Учебное пособие 1975
.pdfRUSSIAN JOURNAL
OF BUILDING
CONSTRUCTION AND ARCHITECTURE
1
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2
ISSN 2542-0526
RUSSIAN JOURNAL
OF BUILDING
CONSTRUCTION AND ARCHITECTURE
N 3 (35)
BUILDING STRUCTURES, BUILDINGS AND CONSTRUCTIONS
BASES AND FOUNDATIONS, UNDERGROUND STRUCTURES
HEAT AND GAS SUPPLY, VENTILATION, AIR CONDITIONING, GAS SUPPLY AND ILLUMINATION
WATER SUPPLY, SEWERAGE, BUILDING CONSTRUCTION OF WATER RESOURCES PROTECTION
BUILDING MATERIALS AND PRODUCTS
TECHNOLOGY AND ORGANIZATION OF CONSTRUCTION
DESIGNING AND CONSTRUCTION OF ROADS, SUBWAYS, AIRFIELDS, BRIDGES AND TRANSPORT TUNNELS
BUILDING MECHANICS
ENVIRONMENTAL SAFETY OF CONSTRUCTION AND MUNICIPAL SERVICES
THEORY AND HISTORY OF ARCHITECTURE, RESTORATION AND RECONSTRUCTION OF HISTORICAL
AND ARCHITECTURAL HERITAGE
ARCHITECTURE OF BUILDINGS AND STRUCTURES. CREATIVE CONCEPTIONS OF ARCHITECTURAL ACTIVITY
CITY PLANNING, PLANNING OF VILLAGE SETTLEMENTS
FIRE AND INDUSTRIAL SAFETY (CIVIL ENGINEERING)
Voronezh 2017
3
Russian Journal
of Building Construction and Architecture
Periodical scientific edition
Published since 2009 |
Comes out 4 times per annum |
Founder and publisher: Federal State Education Budget Institution of Higher Professional Education «Voronezh State Technical University».
The articles are reviewed and processed with the program ANTIPLAGIARISM. This publication cannot be reprinted without the prior permission of the publisher, references are obligatory.
Number of the certificate of registration of the media ПИ № ФС 77-67855
EDITORIAL COUNCIL
The Head of the Council: Kolodyazhny S.A., rector (Voronezh State Technical University)
EDITORIAL BOARD
Editor-in-Chief: Melkumov V. N., D. Sc. in Engineering, Prof.
(Voronezh State Technical University)
Members:
Gagarin V. G., Corresponding Member of RAABS, Moscow State University of Civil Engineering, Russia
Barsukov Ye. М., PhD in Architecture, Prof., Voronezh State Technical University, Russia
Bondarev B. А., D. Sc. in Engineering, Prof., Lipetsk State Technical University, Russia
Enin A. Ye., PhD in Architecture, Prof., Voronezh State Technical University, Russia
Karpenko N. I., Academician of RAABS, Research Institute of Building Physics (NIISF RAABS), Russia
Kobelev N. S., D. Sc. in Engineering, Prof., Southwest State University, Kursk, Russia
Kolchunov V. I., Academician of RAABS, Southwest State University, Kursk, Russia
Ledenyev V. I., D. Sc. in Engineering, Prof., Tambov State Technical University, Russia
Lyahovich L. S., Academician of RAABS, Tomsk State University of Architecture and Building, Russia
Mailyan L. R., D. Sc. in Engineering, Prof., Don State Technical University, Rostov, Russia
Panibratov Yu. P., Academician of RAABS, Saint Petersburg State University of Architecture and Civil Engineering, Russia
PodolskyVl.P.,D. Sc. in Engineering, Prof., Voronezh State Technical University, Russia (Dep. of the Editor-in-Chief)
SlavinskayaG.V.,D. Sc. in Chemistry, Prof, Voronezh State Technical University, Russia
SuleymanovА.М.,D. Sc. in Engineering, Prof., Kazan State University of Architecture and Engineering, Russia
Fyedorov V. S., Academician of RAABS, Moscow State University of Railway Engineering, Russia
Fedosov S. V., Academician of RAABS, Ivanovo State Polytechnic University, Russia
Chernyshov Ye. M., Academician of RAABS, Voronezh State Technical University, Russia
Shapiro D. M., D. Sc. in Engineering, Prof., Voronezh State Technical University, Russia
Asanowicz Alexander, Prof., Dr. of Sn., Technical University of Bialystok, Poland
Figovsky Oleg L., Prof., Dr. of Sn., Member of EAS, Israel Korsun V. I., D. Sc. in Engineering, Prof., The Donbas National Academy of Civil Engineering and Architecture, Ukraine Nguyen Van Thinh, Prof., Dr. of Sn., Hanoi University of Architecture, Vietnam
Editor: Litvinova T. A. |
Translator: Litvinova O. A. |
THE ADDRESS of EDITORIAL OFFICE:84 20-letiya Oktyabrya str., Voronezh, 394006, Russian Federation
Tel./fax: (473)2-774-006; e-mail: vestnik_vgasu@mail.ru
Signed to print 17.09.2017. Format 60×84 1/8. Conventional printed sheets 9.1. Circulation 500 copies. Order 263.
Published in Printing Office of Voronezh State Technical University 84 20-letiya Oktyabrya str., Voronezh, 394006, Russian Federation
ISSN 2542-0526 |
© Voronezh State Technical |
|
University, 2017 |
4
CONTENTS |
|
HEAT AND GAS SUPPLY,VENTILATION,AIR CONDITIONING, |
|
GAS SUPPLY AND ILLUMINATION.............................................................................................. |
6 |
Mel'kumov V. N., Kitaev D. N. |
|
Mathematical Model of Convection Heat Transfer |
|
When Charging a Heat Accumulator of a Heat Supply System ................................................ |
6 |
TECHNOLOGY AND ORGANIZATION OF CONSTRUCTION ...................................................... |
17 |
Kudryavtsev P. G., Figovskii O. L. |
|
Organic Water-Soluble Silicates for Protective Coatings........................................................ |
17 |
TECHNOLOGY AND ORGANIZATION OF CONSTRUCTION ....................................................... |
32 |
Tkachenko A. N., Kazakov D. A., Mershchiev A. A. |
|
Quality Assurance in the Construction of Oil and Gas Facilities ............................................ |
32 |
DESIGNING AND CONSTRUCTION OF ROADS,SUBWAYS, |
|
AIRFIELDS,BRIDGES AND TRANSPORT TUNNELS................................................................... |
43 |
Boyko C. A., Kalgin Yu. I., Strokin A. S. |
|
Development of Stone Mastic Asphalt Mixtures With Enhanced Workability for Installation |
|
and Repair of Road Surfaces.................................................................................................... |
43 |
ENVIRONMENTAL SAFETY OF CONSTRUCTION AND MUNICIPAL SERVICES ......................... |
50 |
Slavinskaya G. V., Kurenkova O. V. |
|
The Influence of Reaction Medium on the Effectiveness of Sorptive Water Purification |
|
From Natural and Synthetic Surfactants Anionitami............................................................... |
50 |
CITY PLANNING,PLANNING OF VILLAGE SETTLEMENTS...................................................... |
66 |
Bol’shakov A. G. |
|
Space Topology of the Belgorod City...................................................................................... |
66 |
Men'shikova Ye. P. |
|
Approaches to the Master Plan as a Comprehensive Strategic Document .............................. |
80 |
FIRE AND INDUSTRIAL SAFETY (CIVIL ENGINEERING).......................................................... |
89 |
Kolodyazhnyi S. A., Puzach S. V., Kozlov V. A., Kolosova N. V. |
|
Improved Calculation of Mass Consumption of a Gas Mix Released During Fire in Premises.... |
89 |
INSTRUCTIONS TO AUTHORS................................................................................................. |
102 |
5
Russian Journal of Building Construction and Architecture
HEAT AND GAS SUPPLY,VENTILATION,AIR CONDITIONING,
GAS SUPPLY AND ILLUMINATION
UDC 697.328
V. N. Mel'kumov1, D. N. Kitaev2
MATHEMATICAL MODEL OF CONVECTION HEAT TRANSFER WHEN CHARGING A HEAT ACCUMULATOR OF A HEAT SUPPLY SYSTEM
Voronezh State Technical University
Russia, Voronezh, tel.: (473) 271-53-21, e-mail: teplosnab_kaf@vgasu.vrn.ru, e-mail: dim.kit@rambler.ru 1D. Sc. in Engineering, Prof., Head. of the Dept. of Heat Supply and Oil and Gas Business
2PhD in Engineering, Assoc. Prof. of the Dept. of Heat Supply and Oil and Gas Business
Statement of the problem. Currently in order to improve the reliability of heat supply technologies of small energy sources are being implemented, e.g., small heating plant based on internal combustion engines. The thermal energy in such installations is mainly produced by utilizing the waste heat of outflow smoke gases having a high temperature and thus heating the water in the tank. It is important to search for the most adequate mathematical models allowing one to determine the time of heating of a coolant in tank-accumulators.
Results and conclusions. Mathematical models of unsteady processes of charging a storage tank used in a heating system are obtained. By means of identifying the models based on the minimization of the functional Gauss implemented in the algorithms, the most appropriate mathematical model was established. A simplified mathematical model of the charging process of a storage tank was obtained allowing one to determine the water temperature with an error of less than 8 %. Based on mathematical modeling, analytical dependences for determining the temperature of a heat carrier at the inlet and outlet of the storage tank are identified.
Keywords: heating, storage tank, heat transfer.
Introduction
One of Russia’s top priorities is to improve its central heating system but their performance has to be improved by means of utilizing non-conventional energy sources [18]. One of the promising technologies to employ in energy supply are thermal power stations that cater for heat and energy demands.
© Mel’kumov V. N., Kitaev D. N., 2017
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Issue № 3 (35), 2017 |
ISSN 2542-0526 |
These stations have the capacity from several kilowatts to dozens of megawatts [5] making their application range extremely wide. There is currently data available on how they are being implemented [6], but there are no reliable mathematical models to allow the temperatures of heat-carriers to be calculated over the operation time. An important issue is controlling the capacity of these stations in order to maintain the temperature modes within thermal networks [4, 7—9]. It becomes necessary to regard a mathematical model of charging a heat accumulator in the context of the operation in heat supply systems. Installing this kind of a device allows the daily hot water consumption to be more even.
1. Mathematical model of water heating using smoke gas
Water is heated by means of contact of smoke gas with the wall of the pipes of a heat exchanger operating in the cross mode (Fig. 1). Due to a difference in the temperatures and thus water density natural convection occurs. While circulating continuously, the water gradually heats up to a necessary temperature (95 °С). The convection rate u is not known beforehand.
Storage tank
Smoke gas
Fig. 1. Scheme of charging of the heat accumulator
Using the methods of engineering hydraulics [1] considering the movement mode (the Reynolds number) a maximum possible rate of a natural movement of water in a heat transfer pipe was determined. It is umax = 0.424 m/sec.
Let us write a mathematical model of heating water in the pipe whose side surface is thermally insulated and in the lower original part the heat is supplied from the smoke gas. At some point in time the rate of the outlet water flow in the pipe u can be assumed to be constant. The equation of heat conductivity is as follows
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Russian Journal of Building Construction and Architecture
where T is the temperature, ºС; τ is the time, с; а is the coefficient of heat conductivity, m2/seс; u is the rate of water, m/seс.
It is assumed that due to a small diameter of the pipe the temperature along the entire section is distributed evenly.
Let us introduce the following initial and boundary conditions for solving the equation (1). Counting the temperatures from Т0, the initial condition is as follows
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At the top end of the pipe х = l the heat is transferred into the environment according to the Newton-Richman law (in the tank) with the coefficient of heat conductivity α:
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where α is the coefficient of heat conductivity, J/(m2·sec); is the coefficient of heat conductivity of water J/(m·sec).
At the lower end of the pipe the water gets the heat from the smoke gas.
Due to an uncertainty the following options for the boundary conditions [19] for х = 0 and х = l were considered:
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where Т00 is an unknown temperature of the wall of the pipe for х = 0.
The analytical solution of the equation (1) using the boundary and initial conditions (2) was obtained by means of Fourier’s method (dividing the variables):
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Issue № 3 (35), 2017 |
ISSN 2542-0526 |
where n are positive roots of the resulting characteristic equation such as |
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N u / n , |
(5) |
where Nu |
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As seen from Formula (4), the calculation value Т(l, τ) depends on three parameters: T00, Nu and u.
2. Identification of mathematical models
The resulting model should be identified, i.e. such numerical values of its parameters should be determined so that the models would be in good agreement with the empirical data [15, 16]. The structural scheme of the calculation of the identification of the model is given in Fig. 2.
Block 1. Introducing the original data: the initial temperature Т0; the coordinate х where the temperatures were measured at different points in time; the empirical time range τ(j) and a corresponding empirical temperature range Топ (j); the values of the parameters of the model: the convection rate u, the Nusselt number Nu, the temperature Т00.
Block 2. The solution for the specified Nusselt number Nu of the characteristic equation (5) using the algorithm (9)—(10).
Block 3. Calculating the temperature Т(l, τ(j)) for each point in time τ(j) using the calculation scheme (4).
Block 4. Calculating the efficiency criterion, i.e. the Gaussian function that corresponds with the values of the parameters of the model u, Nu, T00.
Block 5. Minimizing the Gaussian function by combining the methods of coordinate and shortest descend that includes planning the calculational experiment; going back to Block 1 to change the numerical value of the parameters u, Nu, T00; switching to Block 6 as soon as the minimum value is achieved [12, 14].
Block 6. Comparing the optimal value of the Gaussian function with a dispersion of the reproducibility using the Fisher statistical criterion [20]. Introducing the mathematical model, i.e. identifying numerical values of the parameters u, Nu, T00, in case of efficiency. Switching to Block 7.
Block 7. Printing the optimal values u, Nu, T00 and calculation values of the temperatures Т(х, τ(j)). Abandoning the mathematical model in case it is not efficient.
In order to identify the roots μn we use Newton’s iteration [10]:
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Russian Journal of Building Construction and Architecture
where using g and g' the following functions are denoted g стn tg стn Nu
and its derivative
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Block 1. Initial data
T0, x, τ(j), Tоп (j), u, Nu, T00
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Block 3. Calculating
T x, j
Block 4. Calculating the efficiency criterion Ф (11)
Block 5. Minimizing the efficiency criterion Ф
no
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Block 6. Testing the effi- |
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print end
Fig. 2. Structural scheme of the identification of the mathematical model
(7)
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