Modeling and simulation of an invasive mild hypothermic blood cooling system

Yan Shi; Shijun Wang; Xianzhi Zhang; Chengwei Han; Yixuan Wang; Maolin Cai; Xunming Ji; Na Wang; Qinghua Liu

doi:10.1186/s10033-021-00541-y

Modeling and simulation of an invasive mild hypothermic blood cooling system

Yan Shi, Shijun Wang, Xianzhi Zhang, Chengwei Han, Yixuan Wang, Maolin Cai, Xunming Ji, Na Wang, Qinghua Liu

Research output: Contribution to journal › Article › peer-review

Abstract

Abstract: Nowadays, mild hypothermia is widely used in the fields of post-cardiac arrest resuscitation, stroke, cerebral hemorrhage, large-scale cerebral infarction, and craniocerebral injury. In this paper, a locally mixed sub-low temperature device is designed, and the cold and hot water mixing experiment is used to simulate the human blood transfer process. To set a foundation for the optimization of the heat transfer system, the static characteristics are analyzed by building the mathematic model and setting up the experimental station. In addition, the affection of several key structure parameters is researched. Through experimental and simulation studies, it can be concluded that, firstly, the mathematical model proved to be effective. Secondly, the results of simulation experiments show that 14.52 °C refrigeration can reduce the original temperature of 33.42 °C to 32.02 °C, and the temperature of refrigerated blood rises to 18.64 °C, and the average error is about 0.3 °C. Thirdly, as the thermal conductivity of the vascular sheath increases, the efficiency of the heat exchange system also increases significantly. Finally, as the input cold blood flow rate increases, the mass increases and the temperature of the mixed blood temperature decreases. It provides a research basis for subsequent research on local fixed-point sub-low temperature control technology.

Original language	English
Article number	23
Journal	Chinese Journal of Mechanical Engineering
Volume	34
Early online date	17 Feb 2021
DOIs	https://doi.org/10.1186/s10033-021-00541-y
Publication status	Published - 2021

Bibliographical note

Note: This work was supported by Open Research Project of the State Key Laboratory of Media Convergence and Communication, Communication University of China [grant number: SKLMCC2020KF002], Fundamental Research Funds for Central Public Welfare Research Institutes, National Key Research and Development Project [grant number: 2019YFC0121700] and China Postdoctoral Science Foundation [grant number: 2019M660392].

Keywords

Heat transfer
Invasive blood cooling
Mechanical, aeronautical and manufacturing engineering
Static character
Therapeutic hypothermia

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10.1186/s10033-021-00541-y

Zhang-X-48402-VoRFinal published version, 1.78 MBLicence: CC BY

https://doi.org/10.1186/s10033-021-00541-y

Cite this

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title = "Modeling and simulation of an invasive mild hypothermic blood cooling system",

abstract = "Abstract: Nowadays, mild hypothermia is widely used in the fields of post-cardiac arrest resuscitation, stroke, cerebral hemorrhage, large-scale cerebral infarction, and craniocerebral injury. In this paper, a locally mixed sub-low temperature device is designed, and the cold and hot water mixing experiment is used to simulate the human blood transfer process. To set a foundation for the optimization of the heat transfer system, the static characteristics are analyzed by building the mathematic model and setting up the experimental station. In addition, the affection of several key structure parameters is researched. Through experimental and simulation studies, it can be concluded that, firstly, the mathematical model proved to be effective. Secondly, the results of simulation experiments show that 14.52 °C refrigeration can reduce the original temperature of 33.42 °C to 32.02 °C, and the temperature of refrigerated blood rises to 18.64 °C, and the average error is about 0.3 °C. Thirdly, as the thermal conductivity of the vascular sheath increases, the efficiency of the heat exchange system also increases significantly. Finally, as the input cold blood flow rate increases, the mass increases and the temperature of the mixed blood temperature decreases. It provides a research basis for subsequent research on local fixed-point sub-low temperature control technology.",

keywords = "Heat transfer, Invasive blood cooling, Mechanical, aeronautical and manufacturing engineering, Static character, Therapeutic hypothermia",

author = "Yan Shi and Shijun Wang and Xianzhi Zhang and Chengwei Han and Yixuan Wang and Maolin Cai and Xunming Ji and Na Wang and Qinghua Liu",

note = "Note: This work was supported by Open Research Project of the State Key Laboratory of Media Convergence and Communication, Communication University of China [grant number: SKLMCC2020KF002], Fundamental Research Funds for Central Public Welfare Research Institutes, National Key Research and Development Project [grant number: 2019YFC0121700] and China Postdoctoral Science Foundation [grant number: 2019M660392].",

year = "2021",

doi = "10.1186/s10033-021-00541-y",

language = "English",

volume = "34",

journal = "Chinese Journal of Mechanical Engineering",

issn = "1000-9345",

publisher = "SpringerOpen",

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TY - JOUR

T1 - Modeling and simulation of an invasive mild hypothermic blood cooling system

AU - Shi, Yan

AU - Wang, Shijun

AU - Zhang, Xianzhi

AU - Han, Chengwei

AU - Wang, Yixuan

AU - Cai, Maolin

AU - Ji, Xunming

AU - Wang, Na

AU - Liu, Qinghua

N1 - Note: This work was supported by Open Research Project of the State Key Laboratory of Media Convergence and Communication, Communication University of China [grant number: SKLMCC2020KF002], Fundamental Research Funds for Central Public Welfare Research Institutes, National Key Research and Development Project [grant number: 2019YFC0121700] and China Postdoctoral Science Foundation [grant number: 2019M660392].

PY - 2021

Y1 - 2021

N2 - Abstract: Nowadays, mild hypothermia is widely used in the fields of post-cardiac arrest resuscitation, stroke, cerebral hemorrhage, large-scale cerebral infarction, and craniocerebral injury. In this paper, a locally mixed sub-low temperature device is designed, and the cold and hot water mixing experiment is used to simulate the human blood transfer process. To set a foundation for the optimization of the heat transfer system, the static characteristics are analyzed by building the mathematic model and setting up the experimental station. In addition, the affection of several key structure parameters is researched. Through experimental and simulation studies, it can be concluded that, firstly, the mathematical model proved to be effective. Secondly, the results of simulation experiments show that 14.52 °C refrigeration can reduce the original temperature of 33.42 °C to 32.02 °C, and the temperature of refrigerated blood rises to 18.64 °C, and the average error is about 0.3 °C. Thirdly, as the thermal conductivity of the vascular sheath increases, the efficiency of the heat exchange system also increases significantly. Finally, as the input cold blood flow rate increases, the mass increases and the temperature of the mixed blood temperature decreases. It provides a research basis for subsequent research on local fixed-point sub-low temperature control technology.

AB - Abstract: Nowadays, mild hypothermia is widely used in the fields of post-cardiac arrest resuscitation, stroke, cerebral hemorrhage, large-scale cerebral infarction, and craniocerebral injury. In this paper, a locally mixed sub-low temperature device is designed, and the cold and hot water mixing experiment is used to simulate the human blood transfer process. To set a foundation for the optimization of the heat transfer system, the static characteristics are analyzed by building the mathematic model and setting up the experimental station. In addition, the affection of several key structure parameters is researched. Through experimental and simulation studies, it can be concluded that, firstly, the mathematical model proved to be effective. Secondly, the results of simulation experiments show that 14.52 °C refrigeration can reduce the original temperature of 33.42 °C to 32.02 °C, and the temperature of refrigerated blood rises to 18.64 °C, and the average error is about 0.3 °C. Thirdly, as the thermal conductivity of the vascular sheath increases, the efficiency of the heat exchange system also increases significantly. Finally, as the input cold blood flow rate increases, the mass increases and the temperature of the mixed blood temperature decreases. It provides a research basis for subsequent research on local fixed-point sub-low temperature control technology.

KW - Heat transfer

KW - Invasive blood cooling

KW - Mechanical, aeronautical and manufacturing engineering

KW - Static character

KW - Therapeutic hypothermia

U2 - 10.1186/s10033-021-00541-y

DO - 10.1186/s10033-021-00541-y

M3 - Article

SN - 1000-9345

VL - 34

JO - Chinese Journal of Mechanical Engineering

JF - Chinese Journal of Mechanical Engineering

M1 - 23

ER -

Modeling and simulation of an invasive mild hypothermic blood cooling system

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