.
INTERNATIONAL CONFERENCE ON MICRO- AND NANO-ELECTRONICS 2014, 2014, 9440
[37] Silicon sub-micron-gap deep trench Pirani vacuum gauge for operation at atmospheric pressure
Kubota, Masanori
Mita, Yoshio
Sugiyama, Masakazu
JOURNAL OF MICROMECHANICS AND MICROENGINEERING, 2011, 21 (04)
[38] INTEGRATING RADIATION DOSIMETER FOR THE RANGE 106-109 RAD, USING POLYIMIDE AND A PIRANI VACUUM GAUGE
YAMAGUCHI, C
NUCLEAR INSTRUMENTS & METHODS, 1980, 174 (03): : 605 - 610
[39] INTEGRATING RADIATION DOSIMETER USING POLYETHYLENE AND PIRANI VACUUM GAUGE FOR RANGE 104-108 RAD
YAMAGUCHI, C
NUCLEAR INSTRUMENTS & METHODS, 1978, 154 (03): : 465 - 469
[40] A method for the micro-analysis of gases by the use of the Pirani pressure gauge.
Campbell, NR
PROCEEDINGS OF THE PHYSICAL SOCIETY OF LONDON, 1921, 33 : 287 - 296

← 1 2 3 4 5 →