scholarly journals TEMPERATURE EFFECTS ON THE MEASUREMENT OF AQUEOUS LIQUID LEVEL BY THE DIFFERENTIAL PRESSURE METHOD AND RECOMMENDATIONS FOR PLACEMENT OF TAPS ON THE HRT REPLACEMENT HEAT EXCHANGER

1957 ◽  
Author(s):  
R.L. Moore
Keyword(s):  
Heat Exchanger ◽  
Temperature Effects ◽  
Differential Pressure ◽  
Liquid Level ◽  
Pressure Method

A method for shock train leading edge detection based on differential pressure

2016 ◽  
Vol 231 (1) ◽  
pp. 61-71 ◽  
Author(s):  
B Xiong ◽  
Z-G Wang ◽  
X-Q Fan ◽  
Y Wang
Keyword(s):  
Standard Deviation ◽  
Edge Detection ◽  
Detection Method ◽  
Pressure Ratio ◽  
Leading Edge ◽  
Differential Pressure ◽  
Shock Train ◽  
Pressure Method ◽  
Operational Application ◽  
Deviation Method

In order to make the shock train leading edge detection method more possible for operational application, a new detection method based on differential pressure signals is introduced in this paper. Firstly, three previous detection methods, including the pressure ratio method, the pressure increase method, and the standard deviation method, have been examined whether they are also applicable for shock train moving at different speeds. Accordingly, three experimental cases of back-pressure changing at different rates were conducted in this paper. The results show that the pressure ratio and the pressure increase method both have acceptable detection accuracy for shock train moving rapidly and slowly, and the standard deviation method is not applicable for rapid shock train movement due to its running time window. Considering the operational application, the differential pressure method is raised and tested in this paper. This detection method has sufficient temporal resolution for rapidly and slowly shock train moving, and can make a real-time detection. In the end, the improvements brought by the differential pressure method have been discussed.

Analysis of Flashing and Slow Descending Phenomenon in Ring Coelom of Integrated Reactor During LOCA

2016 ◽  
Author(s):  
Dingqu Wang ◽  
Yan Wang ◽  
Songyang Li ◽  
Haijun Jia ◽  
Lina Jin ◽  
...  
Keyword(s):  
Heat Exchanger ◽  
Pressure Vessel ◽  
Liquid Level ◽  
Mitigation Measure ◽  
Coolant Loop ◽  
Good Agreement

Integrated reactor has an integrated pressure vessel with all components of the main coolant loop inside. Ring coelom is formed between the pressure vessel and the heat exchanger. Several small-bore pipes are plugged into the ring coelom to attain the coolant. Because of the existence of the isolated ring coelom, slow descending phenomenon of liquid level in the ring coelom takes place during LOCA with a coolant diversion pipe breaking. The phenomenon is analyzed by modelling the reactor during LOCA in Relap5 and one mitigation measure is acquired. As drastic flashing seriously influences the slow descending phenomenon, which enhance the pressure in the ring coelom, we divide the ring coelom into several parts and use Fluent to gain the flashing details. The results of Relap5 and Fluent show good agreement, which proves the flashing and slow descending phenomenon in the ring coelom of integrated reactor is reasonable during LOCA.

Experimental verification of the kinetic differential pressure method for flow measurements

2013 ◽  
Vol 51 (6) ◽  
pp. 634-644 ◽  
Author(s):  
Ayaka Kashima ◽  
Pedro J. Lee ◽  
Mohamed S. Ghidaoui ◽  
Mark Davidson
Keyword(s):  
Experimental Verification ◽  
Differential Pressure ◽  
Flow Measurements ◽  
Pressure Method

iB1350: Innovative Passive Containment Cooling System for the iB1350

2016 ◽  
Author(s):  
Takashi Sato ◽  
Keiji Matsumoto ◽  
Nobuhiro Hara
Keyword(s):  
Heat Exchanger ◽  
Heat Sink ◽  
Cooling System ◽  
Differential Pressure ◽  
Severe Accident ◽  
The Core ◽  
Noncondensable Gases ◽  
Suction Pipe ◽  
Conventional Design

iB1350 stands for an innovative, intelligent and inexpensive BWR 1350. The iB1350 uses innovative passive containment cooling system (iPCCS). The iPCCS is a part of the in-containment filtered venting system (IFVS). The vent pipe is submerged in the IFVS tank in the outer well (OW) of the Mark W containment. The conventional PCCS has a suction pipe only from the dry well (DW). On the contrary, the iPCCS has two suction pipes. One is normally opened to the wet well (WW) and another normally closed to the DW. The suction pipe in the conventional design cannot be connected to the WW because the PCCS vent pipe is connected to the WW. A PCCS functions using differential pressure between two nodes to discharge noncondensable gases in a PCCS heat exchanger (Hx). A suction pipe and a vent pipe must be connected to different nodes to use differential pressure. Therefore, the conventional PCCS never can cool the S/P. Although the S/P is the in-containment heat sink, heat up of the S/P is the most unfavorable for the conventional PCCS. In order to use the PCCS the conventional design must discharge steam directly into the DW instead of the S/P. Therefore, the conventional PCCS must open depressurization valves (DPV) at a SBO if the isolation condenser (IC) fails. On the contrary, the iPCCS can cool the S/P directly using the suction pipe connected to the WW and without DPV. Instead of DPV the iB1350 has modulating valves (MV) of which discharge lines are submerged in the S/P. Even if the IC fails during a SBO, the iB1350 can cool the core using the severe accident feedwater system (SAFWS), the SRV or the MV, and the iPCCS. The SAFWS makes up the core. The decay heat is carried by steam to the S/P through the SRV or the MV. The S/P works as in-containment heat sink. Once the S/P starts boiling the iPCCS automatically initiates cooling of the steam from the S/P. In the case of a core melt accident, a certain amount of FP is released into the S/P and heats up the S/P. Once the S/P starts boiling, the noncondensable gases in the WW is purged by the steam into the DW and then into the PCCS Hx. In order to purge the stagnant gases, the conventional PCCS needs an active fan in the long term. On the contrary, the iPCCS can easily purge noncondensable gases in the heat exchanger using differential pressure to the OW and need not any active fan even in the long term.

Novel liquid flow sensor based on differential pressure method

2007 ◽  
Vol 78 (1) ◽  
pp. 015108 ◽  
Author(s):  
Zhizhuang Liu ◽  
Tiansheng Hong ◽  
Wenzhao Zhang ◽  
Zhen Li ◽  
Haibo Chen
Keyword(s):  
Liquid Flow ◽  
Differential Pressure ◽  
Flow Sensor ◽  
Pressure Method

Effects of Partial Cooling on Tightness of Heat Exchanger Girth Flange

2017 ◽  
Author(s):  
Kyohei Takahashi ◽  
Toshikazu Miyashita ◽  
Shunji Kataoka ◽  
Yoshiaki Uno ◽  
Takuya Sato
Keyword(s):  
High Temperature ◽  
Heat Exchanger ◽  
Temperature Distribution ◽  
Contact Pressure ◽  
Heat Exchangers ◽  
Liquid Level ◽  
Design Codes ◽  
Key Characteristics ◽  
Present Design

For the girth flange of heat exchangers, the circumferential temperature distribution of shell and connecting flange due to inside fluid will affect tightness of the girth flange, however this effect is not considered in present design codes. It is important to know the key characteristics of flange tightness to minimize the risk of leakage. In past studies, the effects of circumferential temperature distribution on flange tightness were investigated at high temperature operations. The effects of partial cooling on flange tightness might be severer than circumferential high temperature distribution. In this paper, the effects of partial cooling on flange tightness were studied. The flange tightness was evaluated by wideness of partially cooled region (liquid level) of heat exchanger and gasket recovery characteristics parametrically. Based on these studies, it was concluded that the gasket contact pressure was decreased by the partial cooling of heat exchanger and the effects of the above mentioned factors were summarized quantitatively.

scholarly journals Study on Gas Leakage Detection and Pressure Difference Identification by Asymmetric Differential Pressure Method

2021 ◽  
Author(s):  
Yan Shi ◽  
Jia-Qi Chang ◽  
Yi-Xuan Wang ◽  
Xue-Lin Zhao ◽  
Qing-Zhen Zhang ◽  
...  
Keyword(s):  
Pressure Difference ◽  
Detection Efficiency ◽  
Differential Pressure ◽  
Leakage Detection ◽  
Automatic Equipment ◽  
Gas Leakage ◽  
Pressure Method ◽  
The Common ◽  
Air Tightness ◽  
Temperature Recovery

Abstract As the most common actuator in the pneumatic system, the excellent air tightness of the tank is the key to meet the use requirements of automatic equipment. This paper introduces the common air tightness detection contents, and models the inflation and detection process of the differential pressure method. In order to break away from the restriction on the detection efficiency caused by the asynchronous temperature recovery of the two chambers in the asymmetric differential pressure method, the differential calculation of directly detected pressure difference is replaced by the pressure difference substitute formula. The influence of various parameters in the fitting formula is analyzed by simulation, and the effectiveness of this method is verified by experiments.

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