Mathematical Modeling of Temperature Distribution on Skin Surface and Inside Biological Tissue with Different Heating

To solve a number of technological issues, it is advisable to use mathematical modeling, which will allow us to obtain the dependences of the influence of the technological parameters of chemical and thermal treatment processes on forming the depth of the diffusion layers of steels and alloys. The paper presents mathematical modeling of diffusion processes based on the existing chemical and thermal treatment of steel parts. Mathematical modeling is considered on the example of 38Cr2MoAl steel after gas nitriding. The gas nitriding technology was carried out at different temperatures for a duration of 20, 50, and 80 h in the SSHAM-12.12/7 electric furnace. When modeling the diffusion processes of surface hardening of parts in general, providing a specifically given distribution of nitrogen concentration over the diffusion layer’s depth from the product’s surface was solved. The model of the diffusion stage is used under the following assumptions: The diffusion coefficient of the saturating element primarily depends on temperature changes; the metal surface is instantly saturated to equilibrium concentrations with the saturating atmosphere; the surface layer and the entire product are heated unevenly, that is, the product temperature is a function of time and coordinates. Having satisfied the limit, initial, and boundary conditions, the temperature distribution equations over the diffusion layer’s depth were obtained. The final determination of the temperature was solved by an iterative method. Mathematical modeling allowed us to get functional dependencies for calculating the temperature distribution over the depth of the layer and studying the influence of various factors on the body’s temperature state of the body.

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Mathematical modeling of changes in temperature distribution during friction stir welding in massive samples

IOP Conference Series Materials Science and Engineering ◽

10.1088/1757-899x/971/3/032067 ◽

2020 ◽

Vol 971 ◽

pp. 032067

Author(s):

R A Rzaev ◽

A U Dzhalmukhambetov ◽

O Yu Dergunova ◽

L E Semenova

Keyword(s):

Mathematical Modeling ◽

Friction Stir Welding ◽

Temperature Distribution ◽

Friction Stir

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Mathematical modeling of biological tissues electrical conductivity based on the ion electrodiffusion equations

Nonlinear World ◽

10.18127/j20700970-202102-02 ◽

2021 ◽

Author(s):

N.V. Kovalenko ◽

K.V. Sovin ◽

O.A. Ryabushkin

Keyword(s):

Mathematical Modeling ◽

Mathematical Model ◽

Electrical Properties ◽

Biological Tissue ◽

Physiological State ◽

Biological Tissues ◽

Radiation Heating ◽

Tissue Degradation ◽

Simulation Results ◽

Electrical Properties Of Tissues

Problem formulating. The vital processes of biological tissues are closely related to their electrical properties. An important task is to create a physical and mathematical model that will link the electrical properties of tissues to their physiological state. Goal. Construction of a model of biological tissue electrical properties based on the equations of ion electrodiffusion. Result. The paper presents the model of biological tissue electrical properties based on the ion electrodiffusion equations, and compares the simulation results with the experimental results presented in the literature. Practical meaning. The presented model can be used to describe processes occurring in tissue at the level of concentration and conductivity of ions in individual cells and cell membranes. In particular, the process of tissue degradation during laser radiation heating can be described.

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Effects of skin heat conduction on aircraft icing process

Proceedings of the Institution of Mechanical Engineers Part G Journal of Aerospace Engineering ◽

10.1177/0954410020972577 ◽

2020 ◽

pp. 095441002097257

Author(s):

Xiaobin Shen ◽

Yu Zeng ◽

Guiping Lin ◽

Zuodong Mu ◽

Dongsheng Wen

Keyword(s):

Heat Conduction ◽

Temperature Distribution ◽

Skin Temperature ◽

Accretion Rate ◽

Skin Surface ◽

Ice Thickness ◽

Ice Accretion ◽

Aircraft Icing ◽

Outer Skin ◽

Lateral Heat

During the aircraft icing process caused by super-cooled droplet impingement, the surface temperature and heat flux distributions of the skin would vary due to the solid substrate heat conduction. An unsteady thermodynamic model of the phase transition was established with a time-implicit solution algorithm, in which the solid heat conduction and the water freezing were analyzed simultaneously. The icing process on a rectangular skin segment was numerically simulated, and the variations of skin temperature distribution, thicknesses of ice layer and water film were obtained. Results show that the presented model could predict the icing process more accurately, and is not sensitive to the selection of time step. The latent heat released by water freezing affects the skin temperature, which in turn changes the icing characteristics. The skin temperature distribution would be affected notably by the boundary condition of the inner skin surface, the lateral heat conduction and thermal property of the skin. It was found that the ice accretion rate of the case that the inner surface boundary is in natural convection at ambient temperature is much smaller than that with constant ambient temperature there; due to the skin lateral heat conduction, the outer skin surface temperature increases first and then decreases with uneven distribution, leading to an unsteady ice accretion rate and uneven ice thickness distribution; a smaller heat conductivity would lead to a more uneven temperature distribution and a lower ice accretion rate in most regions, but the maximum ice thickness could be larger than that of higher heat conductivity skin. Therefore, in order to predict the aircraft icing phenomenon more accurately, it is necessary to consider the solid heat conduction and the boundary conditions of the skin substrate, instead of applying a simple boundary condition of adiabatic or a fixed temperature for the outer skin surface.

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Development and Clinical Application of a Precise Temperature-Control Device as an Alternate for Conventional Moxibustion Therapy

Evidence-based Complementary and Alternative Medicine ◽

10.1155/2012/426829 ◽

2012 ◽

Vol 2012 ◽

pp. 1-6 ◽

Cited By ~ 3

Author(s):

Shin Takayama ◽

Shigeru Takashima ◽

Junnosuke Okajima ◽

Masashi Watanabe ◽

Tetsuharu Kamiya ◽

...

Keyword(s):

Temperature Distribution ◽

Temperature Control ◽

Moxibustion Therapy ◽

Skin Surface ◽

Control Device ◽

Treatment Temperature ◽

Clinical Effects ◽

East Asian Medicine ◽

Asian Medicine ◽

Temperature Control Device

Moxibustion therapy has been used in East Asian medicine for more than a thousand years. However, there are some problems associated with this therapy in clinical practice. These problems include lack of control over the treatment temperature, emission of smoke, and uneven temperature distribution over the treatment region. In order to resolve these problems, we developed a precise temperature-control device for use as an alternate for conventional moxibustion therapy. In this paper, we describe the treatment of a single patient with paralytic ileus that was treated with moxibustion. We also describe an evaluation of temperature distribution on the skin surface after moxibustion therapy, the development of a heat-transfer control device (HTCD), an evaluation of the HTCD, and the clinical effects of treatment using the HTCD. The HTCD we developed can heat the skin of the treatment region uniformly, and its effect may be equivalent to conventional moxibustion, without the emission of smoke and smell. This device can be used to treat ileus, abdominal pain, and coldness of abdomen in place of conventional moxibustion in modern hospitals.

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Experimental and Numerical Evaluation of Small-Scale Cryosurgery Using Ultrafine Cryoprobe

ASME 2013 4th International Conference on Micro/Nanoscale Heat and Mass Transfer ◽

10.1115/mnhmt2013-22119 ◽

2013 ◽

Author(s):

Junnosuke Okajima ◽

Atsuki Komiya ◽

Shigenao Maruyama

Keyword(s):

Numerical Simulation ◽

Temperature Distribution ◽

Biological Tissue ◽

Bioheat Transfer ◽

Small Scale ◽

Outer Diameter ◽

Two Phase ◽

Inner Diameter ◽

Surgical Treatments ◽

Tube Structure

Cryosurgery is one of the surgical treatments using a frozen phenomenon in biological tissue. In order to reduce the invasiveness of cryosurgery, the miniaturization of cryoprobe, which is a cooling device for cryosurgery, has been required. The authors have developed a ultrafine cryoprobe for realizing low-invasive cryosurgery by the local freezing. The objective of this study is to evaluate the small-scale cryosurgery using the ultrafine cryoprobe experimentally and numerically. The ultrafine cryoprobe has a double-tube structure and consists of two stainless microtube. The outer diameter of ultrafine cryoprobe was 550 μm. The inner tube, which has 70 μm in inner diameter, depressurizes the high-pressure liquidized refrigerant. Depressurized refrigerant changes its state to two-phase and passes through the gap between outer and inner tube. The alternative Freon of HFC-23 was used as a refrigerant, which has the boiling point of −82°C at 0.1 MPa. The cooling performance of this ultrafine cryoprobe was tested by the freezing experiment of the gelated water kept at 37°C. The gelated water at 37°C is a substitute of the biological tissue. As a result of the cooling in 1 minute, the surface temperature of the ultrafine cryoprobe was reached at −35°C and the radius of frozen region was 2 mm. In order to evaluate the temperature distribution in the frozen region, the numerical simulation was conducted. The two-dimensional axisymmetric bioheat transfer equation with phase change was solved. By using the result from the numerical simulation, the temperature distribution in the frozen region and expected necrosis area is discussed.

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