EUREKA: Physics and Engineering.

The article describes methods to intensify the processes of biodegradation. The results of the investigations of waste biodegradation process modeling of waste and the intensification of these processes are given. Generalized mathematical model of emission of biogas at the landfill is developed and methods of process intensification in the body of the landfill are proved. As a result of research, microbiological and biochemical processes in the body of the landfill are analyzed, the main factors affecting the intensity of the processes are revealed and their impact is analyzed. It was concluded that the landfill is a biochemical reactor, where interrelated heat and mass transfer processes occur in the dense bed through which the gas is filtered and internal sources of heat. It was developed a complete mathematical model allowing estimating based on the equations of material and heat balances, the rate of biogas reactor. A model and calculation method for the analysis of heat and mass transfer processes in a dense bed with internal heat sources and to calculate the emission of biogas at design and operation of the landfill-reactor were given. Possible ways of intensifying the process of biodegradation in the reactor were revealed on the basis of analysis of the equations of the mathematical model describing the process in the reactor and the theory of microbiological processes of this class.

. Bondar, O. I., Horokh, M. P., Korinko, I. V. (2005). Utylizatsiia ta rekuperatsiia vidkhodiv, 459.

. Hrynyn, A. S., Novykov, V. N. (2002). Promishlennie y bitovie otkhodi (khranenye, utylyzatsyia, pererabotka), 200.

. Beyer, Christoph, Pretz, Thomas (2001). Zaiavka 19851361 Hermanyia. Vertahren zur verrottung von Yaus. Sposob obrabotky musora. Gewerbe und Sperrmull MPK V 9/06. Eu Rec Technology GmbH En-tsorgun gsanlagen.

. Modellierung und simulation von Aufbere itungsprozessen zur Verwertung von Abfallen. (2001). Wasserwirt, Abwasser, Abfall, 48, 10, 1452–1454.

. Kostendampfungspotentiale inder kommunalen Abfallwirtschaft. (2000). Galvanotechnik,

, 7, 2029.

. Hosudarstvennie stroytelnie normi Ukrayni. (2005). Hosudarstvennii komitet Ukrayni po stroy-telstvu y arkhytekture. Proektyrovanye. Polyhoni tverdikh bitovikh otkhodov. Osnovnie polozhennia

DBN, 2, 4–2.

. Pan, L. R. (1999). Ekolohyia y tekhnolohycheskye protsessi sovremennikh metodov pererabotky tverdikh bitovikh otkhodov. Sb. statei Lab. byoheokhym. otsenok zahriazn. okruzhaiushchei sredы. Ynst. vodn. эkol. problem. DVO RAN, 9, 52–68.

. Kasymov, A. M., Semenov, V. T., Kovalenko, A. M., Aleksandrov, A. M. (2006). Tverdie bitovie ot-khodi. Tekhnolohyia, oborudovanye. Problemi y reshenyia, 301.

. Predlozhenyia po sozdanyiu systemi upravlenyia otkhodamy vh. Kharkove y Kharkovskoi

oblasty, 20.

. Lapunov, Y. N., Rezynskykh, N. A. (2007). Obosnovanye effektyvnoi tekhnolohy upravlenyia tverdimy bitovimy otkhodamy. Materyali IV Mezhdunarodnoi konferentsyy «Sotrudnychestvo dlia reshenyia problemi otkhodov, 202−203.

. Adamchuk, B. Y., Zynchenko, M. H., Lopukhyna, O. A., Shaporev, V. P. (2006). Sovremennii podkhod y perspektyvi sozdanyia эkolohychesky bezopasnikh khranylyshch dlia deponyrovanyia tverdikh bitovikh otkhodov, byolohycheskoi pererabotky y utylyzatsyy byohaza. Vostochno-Evropeiskyi zhurnal peredovikh tekhnolohyi, 2/2 (20), 172−177.

. Adamchuk, B. Y., Smetaniuk, E. K., Bohlaenko, D. V., Shaporev, V. P. (2007). Obosnovanye effektyvnoi tekhnolohy upravlenyia tverdimy bitovimy otkhodamy. Vestnyk NTU «KhPY», 8, 63−72

. Krasnianskyi, M. E., Belhasem, A., Kalynykhyn, O. N. (2004). Svalka kak byokhymycheskyi reaktor. Obshchaia teoriia. Voprosi khymyyy y khymycheskoi tekhnolohyy. Sb. nauchn. Trudov

DonNTU, 1, 85 − 89.

. Sposob proyzvodstva эnerhyy yz bitovikh otkhodov (2000). Aus Mull wird Energie.

Chem. Ing. Techn, 72, 1−2, 40.

. Hrytsenko, A. V., Horokh, N. P., Vnukova, N. V., Korynko, Y. V. (2005). Tekhnolohycheskye os-novi promishlennoi pererabotky otkhodov mehapolisa, 334.

. Shaporev, V. P., Zhaber, M. A., Kanso, V. A., Shaporev, P. V. (2005). Metodi, tekhnolohy y kontseptsyy utylyzatsyy tverdikh bitovikh otkhodov (TBO) y osadkov stochnikh vod (OSV), obrazovannikh pry byolohycheskoi ochystke. Vestnyk NTU «KhPY», 14, 3−30.

. Matveev, Yu. B., Pukhniuk, A. Yu. (2007). Metodi y opyt otsenky hazoobrazovanyia na ukraynskykh polyhonakh. TBO Materyali IV Mezhdunarodnoi konferentsyy «Sotrudnychestvo dlia reshenyia problemi otkhodov», 198−200.

. Maksymova, S. V., Hlushankov, Y. S., Vaisman, O. Ya. (2003). Modelyrovanye protsessov obra-zovanyia byohaza na polyhonakh tverdikh bitovikh otkhodov. Ynzhenernaia ekolohiia, 4, 32−40.

. Barlaz, M. A., Ham, R. R. (1987). Measurement and prediction of landfill gas quality and quantity. ISWA International sanitary landfill symposium, 8, 1−23.

. Kafarov, V. V. (1985). Metodi kybernetyky v khymyy y khymycheskoi tekhnolohyy, 448.

. Pichler, Martin, Rnicker, Heike. (2000). Changes in the chemical structure of municipal solid waste during composting as studied by solid-state dipolar dephasing and PSRe 13C NMR and solid-state 15N NMR spectroscopy. Kogel-Khabner Ingrid. Environ, Sci and Technol, 34, 18, 4034−4038.

. Smyrnova, T. N. (1989). Oborudovanye dlia yzmelchenyia y hranuliatsyy otkhodov y plastmass. Ser. Khym. prom. Za rubezhem, 2 (314), 36−48.