ON IMPROVING THE ENERGY SUPPLY OF BATCH DYEING APPARATUSES IN THE LIGHT INDUSTRY ENTERPRISES

The paper offers the results of pinch analysis, thermodynamic analysis based on exergy method that determine the energy-supply efficacy enhancement variants for the processing equipment in the light industry finishing production as exemplified by the apparatuses of batch operation for textile dyeing. Scientifically substantiated improvement feasibility estimation for the Belarusian light industry enterprises thermo-technological production energy supply is of current concern and in demand in the existing economic situation. Exergy method allows obtaining the indicated estimation by the simplest and most logical way as against the other methods of thermodynamic analysis e.g. entropy method or employing the cycle theory. Pinch analysis employment not only allows verifying the estimation results but also points out the problem spots demanding cardinal changes and modernization. This complex approach renders possible outlining simple ways of energy saving in the existing technical systems of substance transformation, which is important under the conditions of operating production for successful handling the problem of lowering production costs. The example of the most widespread thermo-technological production of the light industry illustrates the above stated. For most enterprises of the republic, it remains problematic in many ways. The suggested ways of solving the problem are not exhaustive and offer evolutionary changes that secure economic indicators fitting the dictates of time and the enterprises capabilities. Another critical factor of the presented analysis and ways for thermo-technological energy supply improvement is that the proposed changes can realize on basis of the equipment that established a good reputation during continuous service in different productions and manufactured in the republic in working partnership with foreign design engineers. 

1. Romaniuk V. N., Muslina, D. B. (2015) Exergy of Textile Materials. Energetika. Izvestyia vysshikh uchebnykh zavedenii i energeticheskikh ob"edinenii SNG. [Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations.], (3), 46–59 (in Russian).

2. Romaniuk V. N., Muslina, D. B. (2015) Forecasting of Production Output for Light Industry Enterprises with Purpose to Determine their Power Resources Requirements. P. 1. Nauka i Tekhnika [Science and Technique], (4.), 66–76 (in Russian).

3. Romaniuk V. N., Muslina, D. B. (2015) Forecasting of Production Output for Light Industry Enterprises with Purpose to Determine their Power Resources Requirements. P. 2. Nauka i Tekhnika [Science and Technique], (5), 63–75 (in Russian).

4. Romaniuk, V. N. On the Issue of Increasing Energy Supply Efficiency of the lines of continuous dyeing in the Light Industry Enterprises / V. N. Romaniuk, D. B. Muslina // Energy and Management. 2015. No 4 (73). P. 4–9. (in Russian)

5. Romaniuk V. N., Muslina, D. B. (2015) Energy Recovery for Continuous Dyeing Process in Textile Industry Enterprises. Energetika. Izvestyia vysshikh uchebnykh zavedenii i energeticheskikh ob"edinenii SNG. [Energetika. Proceedings of CIS Higher Education Institutions and Power Engineering Associations.], 6, 46–59 (in Russian).

6. Hasanbeigi A., Price L. (2012) A Review of Energy Use and Energy Efficiency Technologies for the Textile Industry. Renewable and Sustainable Energy Reviews, 16 (6), 3648–3665. DOI: 10.1016/j.rser.2012.03.029

7. Pulat E., Etemoglu A. B., Can M. (2009) Waste-Heat Recovery Potential in Turkish Textile Industry: a Case Study for City of Bursa. Renewable and Sustainable Energy Reviews, 13 (3). P. 663–672. DOI: 10.1016/j.rser.2007.10.002

8. Ozturk H. K. (2005) Energy Usage and Cost in Textile Industry: a Case Study for Turkey. Energy, 30 (13) 2424–2446. DOI: 10.1016/j.energy.2004.11.014

9. Brodyanskiy V. M., Sorin M. V. (1985) Efficiency Factor Calculation Principles of the Energy-and-Matter Conversion Engineering Systems. Izv. vuzov. Energetika [Higher Educational Institutions News. Energetika], (1), 60–65 (in Russian).

10. Sorin M. V., Brodyanskiy V. M. (1985) Unambiguous Determination Technique for the Exergetic Efficiency of Energy-and-Matter Conversion Engineering Systems. Izv. vuzov. Energetika [Higher Educational Institutions News. Energetika], (3), 78–88 (in Russian).

11. Choudhury A. Roy. (2006) Textile Preparation and Dyeing. Enfield, Science Publishers. 834 p.

12. Lewis David M., Rippon John A. (2013) The Coloration of Wool and Other Keratin Fibres. Bradford, Wiley. 439 ?.

13. Duff D., Sinclair R. (1989) Giles’s Laboratory Course in Dyeing. 4th ed. Bradford, Society of Dyers and Colourists. 167 ?.

14. Johnson A. (1989) The Theory of Coloration of Textiles. 2th. ed. Bradford, Society of Dyers and Colourists. 552p.

15. Energy Performance: Benchmarking and Best Practices in Canadian Textiles Wet Processing. Natural Resources Canada. Available at: http://oee.nrcan.gc.ca/industrial/technical-info/benchmarking/textiles-wet-processing/10728. (accessed 05.10.2013).

16. Schonberger H., Schafer, T. (2003) Best Available Techniques in Textile Industry / H. Schonberger. Berlin: Federal Environmental Agency (Umweltbundesamt). Available at: http://www.umweltbundesamt.de/publikationen/best-available-techniques-in-textile-industry. (accessed 05.06.2014).

17. Melnikov B. N., Vinogradova G. I. (1986) Colouring Agent Application. Moscow, Chemistry. 240 p. (in Russian)

18. Löffler M. K. (2015) Trapezoid Vapour Compression Heat Pump Cycles and Pinch Point Analysis. International Journal of Refrigeration, 54, 142–150. DOI: 10.1016/j.ijrefrig.2015.03.003

19. Gadalla M. A. (2015) A New Graphical Method for Pinch Analysis Applications: Heat Exchanger Network Retrofit and Energy Integration. Energy, 81, 159–174. DOI: 10.1016/j.energy.2014.12.011

20. Gadalla M. A. (2015) A Novel Graphical Technique for Pinch Analysis Applications: Energy Targets and Grassroots Design. Energy Conversion and Managemen, 96, 499–510. DOI: 10.1016/j.enconman.2015.02.079

21. Kemp Ian C. (2007) Pinch Analysis and Process Integration: a User Guide on Process Integration for the Efficient Use of Energy. 4th ed. Elsevier Science. 415 p.

22. Brodyanskiy V. M., Fratsher V., Mikhalek K. (1998) Exergy Method and its Applications. Moscow, Energoatomizdat. 288 p. (in Russian).

23. Kluchnikov A. D. (2001) Prerequisites for Work Efficiency Radical Increase in the Area of Energy Saving. Promyshlennaia energetika [Industrial Power Economy], (4), 12-17 (in Russian).

24. Romaniuk V. N. (2010) Intensivnoe energosberezhenie v teplotekhnologicheskikh sistemakh promyshlennogo proizvodstva stroitel'nykh materialov. Dis. d-ra. tekhn. nauk [Intensive Energy Saving in Heat-Technological Systems of Industrial Production of the Building Materials. Dr. tech. sci. diss.]. Minsk. 365 p. (in Russian).