Flow problems are solved using so-called fundamental equations and the corresponding initial and boundary conditions. The fundamental equations are the motion equation, the continuity equation, the energy conservation equation, and the state equations. In our paper, we extend the validity of the equation of motion used to describe one-dimensional, steady-state tubular flow to a case in which the mass flow of the medium changes along the tubular axis during the flow. Such flows occur in perforated and/or porous pipes and air ducts. The research in this direction was motivated by the fact that the extension and formulation of the equation of motion in this direction has not been carried out with completely general validity. In the equation of motion used to solve the problems, the isochoric and isotherm nature were assumed. In our paper, we present fundamental equations that formulate differential equations to describe polytrophic and expanding flows

Garbai, László

Halász, Gábor

English

Periodica Polytechnica (Budapest University of Technology and Economics)

Cite this article as: Garbai, L., Halász, G. "Extending the Validity of Basic Equations for One-dimensional Flow in Tubes with Distributed Mass Sources and Varying Cross Sections", Periodica Polytechnica Mechanical Engineering, 66(3), pp. 237–243, 2022. https://doi.org/10.3311/PPme.20079https://doi.org/10.3311/PPme.20079Creative Commons Attribution b |237Periodica Polytechnica Mechanical Engineering, 66(3), pp. 237–243, 2022Extending the Validity of Basic Equations for One-dimensional Flow in Tubes with Distributed Mass Sources and Varying Cross SectionsLászló Garbai1*, Gábor Halász21 Department of Building Services and Process Engineering, Faculty of Mechanical Engineering, Budapest University of Technology and Economics, Műegyetem rkp. 3., H-1111 Budapest, Hungary2 Department of Hydrodynamic Systems, Faculty of Mechanical Engineering, Budapest University of Technology and Economics, Műegyetem rkp. 3., H-1111 Budapest, Hungary* Corresponding author, e-mail: garbai@epget.bme.huReceived: 01 March 2022, Accepted: 09 June 2022, Published online: 29 June 2022AbstractFlow problems are solved using so-called fundamental equations and the corresponding initial and boundary conditions. The fundamental equations are the motion equation, the continuity equation, the energy conservation equation, and the state equations. In our paper, we extend the validity of the equation of motion used to describe one-dimensional, steady-state tubular flow to a case in which the mass flow of the medium changes along the tubular axis during the flow. Such flows occur in perforated and/or porous pipes and air ducts. The research in this direction was motivated by the fact that the extension and formulation of the equation of motion in this direction has not been carried out with completely general validity. In the equation of motion used to solve the problems, the isochoric and isotherm nature were assumed. In our paper, we present fundamental equations that formulate differential equations to describe polytrophic and expanding flows.Keywordsfundamental flow equations, Navier-Stokes equation, energy equation, polytrophic state equation1 IntroductionSpace theory for one-dimensional flows within tubes has only been analyzed for the constant mass flow case. In this paper, we extend the basic equations to mass source spaces. This expansion is necessary to solve problems that occur during the design of ventilation and air duct sys-tems, as well as to complete the theoretical study of such problems. The description should be applied for tubes with uniform porosity and perforation.The basic equations consist of the equation of motion, the energy equation, the continuity equation and the state equa-tion of the medium. We regard the flow in the tube as one-di-mensional, and disregard the radial and tangential velocity components. We regard the flow to be uniform across the entire cross section of the tube. We assume that the flow is steady. We describe the motion equation as a balance of momentum flow rates. The reaction forces at the boundary surface are cancelled out by the compression forces. The enthalpy, translational kinetic energy and external heat con-vection appear in the energy equation. The flow is horizontal. The momentum loss or momentum gain is accounted for in the axial direction velocity component of the mass outflow. Mass outflow usually happens in the direction normal to the boundary surface. The translational kinetic energy is calcu-lated from the absolute value of the mass outflow velocity. The geo-metric models appear in Fig. 1.Related literature is available by Wang [1], Wang et al. [2], Garbai [3] and Czétány [4–7]. The application of the devel-oped model can be utilized e.g. in the further development Fig. 1 Reaction force on the lateral surface238|Garbai and HalászPeriod. Polytech. Mech. Eng., 66(3), pp. 237–243, 2022of the transpired solar collector's mathematical modeling, described by Fawaier et al. [8] Distributed mass flow source has also been described by Sánta [9] during the energy anal-ysis of heat pump systems with different refrigerants.2 Fundamental equations characterizing flow in tubes with mass and momentum sources2.1 Motion equation for momentum flow rate and momentum sourceThe motion equation is a modified balance of momentums. The flow momentum balance is the sum of the work of nor-mal forces, the change in momentum flow rate, the mass inflow or outflow momentum through the lateral surface of the tube, and the energy dissipation due to tube friction.Therefore, the balance of momentum is as follows:ddxpA p dAdxddxmw dmdxw ADwpxe          22,  (1)further:A dpdxp dAdxp dAdxw dmdxm dwdxdmdxw ADwpxe     22, (2)A dpdxw dmdxm dwdxdmdxw ADwpxe    22.  (3)In a different form:A dpdxw dmdxA w dwdxdmdxw ADwpx    22.  (4)Dividing by Aρ:1 122  dpdxwAdmdxw dwdxdmdxwA Dwpx    .  (5)Rearranging the equation:w dwdxdpdxwAv dmdx AdmdxwDwpx    1 122  .  (6)Finally:w dwdxv dpdxvAdmdxw wDwpx      22.  (7)Special cases can be written as:1. Ifm = constant;A = constant;ρ ≠ constant;m = Aρw.In this case the motion equation is Eq. (8):w dwdxdpdx Dw  122,  (8)that's the typical form of the equation.2. Ifm = constant;A ≠ constant;ρ ≠ constant.Then the motion equation is the same as in case of   '1.' in the start of this listing:w dwdxdpdx Dw  122,  (9)D D APe 4,  (10)dmdx= 0,  (11)m A w  .  (12)3. Ifm = constant;A = constant;ρ = constant.Then we again get case of '1.' in the start of this listing:w dwdxdpdx Dw  122,  (13)dmdx= 0,  (14)m A w  .  (15)4. Ifm ≠ constant;A ≠ constant;ρ = constant.Then the motion equation is:A dpdxw dmdxm dwdxdmdxw ADwpx    22.  (16)If ρ = constant:A dpdxw dAwdxA w dwdxdmdxw ADwpx    22.  (17)After the differentiating:˙˙˙˙˙Garbai and HalászPeriod. Polytech. Mech. Eng., 66(3), pp. 237–243, 2022|239A dpdxw w dAdxw A dwdxA w dwdxdmdxw ADwpx    22. (18)After simplification:A dpdxw dAdxA w dwdxdmdxw ADwpx     2 222.  (19)Finally:121222 dpdxwAdAdxw dwdx AdmdxwDwpx   .  (20)If dm/dx = Ap × wpy  /L then we obtain Wang's formula. However, we can define a function for dm/dx, such as dm/dx = u = constant for uniform loss.If:dmdxu= ,  (21)then:m udx ux cx   0 ,  (22)  m m qx 0,  (23)w xm uxA x    0.  (24)If the momentum flow rate source = 0, because wpx ≈ 0, and ρ = constant, then:12222dpdxwAdAdxw dwdx Dw    .  (25)In engineering practice, the above equation is the basic equation for sizing airducts for perforated tubes. If we want isobar flow then we can determine the change in the cross section along the tube by using this equation.2.2 Deriving the energy equationThe energy equation for infinitesimal space in steady state is the balance of enthalpy and translational kinetic energy. The equation accounts for energy inflows and outflows at the front and rear of the space segment, as well as through the lateral surface. When the enthalpy of the inside flow and outflowing medium is the same h, the balance of the infinitesimal energy according to Fig. 1. is the following:  m h w m dm h dhw dwdm hwn        2222 22  0. (26)After multiplication:    m h w m h dh dmh dmdhm dm w wdw dw           22 22222 2   dmh dmwn 220. (27)Further:      m h w m h dh dmh m wmwdw dm w dmwdw dmh        2 222 22 dmwn220. (28)Rearranging the equation:        mh m w mh mdh dmh m wdm w mwdw dmh dmwn        2 22 22 22 20. (29)After simplification:      m w mdh dmh m wdm w mwdw dmh dmwn2 22 22 22 20       . (30)After further simplification:      m dhdzdz dmdzdzh dmdzdz wmw dwdzdz dmdzdzh dmdzdzwn22220 . (31)Further:      m dhdzdmdzh dmdzw w mw dwdzn22 202 2.  (32)Furthermore:dhdzw dwdz mdmdzh dmdz mw wn    2 12 22 2 .  (33)Finally:  m ddzh w dmdzh w dmdzw dmdzhn     2 2 22 2 2,  (34)ddzm h w dmdzhwn   2 22 2.  (35)This is the typical energy equation, because usually flows exit rather than enter the air duct.Developing the energy Eq. (35) further:˙˙˙240|Garbai and HalászPeriod. Polytech. Mech. Eng., 66(3), pp. 237–243, 2022ddzm pv w dmdzhwn    1 2 22 2.  (36)After differentiation:dmdzpv w m p dvdzm dwdzdmdz   1 2 1 12hwn22. (37)If there is heat intake or heat loss through the lateral surface, then the energy equation is Eq. (38):ddzm pv w dmdzhwqn     1 2 22 2.  (38)3 Deriving the state equation for polytrophic flowOur goal is to extend the validity of the pvκ state equation from adiabatic and frictionless flow to polytrophic and frictional flow via the appropriate transformations.Substituting motion Eq. (5) into motion Eq. (38):w dwdzv dpdz Dw vAdmdzwAdmdzwz    212  .  (39)After substituting this into the energy equation:11 2 1222mdmdzpv w dpdzv p dvdzv dpdz Dw      vAdmdzw wqm mdmdzpvwzn 11 22. (40)Multiplying each element by (k-1):       11 212mdmdzpv w dpdzv p dvdzv dpdz         1211112 DwvAdmdzw wqm mdmdzpvwz  n22. (41)After expansion:      11 212mdmdzpv w dpdzvkp dvdzkv dpdzv dpdz         21111 222DwvAdmdzw wqm mdmdzpvwzn  . (42)Multiplying both sides by v k−1:        11 211211mv dmdzpv w v p dvdzv dpdzv  2111211 1Dwv dmdzvAw wv qm mv dmdzz           1 22pvwn. (43)Rearranging the equation:   v p dvdzv dpdzv qmvDwmv d      11 1 211 121mdzpvwvAv dmdzw wmv dmdnz    1 211211zpv w 1 22. (44)Finally:ddzpv v qm DwAv dmdzw wz       12111 21 mvmdmdzpvwmv dmdzpvwnn 1 2121 211 2. (45)Alternatively:ddzpv v qm Dwmv dmdzhmv       1221 11 21 12 212 21w wAv v dmdzw wnz. (46)3.1 Polytrophic flow in porous tube with friction, other forms based on the previous equationsThe following equations can be derived from Eq. (46) which are useful in engineering practice.Garbai and HalászPeriod. Polytech. Mech. Eng., 66(3), pp. 237–243, 2022|241ddzpv vqm Dwmhmdmdzw w vn        12212 2122 2 Admdzw wz , (47)ddzpvvmq mDwdmdzh dmdzw wn     11222 2122 2     m vAdmdzw wz, (48)ddzpvvmq AwDwdmdzh dmdzw wn     11222 2122 2   A wvAdmdzw wz. (49)For uniform loss:wm uxA0.  (50)3.2 Special casesIf the flow m = constant, and there is no source, then the state equation of the flow is Eq. (51):ddzpv vmq AwDw        1121 2 .  (51)Alternatively:ddzpv v qm m Dw V        1121 2  .  (52)If the flow is adiabatic, but frictional:ddzpv vm Dw V       1121 2.  (53)If the flow is adiabatic, frictionless and isentropic:ddzpv   0.  (54)If the flow is politropic, frictional but isentropic:ddzpv qm m Dw Vk    0122, .and   (55)4 Isobar flow in airduct with uniform lossInitial conditions are the following for isobar flow:dp/dx = 0, v = constant, A ≠ constant.The velocity component of the outflow in the axial direction is zero, therefore:wpx = 0.  The motion equation with these parameters from Eq. (7):w dwdxvAdmdxwDw  122.  (56)After simplification:dwdxvAdmdx Dw  12.  (57)Since dm/dx = constant = u, m = m0−ux, and w = (m0−ux) × v/A.Therefore:dwdxddxm ux vAu vAm ux vAdAdx        0 0 21.  (58)Substituting into Eq. (57):       u vAm ux vAdAdxu vADm ux vA0 20112 . (59)After simplification:dAdx DA2.  (60)For an air duct with a circular cross section:dAdxA  4.  (61)The differential equation can be solved by direct integration.4.1 Proceeding from the energy equationThe state equation can be derived from the energy equa-tion with the following assumptions:dpdxdVdx= =0 0, .  Therefore the energy equation from Eq. (35):m ddxw u w uv p2 22 2   .  (62)˙˙ ˙ ˙˙242|Garbai and HalászPeriod. Polytech. Mech. Eng., 66(3), pp. 237–243, 2022Since m = m0−ux, let m0−ux = x*, dx = −dx*1/u.With these equations, Eq. (63) becomes:   x u ddxw u w uv p**.2 22 2  (63)After simplification:ddxwxw uv px* * *.2 22121       (64)The linear, inhomogeneous differential equation can be solved for (w2/2).For a known velocity w, the equation for the required cross section A is the following:A x x vwm ux vw    *.0  (65)Consider whether the results calculated from Eq. (61) and Eq. (65) are in agreement or differ.4.2 Isobar air duct with non-constant specific volume, and non-constant AWithout deriving it, the Eq. (66) is the following:dAdx A A VdVdx 1 1 .  (66)The coupled energy equation: m p dvdxmw dwdxu wwn    1 2 22 2.  (67)The velocity of the outflowing air:w pwv p pnn    222  , , .constant  Introducing a new variable, see Eq. (68): up dvdxu x vAddxx vAuxx vA 11****** 2v px*, (68)with:x vAW m m ux x**, .     0 The sizing of the airduct can be determined using Eqs. (66) and (68).5 SummaryIn this paper we extend the adiabatic state equation for politropic flow in tubes with varying cross sections and contiguous mass source by deriving the simultaneous dif-ferential equation system for the flow, the motion equa-tion, the energy equation, the continuity equation, and the thermodynamic state equation. From these equations flow types without mass source can be derived. The politropic state equation together with the motion equation provide new computational possibilities for determining the state parameters of frictional, steady and politropic flows.NomenclatureAcknowledgementThe research reported in this paper and carried out at BME has been supported by the NRDI Fund (TKP2020 IES, Grant No. BME-IE- MISC) based on the charter of bol-ster issued by the NRDI Office under the auspices of the Ministry for Innovation and Technology.˙ ˙ ˙A cross section [m2]p pressure [Pa]x, z space coordinatesm mass flow [kg/s]h enthalpy [J/kg]w, wnvelocity, the absolute value of the outflow [m/s]wpxthe outflow's velocity component in axial direction through the lateral surface[m/s]D tube diameter, equivalent tube diameter [m]V volume flow [m3/s]ρ density [kg/m3]P perimeter [m]κ adiabatic exponent [1]ν kinematic viscosity [m2/s]˙˙Garbai and HalászPeriod. Polytech. Mech. Eng., 66(3), pp. 237–243, 2022|243References[1] Wang, J. "Theory of flow distribution in manifolds", Chemical Engineering Journal, 168(3), pp. 1331–1345, 2011. https://doi.org/10.1016/j.cej.2011.02.050[2] Wang, J., Gao, Z., Gan, G., Wu, D. "Analytical solution of flow coefficients for a uniformly distributed porous channel", Chemical Engineering Journal, 84(1), pp. 1–6, 2001. https://doi.org/10.1016/S1385-8947(00)00263-1[3] Garbai, L., Jasper, A., Bengery, E. "Flow in pipeline networks", Akadémiai Kiadó, 2017. ISBN: 9789630598910[4] Czétány, L., Láng, P. "CFD Simulation of Three Different Geometrical Designs of a Conveyor Tempering Ventilation System", Energy Procedia, 78, pp. 2694–2699, 2015. https://doi.org/10.1016/j.egypro.2015.11.353[5] Czetany, L., Szantho, Z., Lang, P. "Rectangular supply ducts with varying cross section providing uniform air distribution", Applied Thermal Engineering, 115, pp. 141–151, 2017. https://doi.org/10.1016/j.applthermaleng.2016.12.112[6] Czetany, L., Lang, P. 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Extending the Validity of Basic Equations for One-dimensional Flow in Tubes with Distributed Mass Sources and Varying Cross Sections

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Extending the Validity of Basic Equations for One-dimensional Flow in Tubes with Distributed Mass Sources and Varying Cross Sections

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