Your search keyword '"Michal Holubčík"' showing total 45 results

1. Editorial: Environmental impacts from small heating systems

Author

Michal Holubčík, Dagmar Cagáňová, and Jozef Jandačka

Subjects

heat source, biomass, particulate matter, solid fuels, smart technologies, household, General Works

Published

2024

2. Health risks connected with energy disposal of pandemic waste

Author

Nikola Čajová Kantová, Robert Cibula, Michal Holubčík, and Peter Ďurčanský

Subjects

Disposal of masks, Waste utilization, COVID-19, Particulate matter, Emissions, Mass concentration, Science (General), Q1-390, Social sciences (General), H1-99

Abstract

Enormous amount of protective masks was consumed in connection with the COVID-19 pandemic and they still burden the environment. Therefore, it is necessary to look for possibilities of their disposal in an ecologically acceptable way. This article focuses on particulate matter produced concerning the energy disposal of pandemic FFP2 masks. These masks were processed into small pieces, added to spruce and beech wood (in the weight proportion 5 % and 10 % of FFP2 masks) and formed into pellets. The concentration of particulate matter formed during their combustion was measured by the gravimetric method. The inorganic elements were detected from filters with captured particulate matter by an energy-dispersive X-ray fluorescence spectrometer and verified by inductively coupled plasma-optical emission spectroscopy. It was found that higher concentrations of particulate matter were recorded predominantly with a higher mass airflow. In both airflows (40 % and 50 %), beech pellets had a higher mass concentration than spruce pellets probably caused by the presence of bark in beech wood. Based on the chemical composition, the following elements in small amounts (0–2 mg on a filter) were identified: K, S, Cl and Fe. High concentrations of harmful elements carried in particulate matter have not been detected. FFP2 masks added in a small percentage (up to 10 %) can be used in wood pellets for combustion purposes without significantly affecting the combustion process.

Published

2024

3. Comparison of Energy Properties of Pellets from Different Species of Nut Shells

Author

Juraj Trnka, Nikola Čajová Kantová, Michal Holubčík, Alexander Čaja, Tomáš Najser, and Jan Najser

Subjects

biomass residual, biowaste pellets, energy recovery, nut shells, pellet analysis, Biotechnology, TP248.13-248.65

Abstract

Bio-waste is a source of energy-rich material. Therefore, it can be used in further processes and efficiently utilized. Further processes of waste utilization include compressing them to pellets. However, this type of pellet often has a low bulk density, high ash content, low ash melting temperature, and low calorific value. This research dealt with the energy properties of peanut and pistachio nut shells that were pure or mixed with spruce sawdust in half proportion and compressed into pellets. As a continuation of previous research, the properties of these pellets prepared were measured and compared with pure spruce pellets and with pellets from walnut shells. The tested shell pellets had calorific values similar to wood pellets from spruce. However, mixing nut shells with spruce solved the problems of high ash content and low ash melting temperatures. The amount of wood present in the pellets resulted in increased ash melting temperatures and decreased the ash content.

Published

2023

4. Enhancing Small Heat Source Performance through Gravitational Loop Heat Pipes

Author

Lucia Martvoňová, Milan Malcho, Jozef Jandačka, Peter Ďurčanský, Michal Holubčík, Július Drozda, and Martin Adamička

Subjects

gravitational loop heat pipe, gas fireplace insert, waste heat recovery, combustion air preheating, thermal management, efficiency enhancement, Mechanical engineering and machinery, TJ1-1570

Abstract

This experimental study aimed to validate the integration of a gravitational loop heat pipe (GLHP) with respect to a gas fireplace insert. The GLHP was utilized to enhance the efficiency of the fireplace by preheating the combustion air with waste heat from flue gases. The experiment involved monitoring key parameters such as vapor and condensate temperatures and absolute pressure within the LHP. The results demonstrated that a filling volume of 0.1 L of water in the LHP allowed for successful operation, while exceeding 0.2 L resulted in flooding and decreased system efficiency. Challenges related to vapor production and condensate return were identified, suggesting the need for further research and design improvements. The experimental verification confirmed the feasibility of implementing the gravitational LHP in a gas fireplace insert and emphasized the importance of optimizing vapor production and condensate return mechanisms. This study contributes to the advancement of thermal management strategies and provides valuable insights for enhancing the design and performance of such systems.

Published

2023

5. Application of Particle Image Velocimetry and Computational Fluid Dynamics Methods for Analysis of Natural Convection over a Horizontal Heating Source

Author

Natália Holešová, Richard Lenhard, Katarína Kaduchová, and Michal Holubčík

Subjects

natural convection, numerical simulation, PIV method, CFD method, heating source, Technology

Abstract

The objective of this article is to address the challenges associated with visualizing air flow over a heating source in an open laboratory environment. The study uses a combination of experimental visualization and numerical simulation techniques to generate a 3D model of the air flow and heat transfer between the heating source and the environment via natural convection. The Particle Image Velocimetry method is used to experimentally visualize the air flow, which is known for its benefits of high speed and accuracy, and for its ability to avoid disturbing the flow of the fluid being investigated. The data obtained from this experimental method are used as input for numerical simulations using the Ansys Fluent program. The numerical simulations identify air vortices and other elements that disrupt the airflow in the laboratory environment. The resulting 3D model accurately represents the actual situation in the laboratory and could be further optimized by adjusting parameters such as the output of the heater and the heating source temperature. These parameters play a crucial role in ensuring thermal comfort in the laboratory environment, which is of utmost importance for user comfort. In conclusion, the study provides valuable insights into the visualization of air flow over a heating source and demonstrates the effectiveness of combining experimental and numerical simulation techniques to generate accurate 3D models of air flow and heat transfer.

Published

2023

6. Co-Combustion Investigation of Wood Pellets Blended with FFP2 Masks: Analysis of the Ash Melting Temperature

Author

Nikola Čajová Kantová, Michal Holubčík, Alexander Čaja, Juraj Trnka, Peter Hrabovský, and Pavol Belány

Subjects

COVID-19, disposal of masks, waste utilization, ash behavior, ash preparation, ash melting method, Plant ecology, QK900-989

Abstract

The COVID-19 pandemic brought a period of high consumption of protective masks and an increase in their waste. Therefore, it was necessary to look at possibilities for their disposal. This article is focused on the disposal of FFP2 masks in the form of pellets blended with sawdust. Further, their ash melting behavior was observed. The method of ash preparation can impact the resulting values of melting temperatures. Therefore, this article investigates the resulting values of ash melting temperatures determined during different ash preparations, such as temperatures (550 °C and 815 °C) and ash size (non-sifted, smaller than 50 µm and 100 µm). All measured deformation temperatures were higher than 1100 °C and even higher than 1200 °C for some samples. Moreover, the presence of FFP2 masks in pellets only insignificantly affected the values of melting temperatures compared to pure wood pellets. The measured values also showed that increasing the temperature of ash preparation from 550 to 815 °C can increase the resulting values of melting temperature. The most significant proportion of the fraction size on the resulting melting temperatures was observed for beech with 5% and 10% of masks at an ash temperature of 550 °C and for spruce with 10% of masks at an ash temperature of 815 °C.

Published

2023

7. The reduction of emission production of small heat-sources for solid-based fuels by applying control mechanisms

Author

Michal Holubčík, Jozef Jandačka, and Miriam Nicolanská

Subjects

emissions, heating systems, control mechanism, regulation, slovak republic, Science, Mathematics, QA1-939, Electronic computers. Computer science, QA75.5-76.95

Abstract

INTRODUCTION: Production of emissions from small heat sources burning solid fuels in households inSlovakia is relatively high. At the present time, the operation of such devices are neither controlled norregulated properly and effectively.OBJECTIVES: This work presents a research analysis of current monitoring and maintenance procedures and certified norms for all solid-fuel small-scale heating systems utilized in households.METHODS: The research compared data from over 13 countries in the European Union, evaluatinginformation regarding certified emission limits, efficiency levels, normalized monitoring procedures for both, fuel standards and heating system performance. A proposition is therefore presented for a new monitoring and inspection guide for solid-fuel heating systems in Slovak Republic households, where regulations, such as Ecodesign or the EN 305-5, were integrated.RESULTS: Using a mathematical-statistical model, the implementation of the proposed regulations brings an emission saving of almost 140 tons per 10,000 inhabitants for both central and local heating systems.CONCLUSION: The study demonstrated substantial opportunity in decreasing operation cost, prolongationof product lifetime, and last but not least, the reduction of health risks of local citizens.

Published

2022

8. Analysis of Ash Melting Temperatures of Agricultural Pellets Detected during Different Conditions

Author

Nikola Čajová Kantová, Michal Holubčík, Juraj Trnka, and Alexander Čaja

Subjects

ash melting temperature, ash fusion temperature, ash sintering, biomass, combustion, oxidizing conditions, Physics, QC1-999

Abstract

Agricultural and other residues are promising renewable energy sources. However, they can cause problems in combustion processes. One of these problems is also low ash melting temperatures. Except, the ash melting behavior can be impacted by many factors, such as ash preparation or used atmosphere. This article deals with comparing different atmosphere conditions during measurements of ash melting temperatures of three agricultural pellets: alfalfa, straw, and hay. The first one was oxidizing with compressed air and nitrogen. The second atmosphere was reduced with the air purge, and the last was only reduced, consisting of 60% carbon monoxide and 40% carbon dioxide. Differences between individual atmospheres were none, up to 9.8%. The most significant differences have appeared between oxidizing and reducing atmospheres. In general, the oxidizing atmosphere presents a less expensive way. More attention should be paid to the use of oxidizing atmosphere for applications in heat sources mainly due to its similarity to the combustion process. However, it would be suitable to realize more comprehensive research regarding ash preparation in different ways and with using of different types of fuel.

Published

2023

9. PERFORMANCE POTENTIAL OF HEAT PUMP DRYING CYCLES

Author

Bystrík Červenka, Michal Holubčík, Milan Malcho, and Nikola Kantová

Subjects

heat pump, drying, drying rate, energy efficiency, Technology

Abstract

There are two thermodynamic models of the closed and vented heat pump drying process described in the paper. The models have been used for optimization of process design parameters with respect to drying rate and energy efficiency, respectively. The optimization was performed in points of parametric space defined by refrigerant and air flow rates. Results of the optimization shows the same maximal drying rate performance for closed cycle and both objective functions. There is higher potential of drying time reduction for vented cycle in comparison to closed cycle. Results of the optimization showed strong correlation of the MER parameter with refrigerant flow rate for both closed and vented heat pump drying cycle. There is same maximal MER value obtained for both MER and SMER optimized cycle parameters.

Published

2019

10. PER OPERATION OF THE AUTOMATIC HEAT SOURCE ON PELLETS WITH VARIOUS BURNER TYPES

Author

Michal Holubčík, Nikola Kantová, Juraj Trnka, and Jozef Jandačka

Subjects

heat source, wood pellets, burner, biomass, boiler, Technology

Abstract

One of the most important issues in choosing a heating system is the question: What kind of fuel can be burned in given heating system. Modern automatic solid fuel boilers are often specialized only on a narrow range of suitable pellet materials. Pellets from cheaper sources are also beginning to appear on the market. However, many burners are unable to burn these new types of pellets without significant burning problems. The article deals with the influence of the proper construction of the burner on the smoothness of the combustion process and the smooth operation of the combustion equipment. The results of the experiments document the continuity of the combustion plant in the combustion of less quality pellets containing bark using more modern combustion technologies. In fact, less quality pellets cause the formation of ash sinters which cause the continuous combustion process to be interrupted, resulting in fluctuations in equipment performance and the onset of thermal discomfort. The results showed no problem with burning even when making sinters, but also showed a fluctuation in performance and the need for manual control, especially when heating or clogging the supply pipe. They also showed significant damage to pellets in the worm feeder section. These problems, therefore, ultimately require further research to ensure complete, seamless operation.

Published

2019

11. Optimization of Discharging Electrodes of a Multi-Chamber Electrostatic Precipitator for Small Heat Sources

Author

Michal Holubčík, Juraj Drga, Nikola Čajová Kantová, Jan Najser, and Jaroslav Frantík

Subjects

particulate matter, electrostatic precipitator, reducing emissions, corona discharge, Meteorology. Climatology, QC851-999

Abstract

On the way to reducing emissions released into the atmosphere, there is an obstacle in the form of the emissions of solid pollutants produced by households, namely the burning of solid fuels in small heat sources. In this article, the authors deal with the development of a low-cost electrostatic precipitator, which would be able to significantly reduce the production of particulate matter. This is a tubular precipitator concept, which is enhanced by dividing the precipitation space into four chambers, each of which has an ionization electrode. With the investigated structural arrangement, it is possible to increase the size of the collection area without affecting the external dimensions of the separator. The essence of this article was to focus on the design of an ionization electrode, which, in addition to the function of a negative electrode, would also fulfill the function of a structural element of the proposed geometry. The work contains a technical design for the shape of the ionization electrode, which was subsequently examined using ANSYS Fluent software. The conditions under which a corona discharge will occur on the electrodes and how particulate matter is captured in the separation device were investigated with the help of simulations of the electric field intensity. According to the achieved simulation results, calculations were made for the theoretical efficiency of particle collection, which reached a value of approximately 78%.

Published

2022

12. Decreasing Solid Aerosols from Small Heat Sources Using the Optimized Electrostatic Precipitator

Author

Michal Holubčík, Nikola Čajová Kantová, Juraj Trnka, and Jozef Jandačka

Subjects

particulate matter, electrostatic precipitator, reducing emissions, solid aerosols, Meteorology. Climatology, QC851-999

Abstract

Air quality and air pollution are important issues, and thus it is necessary to look at possibilities for how to decrease emissions in the atmosphere affordably and effectively. This article focuses on solid aerosols, specifically particulate matter, and the design of a low-cost solution for their decrease in the atmosphere. The mass concentration of particulate matter with the proposed optimized electrostatic precipitator was measured and compared with measurement without its implementation. Based on the results, it can be concluded that the designed ESP type could catch approximately 71% of solid particles. However, the real ability to capture particulate matter could be expected to be approximately 50–60% due to possible clogging, irregular cleaning and maintenance under normal conditions. Further, the article deals with the application of the village model with this type of electrostatic precipitator in households. Based on this model, the production of particulate matter would be reduced from 12.24 t/year to 6.12 t/year considering 50% separation efficiency and to 5.25 t/year considering 60% separation efficiency by the application to all heat sources for burning solid fuels for all emission classes. However, the reduction in particulate matter would be lower in real conditions.

Published

2022

13. ENERGY RECOVERY OF BONE WASTE AS HEAT SOURCE

Author

Juraj Trnka, Jozef Jandačka, and Michal Holubčík

Subjects

bone wastes, incineration, ash content, Technology

Abstract

Modern food industry concerning meat producers produce high amounts of bone waste. Bones represent biggest portion of zoo-mass waste which must be destroyed for hygienically reasons. Bones also have long durability and it is taken long time to decomposing this material microbiologically. We already know way to destroy this waste by crushing and making meat and bone meal. However, feeding with meat-and-bone meal can cause animal diseases. Because of that we try to prove combustion as a suitable way to get rid of this waste. Everything can be cleansed by flames and combustion also release energy captured in bone tissue. This energy can be used as heat or transformed to electric current also. But the other side, bone burning also has its emission problems that this work is trying to solve.

Published

2019

14. Polymer Membranes for Enthalpy Exchangers

Author

Kamil Križo, Andrej Kapjor, and Michal Holubčík

Subjects

enthalpy exchanger, mass transfer, polymer membranes, water vapor diffusivity, Technology

Abstract

A membrane-based enthalpy exchanger is a device used for heat and humidity recovery in ventilated buildings. The energy-saving potential of such a device is dependent on the parameters responsible for heat and moisture recovery. The trend is toward composite membranes, which are custom produced, and their parameters can be adjusted for a given application; therefore, the diffusion and sorption characteristics of such membranes are unknown. In order to obtain the values of the water vapor diffusivity of three investigated handmade membranes, a serial resistance model using a Field and Laboratory Emission Cell (FLEC) is proposed. Experiments were conducted to identify the resistance in each step of the moisture transfer process to extract the moisture diffusivity in the membranes. The calculated moisture diffusivities in the membranes were 8.99 × 10−12 (m2/s) for the membranes from cellulose acetate, 1.9 × 10−10 (m2/s) for the microporous PE/PUR membranes, and 1.53 × 10−11 (m2/s) for the PET/PUR microfibrous membranes. The obtained membrane diffusivities were then used in the proposed effectiveness-NTU-based model of an exchanger with a cross-flow arrangement to predict performance under various operating conditions. The results show that the highest latent effectiveness was found for the exchanger core made from the PE/PUR membrane and the lowest was for the one with the PE/PUR membrane core.

Published

2022

15. Modular Spiral Heat Exchanger Thermal Modelling

Author

Bystrík Červenka, Michal Holubčík, Juraj Drga, and Milan Malcho

Subjects

spiral plate, heat exchanger, modular configuration, thermal model, effectiveness, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Spiral plate heat exchangers (SPHEs) are used in industrial applications due to their enhanced thermal performance and tolerance to a soiled stream. The coupling of several SPHEs in series might further improve performance in terms of the effectiveness parameter. In the present study, a compact connection of several SPHE modules is proposed and investigated. For this purpose, a numerical model for the prediction of the effectiveness parameter of a modular SPHE was developed. The model predicted a 2.9% increase in the maximal effectiveness for a two-module SPHE in comparison to a conventional single module SPHE. The temperature profiles of particular streams within the two-module SPHE were predicted. The improved thermal performance and compactness of the modular SPHE configuration observed is advantageous for space-constrained applications.

Published

2022

16. Design of a Low-Cost Electrostatic Precipitator to Reduce Particulate Matter Emissions from Small Heat Sources

Author

Juraj Drga, Michal Holubčík, Nikola Čajová Kantová, and Bystrík Červenka

Subjects

particulate matter, emissions, electrostatic precipitation, corona discharge, small heat sources, computational fluid dynamics, Technology

Abstract

Capturing particulate matter (PM) is an important issue due to the protection of human health and the quality of their life. This paper describes the innovation of an affordable particulate matter capture device for small heat sources to reduce particulate matter emissions. The design of two investigated variants of the device is based on the principle of a tubular electrostatic precipitator with one charging electrode placed in the chimney. The design of the precipitators is aimed at increasing the area of the collecting electrodes by elements dividing precipitation space, with a simultaneously increased number of charging electrodes. The influence of the elements’ application on the pressure drop and the gas flow velocity through the devices is analyzed by computational fluid dynamics (CFD). The work is further focused on the economic evaluation of precipitators and design adjustments for lower energy consumption. The achieved results show the right direction of efforts to improve the equipment designed to capture PM emissions.

Published

2022

17. Energy Consumption Depending on the Durability of Pellets Formed from Sawdust with an Admixture of FFP2 Masks

Author

Nikola Čajová Kantová, Pavol Belány, Michal Holubčík, and Alexander Čaja

Subjects

wood pellets, COVID-19, energy consumption, mechanical durability, particle density, Technology

Abstract

At present, we are still feeling the effects of the COVID-19 pandemic in connection with the huge amount of waste generated. However, the reuse of the produced waste in other processes requires energy consumption. This article deals with the reuse of face masks FFP2, which were added as an admixture to spruce or beech sawdust and then processed into pellets. During the production process of the pellets, energy consumption was measured and further converted to one ton of pellets, and also the consumption was reflected in the price of electricity. After storage, the mechanical durability and dimensions of the individual pellets were measured, and their density was calculated. Based on the results, it can be concluded that spruce pellets with 10% face masks FFP2 (consumption 747.41 kWh; durability 97.53%) and beech pellets with 5% face masks FFP2 (consumption 721.27 kWh; durability 97.38%) achieved higher values of mechanical durability and also consumed more energy than the remaining samples with lower values of durability without considering the sample with spruce sawdust and 5% FFP2 face masks (consumption 872.63 kWh; durability 91.68%). The production of spruce pellets with 5% FFP2 face masks was affected mainly by cold outside weather.

Published

2022

18. Analyses of Pellets Produced from Spruce Sawdust, Spruce Bark, and Pine Cones in Different Proportions

Author

Nikola Čajová Kantová, Michal Holubčík, Alexander Čaja, Juraj Trnka, and Jozef Jandačka

Subjects

biofuels, pellets, cones, energy properties, calorific value, ash, Technology

Abstract

A lot of residual biomass has energy value and can be used for further applications through suitable treatments, such as pelletization. This treatment can improve properties, mainly energy density, but can also lead to problems due to their low ash melting temperatures, high ash content, and the formation of harmful compounds during combustion. This article deals with the energy potential of pellets produced from spruce sawdust, spruce bark, and pine cones in different proportions. The impact of cone and bark contents on pellet properties was also observed. The energy properties of the produced pellets were measured, such as the contents of carbon, hydrogen, nitrogen, moisture, volatile, fixed carbon, and ash, as well as calorific values and ash melting temperatures. Based on the results, it can be concluded that the addition of pine cones and spruce bark to spruce sawdust mainly affected the contents of nitrogen and ash and melting temperatures. Despite this, all produced pellets met the standard EN ISO 17225-2 for the content of nitrogen, ash, and also lower calorific value at least B quality. However, only three pellet samples of five met this standard for A2 and B quality for ash melting behavior. Therefore, they present an alternative fuel with interesting energy potential.

Published

2022

19. Improvement of the Standard Chimney Electrostatic Precipitator by Dividing the Flue Gas Stream into a Larger Number of Pipes

Author

Juraj Trnka, Jozef Jandačka, and Michal Holubčík

Subjects

electrostatic precipitator, particulate matter, emissions reduction, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Combustion of biomass-based solid fuels is becoming increasingly popular, especially in small heat sources. A major problem in the combustion of biomass is the increased production of emissions and especially the solid component of PM particles. Currently, the most used solution to this problem is the application of electrostatic chimney separators, which innovations are discussed in our article. Two models of electrostatic precipitators were constructed in this work. The aim of this work was to compare the use of a standard single-pipe chimney electrostatic precipitator with a newer four-pipe variant. Eight measurements were performed on both devices with and without the use of an electrostatic precipitator, on the basis of which the separation efficiency was evaluated for both variants. The results of the measurements showed the initial value of the average PM production in the one-pipe variant decreased from 1012 to 416 mg.m−3 when using the separator, while in the use of the four-pipe variant it decreased from the starting value 342 to only 152 mg.m−3. These results show that the improvement of the classic single-pipe separator by increasing the number of tubes significantly reduced the production of PM emissions and increased the separation efficiency from 66 to 85%.

Published

2022

20. Dependence of the Flue Gas Flow on the Setting of the Separation Baffle in the Flue Gas Tract

Author

Nikola Čajová Kantová, Alexander Čaja, Marek Patsch, Michal Holubčík, and Peter Ďurčanský

Subjects

particulate matter (PM), reducing emissions, computational fluid dynamics (CFD), particle imaging velocimetry (PIV), Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

With the combustion of solid fuels, emissions such as particulate matter are also formed, which have a negative impact on human health. Reducing their amount in the air can be achieved by optimizing the combustion process as well as the flue gas flow. This article aims to optimize the flue gas tract using separation baffles. This design can make it possible to capture particulate matter by using three baffles and prevent it from escaping into the air in the flue gas. The geometric parameters of the first baffle were changed twice more. The dependence of the flue gas flow on the baffles was first observed by computational fluid dynamics (CFD) simulations and subsequently verified by the particle imaging velocimetry (PIV) method. Based on the CFD results, the most effective is setting 1 with the same boundary conditions as those during experimental PIV measurements. Setting 2 can capture 1.8% less particles and setting 3 can capture 0.6% less particles than setting 1. Based on the stoichiometric calculations, it would be possible to capture up to 62.3% of the particles in setting 1. The velocities comparison obtained from CFD and PIV confirmed the supposed character of the turbulent flow with vortexes appearing in the flue gas tract, despite some inaccuracies.

Published

2021

21. Effect of Paper Sludge and Dendromass on Properties of Phytomass Pellets

Author

Radovan Nosek, Alexander Backa, Peter Ďurčanský, Michal Holubčík, and Jozef Jandačka

Subjects

wheat straw, sawdust, paper sludge, combustion, emissions, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Woody and agricultural wastes are important fuels in many countries, and have the potential of being even more important in the future. The main problems of plant biomass combustion are low ash melting temperatures and increased emissions. The most widely used treatment to solve the problem of low ash melting point is blending a fuel with an additive. In this work, pellets were produced from wheat straw containing wood sawdust and paper sludge in the following proportions 40:40:20 and 45:45:10 (straw/sawdust/paper sludge). The purpose of this work was to study the influence of sludge and dendromass on the straw pellet parameters and combustion process. The highest calorific value of 15.71 MJ kg−1 was registered for a sample with a 10% paper sludge concentration. The effectiveness of paper sludge was proved, and the ash melting temperature was increased from 1025 to 1328 °C for the same sample.

Published

2020

22. Pyrolysis Conversion of Polymer Wastes to Noble Fuels in Conditions of the Slovak Republic

Author

Michal Holubčík, Ivana Klačková, and Peter Ďurčanský

Subjects

polymer waste, pyrolysis, noble fuel, energetic properties, Technology

Abstract

This paper deals with the pyrolysis conversion of synthetic waste materials into noble fuels, i.e., heating oils, gasoline, diesel, and carbon. The following article presents the principle and use of pyrolysis conversion of waste tires and plastics. The core of the paper is the determination of energy properties of noble fuels obtained from pyrolysis conversion and the possibility of their real use in industry. The aim of this paper is a technical-economic evaluation of the use of waste pyrolysis in practice in the Slovak Republic. Unlike various methods of waste management, there are also more efficient methods, which primarily have a positive effect on the ecology of our Earth and at the same time can be effectively used for the production of alternative fuels. One of these methods is the pyrolysis conversion of synthetic waste materials into noble fuels. It is an ecological, waste-free, economical, and economical disposal of waste with a full recovery of its energy and material components with reduced emissions, and therefore this direction of using synthetic waste for the conversion of alternative fuels contributes to sustainable development. A significant advantage of this waste management is considered to be the fact that only waste tires or chlorine-free plastics are used as input materials without other necessary raw materials obtained by other economic activity. Tires and plastics are generated daily as waste in every household.

Published

2020

23. Combustion of pellets from wheat straw

Author

Jozef Jandačka, Michal Holubčík, Štefan Papučík, and Radovan Nosek

Subjects

wood pellets, straw pellets, energy crops, performance, emission, Mining engineering. Metallurgy, TN1-997, Geology, QE1-996.5

Abstract

The alternative energy sources are more and more used for production of heat. Several new combustion devices allow co-firingof different fuels, like dendromass and phytomass. The article analyses combustion of wood and straw pellets in the same boiler.Measurements were realized in two automatic heat sources – one is adapted to burn pellets made from wood or straw and anotherallows only burning of wood pellets. There are analysed performance and emission parameters of boiler.

Published

2012

24. Emission Controls Using Different Temperatures of Combustion Air

Author

Radovan Nosek, Michal Holubčík, and Štefan Papučík

Subjects

Technology, Medicine, Science

Abstract

The effort of many manufacturers of heat sources is to achieve the maximum efficiency of energy transformation chemically bound in the fuel to heat. Therefore, it is necessary to streamline the combustion process and minimize the formation of emission during combustion. The paper presents an analysis of the combustion air temperature to the heat performance and emission parameters of burning biomass. In the second part of the paper the impact of different dendromass on formation of emissions in small heat source is evaluated. The measured results show that the regulation of the temperature of the combustion air has an effect on concentration of emissions from the combustion of biomass.

Published

2014

25. The Performance and Emission Parameters Based on the Redistribution of the Amount of Combustion Air of the Wood Stove

Author

Michal Holubčík, Nikola Čajová Kantová, Jozef Jandačka, and Alexander Čaja

Subjects

particulate matter, emissions, combustion, burning condition, air distribution, air supply, Process Chemistry and Technology, Chemical Engineering (miscellaneous), Bioengineering

Abstract

Several factors affect how particulate matter and gaseous emissions are formed during the combustion processes of biomass. The amount of combustion air, as well as its redistribution, is one of these factors. This article deals with the performance and emission parameters determined using different distributions of the amount of combustion air of the wood stove with beech wood as a fuel. Eighteen different settings of primary, secondary and tertiary air supplies were realized, while heat output, efficiency, particulate matter, carbon monoxide and nitrogen oxides were measured or determined. The aim of this article is to identify the optimal air distribution between primary, secondary, and tertiary air supplies focused on the mentioned parameters. Based on the results, two settings (25/50/25 and 0/100/0) could be the optimal variant. However, the concentration of particulate matter reached a higher value during the setting with a ratio of 25/50/25, similar to a ratio of 50/25/25. The measurement during the setting with a ratio of 0/100/0 could be influenced by the existing embers on the grid before the start of the measurement. However, it is important to supply all three types of combustion air with the main emphasis on the secondary air supply due to the completely use of the combustible gases.

Published

2022

26. PER OPERATION OF THE AUTOMATIC HEAT SOURCE ON PELLETS WITH VARIOUS BURNER TYPES

Author

Jozef Jandačka, Nikola Kantová, Juraj Trnka, and Michal Holubčík

Subjects

Materials science, biomass, heat source, lcsh:T, wood pellets, Metallurgy, Pellets, Combustor, General Earth and Planetary Sciences, boiler, burner, lcsh:Technology, General Environmental Science

Abstract

One of the most important issues in choosing a heating system is the question: What kind of fuel can be burned in given heating system. Modern automatic solid fuel boilers are often specialized only on a narrow range of suitable pellet materials. Pellets from cheaper sources are also beginning to appear on the market. However, many burners are unable to burn these new types of pellets without significant burning problems. The article deals with the influence of the proper construction of the burner on the smoothness of the combustion process and the smooth operation of the combustion equipment. The results of the experiments document the continuity of the combustion plant in the combustion of less quality pellets containing bark using more modern combustion technologies. In fact, less quality pellets cause the formation of ash sinters which cause the continuous combustion process to be interrupted, resulting in fluctuations in equipment performance and the onset of thermal discomfort. The results showed no problem with burning even when making sinters, but also showed a fluctuation in performance and the need for manual control, especially when heating or clogging the supply pipe. They also showed significant damage to pellets in the worm feeder section. These problems, therefore, ultimately require further research to ensure complete, seamless operation.

Published

2019

27. Effect of Paper Sludge and Dendromass on Properties of Phytomass Pellets

Author

Radovan Nosek, Alexander Backa, Jozef Jandačka, Peter Ďurčanský, and Michal Holubčík

Subjects

020209 energy, Melting temperature, Pellets, 02 engineering and technology, Combustion, lcsh:Technology, lcsh:Chemistry, 020401 chemical engineering, Pellet, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, 0204 chemical engineering, Instrumentation, lcsh:QH301-705.5, Fluid Flow and Transfer Processes, wheat straw, paper sludge, lcsh:T, Process Chemistry and Technology, General Engineering, emissions, Straw, Pulp and paper industry, lcsh:QC1-999, Computer Science Applications, sawdust, lcsh:Biology (General), lcsh:QD1-999, lcsh:TA1-2040, visual_art, visual_art.visual_art_medium, Melting point, Environmental science, Heat of combustion, Sawdust, lcsh:Engineering (General). Civil engineering (General), lcsh:Physics, combustion

Abstract

Woody and agricultural wastes are important fuels in many countries, and have the potential of being even more important in the future. The main problems of plant biomass combustion are low ash melting temperatures and increased emissions. The most widely used treatment to solve the problem of low ash melting point is blending a fuel with an additive. In this work, pellets were produced from wheat straw containing wood sawdust and paper sludge in the following proportions 40:40:20 and 45:45:10 (straw/sawdust/paper sludge). The purpose of this work was to study the influence of sludge and dendromass on the straw pellet parameters and combustion process. The highest calorific value of 15.71 MJ kg&minus, 1 was registered for a sample with a 10% paper sludge concentration. The effectiveness of paper sludge was proved, and the ash melting temperature was increased from 1025 to 1328 &deg, C for the same sample.

Published

2021

28. Experimental Verification of CFD Simulation When Evaluating the Operative Temperature and Mean Radiation Temperature for Radiator Heating and Floor Heating

Author

Pavol Mičko, Dávid Hečko, Michal Holubčík, and Andrej Kapjor

Subjects

radiator heating, Operative temperature, floor heating, 020209 energy, Nuclear engineering, 0211 other engineering and technologies, Bioengineering, TP1-1185, 02 engineering and technology, law.invention, Operating temperature, law, operative temperature, 021105 building & construction, Heat exchanger, Thermal, 0202 electrical engineering, electronic engineering, information engineering, Chemical Engineering (miscellaneous), mean radiation temperature, QD1-999, Chemical technology, Process Chemistry and Technology, Thermal comfort, Chemistry, Heating system, Heat transfer, Environmental science, Radiator

Abstract

The assessment of heating systems is not only interested in the efficiency of the heating system itself, but also in the quality of the environment that the heating system creates. The quality of the environment and the heat-humidity microclimate is closely related to thermal comfort. A suitable environment has a positive effect, for example, on the efficiency of work at the workplace. The range of temperatures, humidity and operating temperatures in workplaces is often also legally prescribed in such a way that there is no thermal discomfort for users in the heated space. In terms of savings, it is therefore best to use heating systems that can create a comfortable environment with the lowest possible energy costs. During their development, variations are possible with temperature gradients, the size of the heat exchange area, or the ratio of the radiant and convective components of heat transfer. When developing such systems, it is appropriate to consider CFD simulations. The comparison of the results of CFD simulation and experimental measurement is also in the following article, where the comparison of the operating temperature and the mean radiation temperature of two different heating systems in the model office is monitored.

Published

2021

29. Small Heat Source Used for Combustion of Wheat-Straw Pellets

Author

Michal Holubčík, Andrej Kapjor, Marián Pafčuga, Milan Malcho, and Peter Durcansky

Subjects

Flue gas, Technology, QH301-705.5, 020209 energy, QC1-999, Pellets, Biomass, 02 engineering and technology, 010501 environmental sciences, Combustion, 01 natural sciences, wheat-straw, Heat exchanger, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, Biology (General), Process engineering, Instrumentation, QD1-999, 0105 earth and related environmental sciences, Fluid Flow and Transfer Processes, business.industry, Process Chemistry and Technology, Physics, General Engineering, Boiler (power generation), Straw, Engineering (General). Civil engineering (General), Computer Science Applications, Renewable energy, small heat source, Chemistry, Environmental science, boiler, TA1-2040, business, CFD, combustion

Abstract

Wheat straw, as a secondary waste agricultural product, presents a potential renewable source of energy. It is necessary to design simple heat sources to achieve better usage. As part of an analysis of heat sources, a tubular type of heat exchanger was reviewed. The design of the exchanger was focused on the smallest possible dimensional requirements, low costs, high reliability and easy maintenance. We chose a tubular type of heat exchanger. In our case, flue gas flows through the tubes, and water flows outside of the tubes. This type of exchanger allows for continuous cleaning, but also simple maintenance, even in case of equipment failure. It is possible to replace individual parts (pipes) of equipment that are exposed to the adverse corrosive effects of biomass flue gases. A mathematical model was composed to compute the construction of a heat source. The model was verified by CFD simulation. The main idea of this design is modularity. The composed model can be used to design a series of similar heat sources with different levels of power, and which, as it is of maximal availability for this type of construction, increase use of waste straw as fuel by small farms.

Published

2021

30. ENERGY RECOVERY OF BONE WASTE AS HEAT SOURCE

Author

Michal Holubčík, Jozef Jandačka, and Juraj Trnka

Subjects

Energy recovery, bone wastes, Waste management, ash content, lcsh:T, incineration, General Earth and Planetary Sciences, Environmental science, food and beverages, lcsh:Technology, General Environmental Science

Abstract

Modern food industry concerning meat producers produce high amounts of bone waste. Bones represent biggest portion of zoo-mass waste which must be destroyed for hygienically reasons. Bones also have long durability and it is taken long time to decomposing this material microbiologically. We already know way to destroy this waste by crushing and making meat and bone meal. However, feeding with meat-and-bone meal can cause animal diseases. Because of that we try to prove combustion as a suitable way to get rid of this waste. Everything can be cleansed by flames and combustion also release energy captured in bone tissue. This energy can be used as heat or transformed to electric current also. But the other side, bone burning also has its emission problems that this work is trying to solve.

Published

2019

31. Energy accumulation system based on gas hydrates

Author

Peter Durcansky, Jozef Jandačka, Milan Malcho, and Michal Holubčík

Subjects

Marketing, Materials science, 010308 nuclear & particles physics, Renewable Energy, Sustainability and the Environment, energy storage, lcsh:Mathematics, Clathrate hydrate, Energy Engineering and Power Technology, Thermodynamics, gas hydrate, lcsh:QA1-939, 01 natural sciences, lcsh:QA75.5-76.95, numerical simulation, 0103 physical sciences, lcsh:Q, lcsh:Electronic computers. Computer science, 010306 general physics, lcsh:Science, Energy (signal processing)

Abstract

Accumulation of primary energy of natural gas is a perspective option to store natural gas as artificially created hydrate, where this matter can be stored and, if necessary, can be released to cover energy peaks. Gas can be stored this way at partially higher temperatures and low pressures compared to other storage technologies. The technique of rapidly and continuously producing hydrates of gas could compete with the existing means for storing and transporting these energy reserves in more than an economically efficient aspect, but again these new technologies need development. Transporting and storage of natural gas is economically and technologically demanding, which is always reflected in the resulting price. Natural gas hydrates allow transport and storage at low pressures and relatively favorable temperatures. Presented article deals with design of new energy accumulation system based on gas hydrates. In article is presented the main design and also a numerical model, where the parameters of created hydrate are qualified.

Published

2021

32. Particulate matter measurement by using the particle sizers APS and SMPS

Author

Jozef Jandačka, Michal Holubčík, P. Ďurčanský, and A. Čaja

Subjects

Marketing, particulate matter, Range (particle radiation), Flue gas, smps, Materials science, Renewable Energy, Sustainability and the Environment, lcsh:Mathematics, Analytical chemistry, Energy Engineering and Power Technology, particle sizer, gravimetric method, Particulates, lcsh:QA1-939, lcsh:QA75.5-76.95, Aerosol, Scanning mobility particle sizer, Particle-size distribution, Particle, lcsh:Q, Particle size, lcsh:Electronic computers. Computer science, lcsh:Science, aps

Abstract

Currently, there is an increasing trend in the use of biomass for energy purposes, due to global pressure on the use of renewable energy sources and a gradual decline in fossil fuel stocks. However, biomass combustion can be considered as a significant source of particulate concentrations in the atmosphere. Measurement of particles from biomass combustion plants is very demanding; the particle size range is large, usually ranging from a few nanometers (nm) to a few micrometers (μm). The measurement of the particles is carried out in terms of mass concentrations, numerous concentrations and their particle size distribution. The selection of metering devices for measuring particulate matter and their size distribution is important because different devices differ in their characteristics and have specific advantages and disadvantages. The large particle number concentrations in the flue gas after biomass combustion exceed the detection capacity of some plants, therefore they are used for measurement with flue gas diluents for measurement. At present, the gravimetric method, the method of particulate matter measuring using an aerodynamic particle sizer (APS) or a scanning mobility particle sizer (SMPS) is often used. The cascade impactor gravimetric method is based on comparing particles basedon their aerodynamic diameter. APS is a spectrometer that measures particles between 0.5 and 20 μm in size. The working principle is based on the acceleration of aerosol sample flow through an accelerating orifice. SMPS measures the size distribution and concentration of particles in the size range of 1 nm to 1 μm using differential mobility analysis. When the device SMPS is used with the APS, the range increases to 20 μm. This paper focuses on the measurement of particulate matter by tandem connection of APS and SMPS particle sizers using dilution. Dilution is used to eliminate the mechanisms that arise when sampling particles that may affect their properties. These are nucleation, condensation, evaporation and coagulation. The results are then compared with gravimetric measurements.

Published

2021

33. Influence of Biomass Combustion Method on Properties of Solid Fuel Residues

Author

Michal Holubčík, Juraj Trnka, and Jozef Jandačka

Subjects

Waste management, Biomass combustion, Environmental science, TA1-2040, Solid fuel, Engineering (General). Civil engineering (General)

Abstract

The correct course of the combustion process has a great influence on several output parameters. In addition to the impact on the performance and efficiency of the device, the impact on the formation and properties of gaseous emissions and solid residue is particularly noticeable. The solid combustion residue, in particular in the form of ash, remains trapped as the final product after combustion in the incinerator or may be released to the outside environment. Improperly, combustion can form two negative extremes. The first extreme is the formation of too fine dust particles of ash and solid pollutants escaping into the air as dangerous emission substances for human and other organism’s health. The second is the failure to burn larger pieces of fuel or sinter them into clumps, which can subsequently damage the combustion device or reduce the efficiency of combustion. This article aims to examine the various factors influencing the impact of combustion in different types of combustion plants on the properties of the resulting solid fuel residues and further possibilities of their use and effects on the environment.

Published

2020

34. Design of an Experimental Device for Simulation of Pipeline Expansion

Author

Stanislav Gavlas, Michal Holubčík, and Juraj Drga

Subjects

Materials science, 010308 nuclear & particles physics, Pipeline (computing), 0103 physical sciences, 02 engineering and technology, TA1-2040, 021001 nanoscience & nanotechnology, 0210 nano-technology, Engineering (General). Civil engineering (General), 01 natural sciences, Marine engineering

Abstract

This article describes the design of an experimental device for simulating pipe expansion. The device consisted of various variants of compensating elements and types of piping materials. Based on this, a 3D model was developed, together with numerical design calculations of compensators. Subsequently, a more complex analysis was performed by using the CAE Pipe calculation program, which performed calculations of dilatations, forces at fixed points and stresses in the pipeline.

Published

2020

35. Reduction in Difficulties of Phytomass Combustion by Co-Combustion of Wood Biomass

Author

Jozef Mičieta, Jozef Jandačka, and Michal Holubčík

Subjects

co-combustion, ash melting temperature, Waste management, biomass, Pellets, Boiler (power generation), combustion difficulties, Particulates, Straw, pellet, Combustion, TK1-9971, Biofuel, Pellet, emission, Environmental science, Electrical engineering. Electronics. Nuclear engineering, Electrical and Electronic Engineering, NOx

Abstract

Nowadays, the most used biofuel in Slovak republic is log wood. Alternatively, there are also biofuels based on vegetal biomass (phytomass) like wheat straw or grass. The advantage of these biofuels is lower cost price because they are usually considered as waste product. The major disadvantage of these vegetal biofuels is their problematic combustion. It is mainly due to the low ash melting temperature because of chemical composition of ash from phytomass. The low ash melting temperature causes slagging and sintering, which reduce the efficiency of the combustion process. This disadvantage causes very difficult and problematic combustion of phytomass. The article deals the way of trouble reduction during combustion of pellets made from phytomass (specific hay) through the wood pellet co-combustion in a standard automatic boiler for combustion of wood pellets. During the experiments, the mixing ratio of hay pellets and wood pellets is varied and subsequently, there is determined its impact on the combustion process, namely on heat output of the boiler, and there is also evaluated the effect of the mixing ratio on the production of carbon monoxide (CO), nitrogen oxides (NOx), sulphur dioxide (SO2), organic hydrocarbons (OGC) and particulate matters (PM10, PM2.5).

Published

2016

36. Flow modelling of particulate matter by using baffles placed in the flue tract of wood stove

Author

Jozef Jandačka, Nikola Kantová, Michal Holubčík, and Alexander Čaja

Subjects

Waste management, lcsh:TA1-2040, Flow (psychology), Wood stove, Environmental science, Baffle, Particulates, lcsh:Engineering (General). Civil engineering (General), Flue

Abstract

It is very important to separate particulate matter before their leaving into the air because of their harmful impact on human health. It exists a lot of devices, which can separate these particles. But their implementation and operation in small heat source can be considerably difficult on finances, and often have complex maintenance. Therefore, it is important to look for solutions of reduction the producing of particulate matter with easier maintenance and also less financial difficulty. This article deals with flow modelling of particulate matter by using baffles placed in the flue tract of wood stove. Influence of baffles is observed by using CFD simulations.

Published

2018

37. Impact of Seasonal Heating on PM10 and PM2.5 Concentrations in Sučany, Slovakia: A Temporal and Spatial Analysis

Author

Dusan Jandacka, Daniela Durcanska, Miriam Nicolanska, and Michal Holubcik

Subjects

local heating, particulate matter, emission dispersion, heating seasons, monitoring, Physics, QC1-999

Abstract

Complying with strict PM10 and PM2.5 limit values poses challenges in many European regions, influenced by diverse factors such as natural, regional, and local anthropogenic sources. Urban air pollution, exacerbated by road transport, local industry, and dust resuspension, contrasts with rural areas affected by solid fuel-based local heating and increasing wood burning. This study focuses on village of Sučany, located in Slovakia, analysing PM concentrations during non-heating and heating seasons. The method of analysis relies on the use of the MP101M air quality analyser that utilises beta radiation absorption method. One set of measurements was conducted at five distinct locations during the heating season (18/01/2019 to 28/02/2019) and non-heating season (14/08/2018 to 1/10/2018). Significant differences emerged during the non-heating season with corresponding PM10 averages of 23.0 µg/m3 and PM2.5 at 19.3 µg/m3. In contrast, the PM10 averaged 53.9 µg/m3 and 52.8 µg/m3 during the heating season. The heating season shows PM2.5 contributing up to 98% of total PM10. The distribution of PM10 and PM2.5 pollution and the location of the potential source obtained using polar plots differed during the heating and non-heating seasons. This research underscores the impact of local heating on air quality in a typical Slovak village. The key recommendation for targeted interventions is supporting up-to-date air quality data, education, and financial incentives for citizens in order to implement cleaner and modern heating solutions.

Published

2024

38. Design of Heat Exchanger for Ericsson-Brayton Piston Engine

Author

Peter Durcansky, Michal Holubčík, Štefan Papučík, Radovan Nosek, and Jozef Jandačka

Subjects

Thermal efficiency, Stirling engine, Hot Temperature, Article Subject, Combined cycle, Transducers, External combustion engine, lcsh:Medicine, lcsh:Technology, General Biochemistry, Genetics and Molecular Biology, law.invention, Heating, Cogeneration, Electric Power Supplies, law, Waste heat, lcsh:Science, Process engineering, General Environmental Science, Heat engine, lcsh:T, business.industry, lcsh:R, Thermal Conductivity, General Medicine, Equipment Design, Equipment Failure Analysis, Internal combustion engine, Energy Transfer, Environmental science, Computer-Aided Design, lcsh:Q, business, Research Article

Abstract

Combined power generation or cogeneration is a highly effective technology that produces heat and electricity in one device more efficiently than separate production. Overall effectiveness is growing by use of combined technologies of energy extraction, taking heat from flue gases and coolants of machines. Another problem is the dependence of such devices on fossil fuels as fuel. For the combustion turbine is mostly used as fuel natural gas, kerosene and as fuel for heating power plants is mostly used coal. It is therefore necessary to seek for compensation today, which confirms the assumption in the future. At first glance, the obvious efforts are to restrict the use of largely oil and change the type of energy used in transport. Another significant change is the increase in renewable energy—energy that is produced from renewable sources. Among machines gaining energy by unconventional way belong mainly the steam engine, Stirling engine, and Ericsson engine. In these machines, the energy is obtained by external combustion and engine performs work in a medium that receives and transmits energy from combustion or flue gases indirectly. The paper deals with the principle of hot-air engines, and their use in combined heat and electricity production from biomass and with heat exchangers as primary energy transforming element.

Published

2014

39. Novel Design for Rotary Burner for Low-Quality Pellets

Author

Michal Holubcik, Peter Durcansky, Jozef Jandacka, Jan Najser, and Andrej Klacko

Subjects

burner, low quality fuel, rotating chamber, renewable energy resource, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

The burning of low-quality fuels causes several problems in the operation of combustion equipment, which can negatively affect the equipment’s efficiency. The possibilities for the burning of pellets made from low-quality raw materials are limited mainly by the fusibility of the ash, which settles and melts on the surfaces of the burner, gradually causing it to clog. Smelted ash also causes a decrease in heat transfer efficiency, which negatively affects the overall efficiency of the heat source. A possible solution is provided by burners with a rotating combustion chamber, where the contact time of the molten ash with the walls of the burner is shortened, and thus there is no significant melting of the ash in the burner. This manuscript is dedicated to summarizing the current state of development of burners with a rotary chamber, presenting a novel design for such a burner, and providing an analysis of that design. To conclude, the results of experimental measurements on a classic burner and a burner with a rotary chamber are presented, including a comparison and evaluation mainly in terms of emissions. The novel-designed rotary burner achieved a higher heat output than the retort burner, but a similar thermal efficiency. The rotary burner produced 32.5% lower CO emissions, 12.5% higher NOx emissions, 23% lower OGC emissions, and 44.7% higher PM emissions in comparison with a retort burner under the same conditions. This novel rotary burner concept could, after optimization, be a suitable option for efficient combustion of alternative biofuels.

Published

2023

40. Small Heat Source Used for Combustion of Wheat-Straw Pellets

Author

Marian Pafcuga, Michal Holubcik, Peter Durcansky, Andrej Kapjor, and Milan Malcho

Subjects

wheat-straw, combustion, CFD, small heat source, boiler, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

Wheat straw, as a secondary waste agricultural product, presents a potential renewable source of energy. It is necessary to design simple heat sources to achieve better usage. As part of an analysis of heat sources, a tubular type of heat exchanger was reviewed. The design of the exchanger was focused on the smallest possible dimensional requirements, low costs, high reliability and easy maintenance. We chose a tubular type of heat exchanger. In our case, flue gas flows through the tubes, and water flows outside of the tubes. This type of exchanger allows for continuous cleaning, but also simple maintenance, even in case of equipment failure. It is possible to replace individual parts (pipes) of equipment that are exposed to the adverse corrosive effects of biomass flue gases. A mathematical model was composed to compute the construction of a heat source. The model was verified by CFD simulation. The main idea of this design is modularity. The composed model can be used to design a series of similar heat sources with different levels of power, and which, as it is of maximal availability for this type of construction, increase use of waste straw as fuel by small farms.

Published

2021

41. The Impact of Bark Content in Wood Pellets on Emission Production During Combustion in Small Heat Source

Author

Michal Holubcik, Jozef Jandacka, Matej Palacka, Nikola Kantova, Ewa Jachniak, and Petr Pavlik

Subjects

wood biomass, bark, emissions, particulate matter, Transportation and communications, HE1-9990, Science, Transportation engineering, TA1001-1280

Abstract

The combustion of biomass is relatively complicated. To minimize the emission production it is necessary to ensure the optimal setting of combustion process. The article deals with the impact of bark content in wood biomass on performance and emission parameters of a small heat source. The increasing content of bark in wood biomass changes its chemical composition and parameters, namely its net calorific value, ash content, ash fusion temperature and others. During experiments samples of wood pellets made from spruce having 1, 2, 5 and 10 percent bark content together with a reference sample without any bark content were burned. The samples were burned in a hot water boiler with a rated output of 18 kW. It was found out that with the increasing bark content, the thermal output of the heat source decreases and the emission production increases, particularly the production of both carbon monoxide (CO) and particulate matter (PM). At the same time it was confirmed that with the increasing bark content the amount of ash also increases. Results showed that the burning of wood pellets with higher bark content has a more negative impact on the environment.

Published

2017

42. Reduction in Difficulties of Phytomass Combustion by Co-Combustion of Wood Biomass

Author

Michal Holubcik, Jozef Jandacka, and Jozef Micieta

Subjects

ash melting temperature, biomass, combustion difficulties, co-combustion, emission, pellet., Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Nowadays, the most used biofuel in Slovak republic is log wood. Alternatively, there are also biofuels based on vegetal biomass (phytomass) like wheat straw or grass. The advantage of these biofuels is lower cost price because they are usually considered as waste product. The major disadvantage of these vegetal biofuels is their problematic combustion. It is mainly due to the low ash melting temperature because of chemical composition of ash from phytomass. The low ash melting temperature causes slagging and sintering, which reduce the efficiency of the combustion process. This disadvantage causes very difficult and problematic combustion of phytomass. The article deals the way of trouble reduction during combustion of pellets made from phytomass (specific hay) through the wood pellet co-combustion in a standard automatic boiler for combustion of wood pellets. During the experiments, the mixing ratio of hay pellets and wood pellets is varied and subsequently, there is determined its impact on the combustion process, namely on heat output of the boiler, and there is also evaluated the effect of the mixing ratio on the production of carbon monoxide (CO), nitrogen oxides (NOx), sulphur dioxide (SO2), organic hydrocarbons (OGC) and particulate matters (PM10, PM2.5).

Published

2016

43. The Impact of Bark Content of Wood Biomass on Biofuel Properties

Author

Radovan Nosek, Michal Holubcik, and Jozef Jandacka

Subjects

Woody biomass, Bark content, Ash, Energy content, Moisture, Biotechnology, TP248.13-248.65

Abstract

Woody biomass is an abundant, renewable energy source. Forest residue is the fraction remaining after harvest and the outtake of wood timber, including tree tops and bark. Compared with the wood portion, bark has a wide variation of ash content. Wood usually has a relatively low ash content, while bark has considerably higher ash content, which may generate clinker in the furnace and thereby tends to create more demand for maintenance. High ash content also generates more particulate emissions. Different types of bark were studied in the present work in terms of their effect on energy content, moisture, and ash content. The ash content of three different samples (Norway spruce, birch, and European beech) were measured at 550 and 815 °C. The results showed the impact of bark content on all parameters, in particular the calorific value and ash content. The ash content increased with increasing bark content. The addition of 1% bark content resulted in increases of ash content in the range 0.033 to 0.044%.

Published

2015

44. Factors Affecting Emission Concentrations in Small Heat Sources

Author

Michal Holubcik, Radovan Nosek, Katarína Sulovcova, and Roman Weber

Subjects

emission, dendromass, temperature of combustion air, fuel moisture, air humidity, Transportation and communications, HE1-9990, Science, Transportation engineering, TA1001-1280

Abstract

Combustion of biomass fuel itself as a renewable energy source does not automatically ensure the best use of its energy content with low emission production. Biomass combustion with bad settings of combustion conditions can be ineffective and with a high production of emissions. The article discusses the impact of various aspects on the power and emission parameters of the heat source. The influence of the amount of combustion air, the temperature of combustion air, the relative humidity of combustion air, the fuel feeding and fuel moisture on thermal power and emission production in automatic boiler for combustion of wood pellets were specifically verified. The results show that appropriate setting of these aspects has an effect on concentration of emissions from the combustion of biomass.

Published

2015

45. Mathematical Model for Prediction of Biomass Ash Melting Temperature using Additives

Author

Michal Holubcik and Jozef Jandacka

Subjects

ash melting temperature, biomass ash, additives, prediction, Transportation and communications, HE1-9990, Science, Transportation engineering, TA1001-1280

Abstract

Some types of biomass ash have low ash melting temperature which can result in various problems in combustion processes. Ash slags and sinters can avoid heat transfer in heat exchangers, which can also cause corrosion of heat transfer surfaces. One of the ways of burning fuels with low ash melting temperature is to use additives. Ash melting temperature can be determined in a laboratory on the basis of standard STN ISO 540. Meltability of ash is characterized by the physical state of ash occurring during the heating process under well-defined conditions in the furnace. Experimental determination of ash melting temperature is quite expensive. In this work a prediction method of ash melting temperature is described. The mathematical model uses multiple linear regression where input parameters are the known chemical composition of fuel ash and used additive converted to an amount of SiO2, CaO, K2O, MgO and Al2O3. The mathematical model is relatively accurate with real ash melting temperatures and reaches accuracy about of 90 % compared with ash melting temperatures obtained by STN ISO 540 method in a laboratory.

Published

2014