WATER BALANCE AT PLANTS IN TECHNOLOGICAL SOLUTIONS ENGINEERING

Array

Authors

  • O. Galkina O.M. Beketov National University of Urban Economy in Kharkiv
  • M. Degtyar O.M. Beketov National University of Urban Economy in Kharkiv

Keywords:

phenolic water-circulation systems, coke plants, water management, water balance

Abstract

In this paper questions and conditions of water management in the water-circulation systems taking into account water losses on the example of the coke-chemical plant are considered. The water balance of the primary gas refrigerators cycle at the Kharkiv coke plant has been calculated and compiled, taking into account the proposed technological solutions. As a result of the operation of the water-circulation systems, it was found that the water loss for evaporation at the Kharkiv Coke Plant is on average 2% in winter and 3% in summer. Water losses in the system are replenished with fresh technical water and purified phenolic wastewater. Technical appraisal of the work of heat-exchange equipment at coke plants is carried out consists of replacing part of fresh technical water with phenolic wastewater and minimizing wastewater discharges. The purpose of the project is to create conditions for the water re-use by coke-chemical plants and to predict its water balance depending on the technological decisions made. Thus, the purge of the system is 5.6 m3/hour, while the total irreparable water loss in the system is 9.4 m3/hour. In the article it is established that the application of the proposed technical solutions allows to reduce the amount of discharge of sewage into urban sewer network at 36 000 m3/year and consumption of fresh industrial water to 52 000 m3/year, and increase the service life of equipment from 6.5 to 8 years. These measures help to improve water and environmental situation, effective water management of the coke-plant, that is, to decrease the payment made for consumption of water resources and sewage plant. The presented water balance and calculations of losses of water in the reverse water supply system of the enterprise are executed prove positive effect from the proposed technology solutions.

Author Biographies

O. Galkina, O.M. Beketov National University of Urban Economy in Kharkiv

Ph.D., Associate Professor

M. Degtyar, O.M. Beketov National University of Urban Economy in Kharkiv

Ph.D., Associate Professor

References

Airapetian, T. S. (2009). Vodne hospodarstvo promyslo-vykh pidpryiemstv (Water management of industrial enterprises): Navchalnyi posibnyk. 280 р.

Adamenko, M. I., & Kuchuk, N. G. (2014). Theoretical basis of environmental balancе. Bulletin of Lviv State University of Life Safety, 10, 158-162.

Galkina, O. P., & Shevchenko, T. O. (2018). Otsiniuvannia efektyvnosti roboty teploobminnoho obladnannia system oborotnoho vodopostachannia koksokhimichnykh pidpryiemstv (Estimation of efficiency of work of heat exchange equipment of water-circulating systems of coke-chemical plants). Komunalne hospodarstvo mist. Seriia: Tekhnichni nauky ta arkhitektura, (7), 257-263.

Galkina, O. P., & Dehtiar, M. V. (2019). Tekhnolohii ochyshchennia fenolnykh stichnykh vod (Technologies of penole waste water treatment). Ekolohiia i vyrobnytstvo, 5, 32-36. С. 32-36.

Horban, N. S., Khvat, V. M., & Khvat, A. V. (2010). Zmenshennia nehatyvnoho vplyvu doshchovykh stichnykh vod na vodni obiekty shliakhom kontroliu ta upravlinnia nakopychenniam tverdykh chastok na poverkhni miskykh vodozboriv (Reducing the negative impact of rainwater on water bodies by controlling and controlling the accumulation of solids on the surface of urban catchments). Эkolohyia y promishlennost, (4), 57-63.

Selytskyi, H. A., Ulasovets, E. A., & Ermakov, D. V. (2008). Tekhnolohyia ochystky promishlennikh y lyvnevikh stochnikh vod dlia yspolzovanyia v oborotnoi systeme vodos-nabzhenyia hornometallurhycheskoho predpryiatyia (Technolo-gy of purification of industrial and storm sewage for use in the circulating water supply system of a mining and metallurgical enterprise). Vodosnabzhenye i kanalyzatsyia : ot redaktsiy, 51-58.

Hartwick, D. (2001) Water Treatment In Closed Systems. ASHRAE Journal, February, 30–38.

McNeill, L. S., & Edwards, M. (2002). The importance of temperature in assessing iron pipe corrosion in water distribu-tion systems. Environmental Monitoring and Assessment, 77(3), 229-242.

Mokhtari, S. A., Aalighadri, M., Hazrati, S., Sadeghi, H., Gharari, N., & Ghorbani, L. (2010). Evaluation of corrosion and precipitation potential in Ardebil drinking water distribution system by using Langelier & Ryznar indexes. Journal of health, 1(1), 14-23.

Kucherenko, D.I., & Gladkov, V.A. (1980). Oborotnoe vodosnabzhenie (Sistemy vodyanogo okhlazhdeniya) (Water-Circulation Systems for Industrial Cooling), Moscow: Stroiizdat, 1980.

Nesterenko, S. V., Tkachev, V. A., Smilka, E. P. (2013) Reducing the Corrosion Losses of Metals when Using Phenolic Wastewater in Coke-Plant Cooling Systems. Coke and Chemistry, 56, 8, 286–291.

Nesterenko, S. V., Smіlka, O. P., Grigorov V. І. , Kancedal, L. D., Bannіkov, L. P. & Tkachov V. O. (2015). Kompozicіya dlya zapobіgannya korozії metalіv v oborotnih sistemah ta sposіb utilіzacії stіchnih vod promislovih pіdpriєmstv, yakі mіstyat' amonіjnij azot. Pat. 109035 Ukrane C 23 F 11/18, C 02 F 1/50, 13.

Rozhkov, V. S. (2008). Vikoristannya bіologіchno ochishchenih stіchnih vod u sistemah oborotnogo vodopostachannya koksohіmіchnih pіdpriєmstv. Avtoreferat dis. kand. tekhn. nauk, pp. 14.

Bal'cer, D. V, Pavlovich, L. B. (2012). Ispol'zovanie ochishchennyh fenol'nyh stochnyh vod v vodosnabzhenii koksohimicheskogo proizvodstva. Vodosnabzhenie i sanitarnaya tekhnika, 12, 52–58.

Galkina, E. P. (2016). Racional'noe ispol'zovanie zamknutyh sistem vodosnabzheniya koksohimicheskih predpriyatij i oborotnyh ciklov ih vodosnabzheniya. Resursosberezhenie i ehnergo-ehffektivnost' inzhenernoj infrastruktury urbanizirovannyh territorij i promyshlennyh predpriyatij : II mezhdunar. nauch.-tekhn. konf., 2–27 fevralya, 18–20.

Published

2020-04-03

How to Cite

Galkina, O., & Degtyar, M. (2020). WATER BALANCE AT PLANTS IN TECHNOLOGICAL SOLUTIONS ENGINEERING : Array. Municipal Economy of Cities, 1(154), 148–153. Retrieved from https://khg.kname.edu.ua/index.php/khg/article/view/5546