Next Article in Journal
A Method to Process Hollow-Core Anti-Resonant Fibers into Fiber Filters
Previous Article in Journal
Flexural Behavior of Carbon Textile-Reinforced Geopolymer Composite Thin Plate
 
 
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Article

In-Situ Vacuum Assisted Gas Stripping Recovery System for Ethanol Removal from a Column Bioreactor

1
Department of Biochemical Engineering, Faculty of Food Technology and Biotechnology, University of Zagreb, Pierottijeva 6, 10000 Zagreb, Croatia
2
Department of Food Sciences and Technology, University of Natural Resources and Life Sciences, 1190 Vienna, Austria
*
Author to whom correspondence should be addressed.
Submission received: 28 September 2018 / Revised: 1 November 2018 / Accepted: 6 November 2018 / Published: 9 November 2018
(This article belongs to the Special Issue Enzymatic Cellulose Degradation)

Abstract

:
A three-step process consisting of biomass hydrolysis, fermentation and in-situ gas stripping by a vacuum assisted recovery system, was optimized to increase the ethanol production from sugar beet pulp. The process combines the advantages of stripping and vacuum separation and enhances the fermentation productivity through in-situ ethanol removal. Using the design of experiment and response surface methodology, the effect of major factors in the process, such as pressure, recycling ratio and solids concentration, was tested to efficiently remove ethanol after the combined hydrolysis and fermentation step. Statistical analysis indicates that a decreased pressure rate and an increased liquid phase recycling ratio enhance the productivity and the yield of the strip-vacuum fermentation process. The results also highlight further possibilities of this process to improve integrated bioethanol production processes. According to the statistical analysis, ethanol production is strongly influenced by recycling ratio and vacuum ratio. Mathematical models that were established for description of investigated processes can be used for the optimization of the ethanol production.

1. Introduction

Conventional ethanol fermentation is a typically product inhibiting process leading to low productivity and yield. This problem can be alleviated by continuous removal of ethanol from the fermentation broth. In-situ ethanol separation increases the productivity of the fermentation broth and reduces the amount of water added to the distillation feed stream. Several processes based on continuous ethanol removal during fermentation have been developed, which include: vacuum fermentation [1], flash fermentation [2], stripping fermentation [3], extraction fermentation [4] and membrane separation [5,6]. In the flash fermentation content of a fermenter circulates through a vacuum flash tank. The partial vaporization of water and fermentation products in the flash tank generates a vapor phase rich in solvents and vapor-depleted liquid stream. The vapor is condensed and sent to distillation section while vapor-depleted liquid stream is returned to the fermenter [7]. Stripping fermentation is a simple technique and does not require expensive equipment. Gas (CO2, N2) can be sparged through the fermenter and the volatile ethanol can recovered from the condenser [8]. Flash fermentation and stripping fermentation processes are straightforward, suitable for implementation in industrial applications and have little influence on the culture medium. However, their overall low separation efficiency and compressor restrictions limit the efficiency of these processes. Therefore, a new ethanol flash-strip fermentation process has been proposed, which combines the advantages of both stripping- and flash-fermentation and improves the fermentation productivity by increasing the in-situ ethanol removal [9]. In these processes, a combination of a gas with sterile air enabled the circulation of the medium to replace mechanical agitation and reduce the energy demand. A main cost factor is the compression of the stripping gas, which is injected into the bottom of the fermenter by a sparger [10].
To reduce costs, several options for gas stripping operations were developed [11]. The fermenter content can be recovered through a stripping column, where ethanol is removed by recycling the CO2 gas through a condenser [12]. With the aim to increase productivity and reduce product recovery costs [13] several different gases (air, CO2, N2) have been studied [14]. For the ethanol production from sugarcane, a research group from Brazil tested N2 as a stripping carrier gas [15]. The stripping experiment was done in a continuous fermentation process with a residence time of 7–9 h, without recycling of the stripping gas. It was observed that stripping the reaction products (ethanol and CO2) increased productivity while lowering the formation of other side products of the yeast metabolism. After the stripped ethanol was recovered, the CO2 and gaseous stream was purified using water wash scrubbing. To further lower the production costs, part of the N2 can be replaced with CO2, because N2 has only 2/3 of the mass of the same volume of CO2 at atmospheric pressure. These savings would be even higher as the cost of energy decreases [16].
In a study of de Vrije et al. [17] gas stripping of isopropanol, butanol and ethanol (IBE) by N2 was studied. The process of gas stripping using nitrogen gas was applied to a batch, a repeated batch and continuously grown cultures of Clostridium beijerinckii cultivated on a substrate mixture containing glucose and xylose, which mimics the sugar content of lignocellulosic biomass hydrolysates. The aim of the study was to determine the optimal conditions for a stable, high producing IBE microbial culture. The result was an innovative repeated-batch process where the gas stripping is performed at 70 °C resulting in a prolonged stable IBE culture.
To make the process more sustainable and to accomplish continuous production with high conversion efficiency, gas stripping solid state fermentation (GS-SSF) was developed. Chen et al. [18] optimized the conditions of GS-SSF for the bioethanol production from sweet sorghum stalk. When compared with conventional solid-state fermentation, the ethanol yield increased from 6 to 10% under the same conditions (stripping time, temperature, particle size) and reached 22.7 g EtOH per 100 g dry biomass. The optimized initial gas stripping time was 10 h, while the gas stripping temperature was set to 35 °C at a total fermentation time of 28 h. The particle size of sweet sorghum stalk was 0.15 cm. The accomplished ethanol stripping efficiency of the process was 77.5%. During GS-SSF, the ethanol yield increased by 30% with the particle size decreasing from 0.4 cm to 0.05 cm. The gas stripping reduced the ethanol inhibition effect and improved the mass and heat transfer efficiency, which enhanced the solid-state fermentation performance.
Sonego et al. [19] investigated ethanol production by fed-batch fermentation with CO2 stripping in a 5-L bubble column bioreactor under different substrate concentrations. The experiment was modeled with a hybrid Andrews–Levenspiel model, which is able to accurately predict the behavior of conventional and extractive fed-batch ethanol fermentations. Process kinetic parameters were evaluated by modeling of conventional fed-batch fermentations without stripping using a sucrose concentration of 180 g L−1 in the feed at a temperature of 34 °C and filling times of 3 and 5 h. By applying ethanol stripping, the inhibitory effects of the substrate and ethanol on the yeast cells were reduced, which allowed substrate concentrations in the feed of up to 240 g L−1. The total ethanol concentration was 33% higher when using the fed-batch ethanol fermentation compared to conventional fed-batch fermentation without ethanol removal [19]. With the aim of analyzing economic possibilities of continuous ethanol production from lignocellulose at high solid loadings, a techno-economic analysis was carried out. From the obtained results it was obvious that in-situ removal of ethanol considerably improved the economic aspect of the processes [20]. The experiments reported in this study were conducted to further investigate and characterize the performance of the saccharification and fermentation of high sugar beet pulp (SBP) combined with gas stripping and to optimize the effect of vacuum rate, recycling ratio and solids concentration on ethanol production in a column bioreactor [21]. The aim of this work was to develop an integrated bioprocess for ethanol production and separation from selected lignocellulosic raw material (sugar beet pulp) by using column bioreactor. A novel vacuum assisted in-situ gas striping recovery system for ethanol removal from the column bioreactor was successfully implemented resulting in increased productivity and reduced product recovery costs.

2. Materials and Methods

2.1. Column Bioreactor and In-Situ Gas Striping Vacuum Assisted Recovery System

The column bioreactor is constructed as a 0.6 m long, double-walled Pyrex glass tube with an inner diameter of 0.025 m, resulting in a total volume of approx. 1.2 L. The bioreactor was vertically placed and integrated into the experimental apparatus shown in Figure 1. The figure also shows a scheme of the vacuum assisted gas stripping recovery system. In order to make the strip-flash fermentation work smoothly, a column bioreactor (3) and a recirculation-loop (holdup volume of 0.15 L) was designed to overcome the problem of mixing. The flow rate was controlled by a peristaltic pump (7) and the temperature regulated via the circulation of thermostatted water through the double walls of the column reactor. The carbon dioxide used for stripping was supplied by a 200 bar CO2 bottle with reduction valves connected to a flowmeter to regulate the flow rate (6). To maintain a constant temperature of the culture medium, the CO2 was warmed up by a heater (2) prior to its application via a sparger at the bottom of the reactor (sinter glass with pore dimension 40–100 µm). The under-pressure of the system was regulated by a vacuum pump (5) operated from 25 to 100 kPa. The product stripped by the gas was collected in a sample bottle immersed in ice-water. This was done by passing it through a condenser (4), the temperature of which was kept at 4 °C by a chiller.
In the present study, enzymatic hydrolysis and fermentation of SBP in the column bioreactor was optimized in terms of pressure, recycling ratio and solid concentration. Initially, the column bioreactor was filled with defined SBP loadings (60–180 g L−1 in 50 mM citrate buffer, pH 4.5; 1 L total volume) and separately sterilized by hot steam (121 °C, 20 min). Hydrolysis started with addition of 14.0 ± 0.1 g L−1 Ultrazym AFP-L, which showed the highest product release efficiency in a previous optimization experiment [22]. Additionally, the fungal secretome of Neurospora crassa grown on sugar beet pulp was added to a final concentration of 0.1 mg protein per g of SBP [23]. The final reaction volume was 1 L. The hydrolysis was performed at pH 4.5 and 39 °C. Samples were withdrawn and analyzed after 72 h. After 72 h of enzymatic treatment, fermentation was started by addition of the yeast culture. The initial yeast concentration in the bioreactor was 30 × 106 CFU mL−1. The batch fermentation was performed at 30 °C under atmospheric pressure and at a recirculation rate of 0.5–1.5 L h−1. Samples were withdrawn and analyzed after 24 h. The gas stripping was performed 24 h after the start of the fermentation and was initiated by applying 20 L h−1 CO2 through the sparger to create gas bubbles in the column bioreactor under a pressure of 25 or 50 kPa. Ethanol vapor was collected in the condenser and cooled to 4 °C. The condensate was analyzed after 20 min of stripping. Sunflower oil was used as antifoam and 1 mL was added manually to the fermenter.

2.2. Sugar Beet Pulp, Enzymes and Microorganisms

Dried sugar beet pulp (SBP) with a residual moisture content of 9% w/w was obtained from the Sladorana d.o.o. sugar factory (Županja, Croatia) and ground to a particle size of 0.3–0.5 mm (Moulinex mill; type-505). SBP is mainly composed of cellulose (25–30%), hemicelluloses (24–32%), pectin (38–62%) while the lignin content is typically low (~1%) [24]. Ultrazym AFP-L (14.0 ± 0.1 g L−1, multi-enzyme complex with polygalacturonase and cellulase activities) was obtained from Novozymes (Bagsværd, Denmark) [22]. N. crassa crude extract (0.1 mg protein per g of SBP) was obtained as described previously [23]. The yeast strain utilized in this study was Saccharomyces cerevisiae Y9 (ATCC® MYA-4941) which was previously used for the fermentation of SBP hydrolysates [23]. The yeast strain was maintained on YPD medium containing per liter: 4 g glucose, 10 g peptone (casein hydrolysates) and 5 g yeast extract. A single isolated colony was used to inoculate a 250 mL flask containing 100 mL YPD medium. The inoculum was incubated anaerobically for 18 to 24 h at 30 °C before being transferred into the column bioreactor.

2.3. Analytical Procedures

Concentrations of released reducing sugars were measured by the 3,5-dinitrosalicylic acid (DNSA) assay according to a previously published protocol [25]. Briefly, 600 × 10−6 L of properly diluted sample solution was mixed with 600 × 10−6 L of DNSA reagent containing 10 g L−1 DNSA, 0.5 g L−1 sodium sulfite, 10 g L−1 sodium hydroxide and 2 g L−1 phenol. The mixture was incubated for 15 min at 95 °C to induce color formation, which was stopped by adding 200 × 10−6 L−1 of a 40 g L−1 ice-cold potassium sodium tartrate solution. Absorbance was immediately read at 575 nm and compared to a calibration curve generated with glucose. Carbohydrates released after enzymatic SBP hydrolysis and fermentation in the column bioreactor were quantified by HPLC on a Supelcogel C-610H column using a refractive index detector (RID, Shimadzu 10 A VP; Kyoto, Japan). Analytes were separated at a flow rate of 0.5 mL min−1 with 0.1% H3PO4 as eluent at a constant temperature of 30 °C. Before analysis, all samples were mixed with ZnSO4 to a final concentration of 10% to induce protein precipitation. Solid debris was removed by centrifugation (4500 min−1 for 20 min). Before column application, sample solutions were passed through a 0.20 μm filter.

2.4. Statistical Analysis

The experimental domain (including minimal and maximal values of independent variables and factors) was designed on the basis of preliminary research [24]. The experimental research plan was based on a fractional factorial design. Three levels design is used for the study of linear and quadratic term effects of three factors (pressure, recycling ratio and SBP concentration) where each on three levels (hydrolysis, fermentation and vacuum assisted gas stripping recovery step) was investigated separately. SBP concentration levels were 60, 120 and 180 g L−1, the recycling ratios 0.5, 1.0 and 1.5 L h−1 and pressure rates 25, 50 and 100 kPa. The influence of the factors was investigated using the data analysis software Statistica version 10 (StatSoft, Palo Alto, CA, USA). Three-dimensional surface plots were generated for the results of hydrolysis, fermentation and vacuum assisted gas stripping steps. The interaction of the investigated factors (pressure rate, recycling ratio and SBP concentration) on the production of sugars and ethanol were analyzed using Pareto charts. Statistical significance was assessed at p < 0.05 for all factors. Moreover, mathematical models for the description of responsive variables (ethanol and sugar concentrations) with the investigated factors were established.

3. Results and Discussion

3.1. Evaluation of the Vacuum Assisted Gas Stripping for Ethanol Removal after SBP Hydrolysis and Fermentation

Stripping with CO2 was tested on enzymatically pre-treated and fermented sugar beet pulp (SBP) at atmospheric and below-atmospheric pressures in a column bioreactor. The response surface methodology (RSM) was applied to the output data to evaluate the impact of process variables (investigated factors) on the efficiency of the in-situ gas stripping vacuum assisted system for ethanol removal. The results of the RSM approach were correlations between response variables (sugar or ethanol concentrations) and the investigated factors (pressure, recycling rate and solids concentration). The process was conducted as a three-step process including the (i) enzyme hydrolysis as the initial step; (ii) yeast fermentation and ethanol production as the second step and (iii) in-situ gas stripping, vacuum distillation and ethanol removal as the third step. All stages of the process were done sequentially in the column bioreactor system described in the Section 2.1.
Response surface model plots for the concentrations of released sugars as a function of recycling ratio (0.5, 1 and 1.5 L h−1) and solid concentration (60, 120 and 180 g L−1) were fitted to obtain response variables for the hydrolysis step (Figure 1). Generally, the quantities of carbohydrates released in the hydrolysis step are considerably higher than in any previous tested system [21,22,23]. During the previous investigation of SBP hydrolysis, Ultrazym AFP-L was selected as the most efficient enzyme mixture and optimal conditions for the hydrolysis were investigated [21]. Optimal pH of 4.5, temperature of 39 °C and enzyme loadings (Ultrazym AFP-L (14.0 ± 0.1 g L−1) and fungal secretome of Neurospora crassa (0.1 mg protein per g of SBP)) were used to provide an efficient hydrolysis in the tested column bioreactor system. Ultrazym AFP-L was further supplemented with crude extract from the cellulose-degrading fungus N. crassa, which secretes the redox enzymes cellobiose dehydrogenase and several lytic polysaccharide monooxygenases when grown on cellulosic substrates [26,27]. These enzymes were previously recognized to de-crystallize cellulose, which boosts the performance of hydrolytic enzymes commonly used in biorefineries [28].
In the presented research, the hydrolysis efficiency of SBP was tested in a column bioreactor to obtain optimum performances. Optimum performances, indicated by the total concentration of hydrolyzed sugars, were measured at high recycling ratios and SBP concentrations, and large global optima were observed (Figure 2).
A correlation between the recycling ratio and the solid (SBP) concentration for the fermentation step was found based on the experimental data shown in Figure 3. Compared to the results of the hydrolysis (Figure 2), large global optima were observed with an additional shift to higher values of the tested factors (recycling ratio and SBP concentration; Figure 3b). A shift to higher concentrations of solid particles can be explained by the step-wise processes and may be a consequence of the efficient hydrolysis in the first step. However, absolute values were lower because of the reduction of the solid concentration after hydrolysis. Previous investigations showed that an efficient hydrolysis directly affects the fermentation step, which highlights the necessity to optimize the hydrolysis step [21]. Both results indicate that the hydrolysis and fermentation steps can be successfully conducted in the tested column bioreactor system employing high solid loadings. Adaptation and optimization of the recycling ratio was an important factor in the bioreactor performance. Efficient mixing in the solid and semi-solid bioreactor system is one of the main obstacles for efficient hydrolysis/fermentation, and many authors have addressed this issue [18,19,23]. In our column bioreactor, we identified the recycling step as the most efficient parameter. Variations thereof were also tested, such as the stripping with air during the hydrolysis step, but the efficiency of mixing was unsatisfying (indicated by precipitation of a high number of solid particles under the sparger). If an efficient hydrolysis step is done, fermentation and separation are improved by successful liquefaction and the reduction in the concentration of solid particles. The solid particle reduction was in the range of 30.5 to 56.3% after the hydrolysis step. An increment in hydrolyzed sugar concentration cG had an overall positive effect on the ethanol production (see Figure 3a,c). The measured carbohydrate concentration was in the range from 20.98 g L−1 to 50.77 g L−1. Consequently, the concentration of ethanol during the fermentation step was in the range of 5.3 to 18.2 g L−1, with the efficiency ranging from 50 to 97% according the theoretical yield. For comparison, Taylor et al. [16] using an average glucose concentration in the fermenter of 9 g L−1, were producing 88% of the maximum theoretically yield of ethanol.
As the three-step process fermentation followed the hydrolysis, the overall efficiency strongly depends on the hydrolysis. As mentioned before, a lower efficiency was observed in experiments employing a low recycling ratio (0.5 L h−1), in which insufficient mixing reduced the yields after the hydrolysis and fermentation step.
In the presented study ethanol separation from the fermentation broth was conducted in the third step by an in-situ vacuum-stripping process. CO2 was selected as carrier gas at a flow rate of 20 L h−1. Higher CO2 flow rates decrease the temperature in the column bioreactor (data not shown) [24]. A pressure of 25 kPa was selected as the minimum under-pressure as a result of the equipment limitations. The in-situ gas stripping vacuum system was additionally evaluated at different pressures (25, 50 and 100 kPa) based on the concentration of ethanol collected as condensate in the cooled column. The effect of pressure on the in situ vacuum-stripping is presented in Figure 4a and Figure 4c. The plane shape of the diagram indicates an important influence of the pressure on the separation efficiency. For the lower pressure, higher changes in the ethanol concentration in the condensate were measured with an additional positive effect on the separation efficiency. A plot of the ethanol concentrations in the condensate as a function of the SBP loading and ethanol (produced by fermentation) for the vacuum-stripping step is shown in Figure 4b. High solid loadings (<120 g L−1) and high recycling ratios (<1 L h−1) improved ethanol production in the fermentation step. Consequently, a similar trend was observed in the vacuum-stripping step for solid loadings, which is the result of the higher ethanol production observed in these ranges (Figure 3b and Figure 4b).
Mathematical models describing the response variations (sugars and ethanol concentrations) as a function of variances in the three-step hydrolysis, fermentation and in-situ gas stripping vacuum assisted process of ethanol production from sugar beet pulp are shown in Table 1. All mathematical models describing the responses variations presented quadratic terms (Figure 2, Figure 3 and Figure 4). To obtain a deeper understanding of the process, we performed in-depth statistical analyses of the obtained data and optimized the model for the vacuum assisted gas stripping recovery system for ethanol removal.

3.2. Statistical Analysis and Optimisation of Integrate Ethanol Production Process

In order to visualize the function of three variables-factors (recycling ratio, solid concentration and pressure) from the three-dimensional data presented in Figure 2, Figure 3 and Figure 4 contour plots from these graphs were created (Figure 5).
This contour plot shows the level curves from two of the three-dimensional graphs as a function of recycling ratio, solid concentration and pressure. To establish such a plot, the matrix that holds the values of the function was created and the contour plot of that matrix generated. The plot of the function of the three responsive variables is shown in Figure 5 (for recycling rate and solid SBP concentration Figure 5a; and Figure 4b for solid SBP concentration and pressure). As the indication of the optimum factor ranges for the integrated process, overlapping of the convergence areas is observed in Figure 5a.
Corresponding ethanol yields obtained after in-situ vacuum assisted gas stripping recovery system are presented in Table 2. The ethanol yield depends on a pressure but also on a concentration of ethanol in a fermenter and condensate. The highest ethanol yield obtained was 31.50% at 25 kPa with a measured mass of ethanol in fermenter and condensate of 17.30 g and 5.45 g, respectively. The lowest ethanol yield of 5.66% was obtained at 100 kPa under which we measured the highest mass of ethanol in a fermenter. Lower the pressure higher the ethanol yield was observed.
Using function analyses, the optimal ranges of the investigated factors (pressure rate, recycling ratio and solid concentration) for each of the studied stages were determined (Table 3). Table 3 represents optimal parameters (factors) of the in-situ gas stripping vacuum assisted recovery system for ethanol removal from the column bioreactor. Calculated optimum values of the selected factors (pressure rate, recycling ratio and solid concentration) were different for the hydrolysis and fermentation process stages as well as for the in-situ vacuum stripping processes. Optimal hydrolysis was achieved at a recycling ratio of 1.26 L h−1 and employing an SBP concentration of 156 g L−1. However, optimal values calculated for the fermentation stages were 1.45 L h−1 for the recycling ratio at an SBP concentration of 149 g L−1.
Observed results indicate differences in relation to the mixing (recycling) regime and the rheology of the SBP-slurry in the tested bioreactor system. The increase in viscosity over time is a result of the release of polymeric components during the hydrolysis, which consequently cause an increase in the optimum value of the recycling rate during the fermentative step [23]. Higher recycling rates, effective mixing and an active yeast culture used during the fermentation step ensure optimal conditions. Optimization results gave a sugar concentration of 75.4 g L−1 after hydrolysis. The maximal sugar concentration in our experimental approach was 50.61 g L−1 owing to the technical limitations of our column bioreactor in terms of the maximum SBP (solid) loading than can be reliably stirred. Further experimental studies on this issue are needed in order to evaluate the full potential of our computational approach. The subsequent fermentation step was conducted successfully with a maximum ethanol concentration of 18.2 g L−1. The maximal ethanol concentration calculated for the vacuum stripping was in good agreement with the average values of the ethanol concentration measured during the fermentation step (average value 13.2 g L−1 for fermentation, and optimum at 15.5 g L−1 for vacuum stripping step in the fermenter as well as 62 g L−1 in the condensate). These results indicate the possibility to further enhance the gas stripping vacuum assisted recovery system using simultaneous fermentation and vacuum assisted in-situ gas stripping ethanol recovery processes. On the contrary, the optimized SBP concentration obtained from our computational approach was beyond the investigation ranges (191 g L−1). Also, the pressure could not be adjusted to values below 20 kPa with the herein employed setup. Previous investigations of similar processes arrived at comparable conclusions regarding the process parameter optimization [20]. A major advantage of such simultaneous processes is the reduction of operational costs, but the overall process efficiency is reduced as a consequence of the complexity of the process setup, which requires fine-tuning of many process parameters which are simultaneously conducted in one step. Additional statistical analyses of different stages investigated through this research are presented in Figure 6.
To verify the effects of each operational variable in the responses, Pareto charts were generated (Figure 6). In Figure 6, bars extending to the vertical line correspond to the effects of a 95% confidence level. As can be seen from the figure, the recycling ratio and the pressure exerted a significance level of p < 0.05. For the hydrolysis step, the recycling rate was a significant parameter with the highest p value (Figure 6a Pareto chart). The concentration of SBP was insignificant for the hydrolysis as well as for the fermentation step. According to the adaptation of mixing (recycling) regime to the solid concentration, this observation indicates column bioreactor efficiency in the semi-solid process application. If mixing significantly influence process then process could be optimized by this parameter changes. On the other hand, un-significant of the SBP concentration indicate ability to conduct efficient process in the column bioreactor with high solid concentration by adaptation of mixing and recycling regime. According to the Pareto charts (Figure 6a,c), recycling rates and pressure showed to be the most significant factors for the analyzed three step processes, although with the different effects. An increase in the recycling rate had a positive effect on the hydrolysis, while decreases in vacuum (pressure) enhanced the ethanol recovery. Table 4 summarizes the literature reports on lignocellulosic biomass fermentation for bioethanol production and compares pretreatment and fermentation conditions, as well as theoretical and corresponding ethanol yields.

4. Conclusions

In this study, we tested a novel vacuum assisted in-situ gas striping recovery system for ethanol removal from a column bioreactor. Using a semi-solid process combining SBP hydrolysis and fermentation, the impact of the pressure rate, the recycling ratio and the solid concentration on the overall process was assessed. Following a statistical analysis, the recycling and vacuum ratio had the strongest impact on ethanol production. Using Pareto charts, we show that the recycling ratio is the most important variable affecting the hydrolysis step, and that the pressure ratio is the most important variable affecting the vacuum stripping step. The herein established mathematical models that describe these hydrolysis/fermentation processes can be further used for the ethanol production optimization. Additionally, these results can be utilized for the development of an integrated simultaneous fermentation and in-situ gas striping vacuum distillation process. Future trends of this research will address the scale-up for industrial bioethanol production.

Author Contributions

Conceptualization, T.R.; Methodology, D.O. and T.R.; Software, M.A. and T.R.; Validation, T.R. and R.L.; Formal analysis, M.A., D.O. and T.R.; Investigation, M.A. and D.O.; Data curation, M.A. and T.R.; Writing—original draft preparation, M.A. and T.R.; Writing—review and editing, M.A. and R.L.; Supervision, T.R. and B.Š.

Funding

This research received no external funding.

Acknowledgments

This work was supported financially by the Croatian Science Foundation under the project No. 9158 “Sustainable production of bioethanol and biochemicals from agricultural waste lignocellulosic raw materials”.

Conflicts of Interest

The authors declare no conflict of interest.

Abbreviations

cGhydrolyzed sugar concentration (g L−1)
cEtOHconcentration of ethanol (g L−1)
cDM SBP (Hydrolysis)concentration of sugar beet pulp dry matter during hydrolysis (g L−1)
cEtOH (Fermenter)concentration of ethanol in fermenter (g L−1)
cEtOH (Condensate)concentration of ethanol in condensate (g L−1)
cDM SBP+YEASTconcentration of sugar beet pulp dry matter and yeast (g L−1)
FLRrecycling ratio (L h−1)
ppressure (kPa)

References

  1. Cysewski, G.R.; Wilke, C.R. Rapid ethanol fermentations using vacuum and cell recycle. Biotechnol. Bioeng. 1997, 19, 1125–1143. [Google Scholar] [CrossRef]
  2. Silva, F.L.D.H.; Rodrigues, M.I.; Maugeri, F. Dynamic modeling simulation and optimization of an extractive continuous alcoholic fermentation process. J. Chem. Technol. Biotechnol. 1999, 74, 176–182. [Google Scholar] [CrossRef]
  3. Liu, H.S.; Hsu, H.W. Analysis of gas stripping during ethanol fermentation-1 in a continuous stirred tank reactor. Chem. Eng. Sci. 1990, 45, 1289–1299. [Google Scholar] [CrossRef]
  4. Daugulis, A.J.; Axford, D.B.; McLellan, P.J. The economics of ethanol production by extractive fermentation. Can. J. Chem. Eng. 1991, 69, 488–497. [Google Scholar] [CrossRef]
  5. Gryta, M.; Morawski, A.W.; Tomaszewske, M. Ethanol production in membrane distillation bioreactor. Catalys. Today 2000, 56, 159–165. [Google Scholar] [CrossRef]
  6. Liu, Z.; Zeng, A.W. Ethanol production by strip-flash fermentation. Chem. Eng. 2008, 36, 50–53. [Google Scholar]
  7. Mariano, A.P.; Mohammad, J.K.; Atala, D.I.P.; Filho, F.M.; Wolf Maciel, M.R.; Filho, R.M.; Stuart, P. Energy requirements for butanol recovery using the flash fermentation technology. Energy Fuel 2011, 25, 2347–2355. [Google Scholar] [CrossRef]
  8. Qureshi, N.; Blaschek, H.P. Recovery of butanol from fermentation broth by gas stripping. Renew. Energy 2001, 22, 557–564. [Google Scholar] [CrossRef]
  9. Roychoudhury, P.K.; Ghose, T.K.; Ghosh, P.; Chotani, G.K. Vapor liquid equilibrium behavior of aqueous ethanol solution during vacuum coupled simultaneous saccharification and fermentation. Biotechnol. Bioeng. 1986, 28, 972–976. [Google Scholar] [CrossRef] [PubMed]
  10. Walsh, P.K.; Liu, C.P.; Findley, M.E.; Liapis, A.I.; Siehr, D.J. Ethanol separation from water in a two-stage adsorption process. Biotechnol. Bioeng. Symp. 1983, 13, 629–647. [Google Scholar]
  11. Pham, C.B.; Motoki, M.; Matsumura, M.; Kataoka, H.J. Simultaneous ethanol fermentation and stripping process coupled with rectification. Ferment. Bioeng. 1989, 68, 25–31. [Google Scholar] [CrossRef]
  12. Taylor, F.; Kurantz, M.J.; Goldberg, N.; McAloon, A.J.; Craig, J.C., Jr. Dry-grind process for fuel ethanol by continuous fermentation and stripping. Biotechnol. Progr. 2000, 16, 541–547. [Google Scholar] [CrossRef] [PubMed]
  13. Ezeji, T.C.; Qureshi, N.; Blaschek, H.P. Production of acetone butanol (AB) from liquefied corn starch, a commercial substrate, using Clostridium beijerinckii coupled with product recovery by gas stripping. J. Ind. Microbiol. Biotechnol. 2007, 34, 771–777. [Google Scholar] [CrossRef] [PubMed]
  14. Zhang, J.; Liu, H.J.; Liu, D.H. Effect of different types of gas in gas stripping ethanol fermentation (GSEF). Chin. J. Process. Eng. 2005, 5, 349–352. [Google Scholar]
  15. Márquez, M.A.; Velloso, A.A. Sistema de Fermentaçăo de Etanol (Ethanol Fermentation System). Brazilian Patent PI 0801209-1, 14 April 2008. [Google Scholar]
  16. Taylor, F.; Marquez, M.A.; Johnston, D.B.; Goldberg, N.M.; Hicks, K.B. Continuous high-solids corn liquefaction and fermentation with stripping of ethanol. Bioresour. Technol. 2010, 101, 4403–4408. [Google Scholar] [CrossRef] [PubMed]
  17. De Vrije, T.; Budde, M.; van der Wal, H.; Claassen, P.A.; López-Contreras, A.M. “In situ” removal of isopropanol, butanol and ethanol from fermentation broth by gas stripping. Bioresour. Technol. 2013, 137, 153–159. [Google Scholar] [CrossRef] [PubMed]
  18. Chen, H.Z.; Liu, Z.H.; Dai, S.H. A novel solid state fermentation coupled with gas stripping enhancing the sweet sorghum stalk conversion performance for bioethanol. Biotechnol. Biofuels 2014, 7, 53. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  19. Sonego, J.L.S.; Lemos, D.A.; Pinto, C.E.M.; Cruz, A.J.G.; Badino, A.C. Extractive Fed-Batch Ethanol Fermentation with CO2 Stripping in a Bubble Column Bioreactor. Energy Fuels 2016, 30, 748–757. [Google Scholar] [CrossRef]
  20. Jin, M.; Sarks, C.; Bals, B.D.; Posawatz, N.; Gunawan, C.; Dale, B.E.; Balan, V. Toward high solids loading process for lignocellulosic biofuel production at a low cost. Biotechnol. Bioeng. 2017, 114, 980–989. [Google Scholar] [CrossRef] [PubMed]
  21. Andlar, M.; Rezić, I.; Oros, D.; Kracher, D.; Ludwig, R.; Rezić, T.; Šantek, B. Optimization of enzymatic sugar beet hydrolysis in a horizontal rotating tubular bioreactor. J. Chem. Technol. Biotechnol. 2016, 92, 623–632. [Google Scholar] [CrossRef]
  22. Kracher, D.; Oros, D.; Yao, W.; Preims, M.; Rezić, I.; Haltrich, D.; Rezić, T.; Ludwig, R. Fungal secretomes enhance sugar beet pulp hydrolysis. Biotechnol. J. 2014, 9, 483–492. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  23. Rezić, T.; Oros, D.; Marković, I.; Kracher, D.; Ludwig, R.; Šantek, B. Integrated hydrolastion and fermentation of the sugar beet pulp to bioethanol. J. Microbiol. Biotechnol. 2013, 23, 1244–1252. [Google Scholar] [CrossRef] [PubMed]
  24. Oros, D. Development of Sustainable Processes for Bioethanol Production. Ph.D. Thesis, Faculty of Food Technology and Biotechnology, University of Zagreb, Zagreb, Croatia, 2013. [Google Scholar]
  25. Miller, G.L. Use of dinitrosalicylic acid reagent for determination of reducing sugars. Analyt. Chem. 1959, 31, 426–428. [Google Scholar] [CrossRef]
  26. Phillips, C.M.; Iavarone, A.T.; Marletta, M.A. Quantitative proteomic approach for cellulose degradation by Neurospora crassa. J. Proteome Res. 2011, 10, 4177–4185. [Google Scholar] [CrossRef] [PubMed]
  27. Tian, C.; Beeson, W.T.; Iavarone, A.T.; Sun, J.; Marletta, M.A.; Cate, J.H.D.; Glass, N.L. Systems analysis of plant cell wall degradation by the model filamentous fungus Neurospora crassa. Proc. Natl. Acad. Sci. USA 2009, 106, 22157–22162. [Google Scholar] [CrossRef] [PubMed]
  28. Fushinobu, S. Metalloproteins: A new face for biomass breakdown. Nat. Chem. Biol. 2014, 10, 88–89. [Google Scholar] [CrossRef] [PubMed]
  29. Cha, Y.-L.; An, G.H.; Yang, J.; Moon, Y.-H.; Yu, G.-D.; Ahn, J.-W. Bioethanol production from Miscanthus using thermotolerant Saccharomyces cerevisiae mbc 2 isolated from the respiration-deficient mutants. Renew. Energy 2015, 80, 259–265. [Google Scholar] [CrossRef]
  30. Kumar, S.; Dheeran, P.; Singh, S.P.; Mishra, I.M.; Adhikari, D.K. Continuous ethanol production from sugarcane bagasse hydrolysate at high temperature with cell recycle and in-situ recovery of ethanol. Chem. Eng. Sci. 2015, 138, 524–530. [Google Scholar] [CrossRef]
  31. Lopez-Linares, J.C.; Romero, I.; Cara, C.; Ruiz, E.; Castro, E.; Moya, M. Experimental study on ethanol production from hydrothermal pretreated rapeseed straw by simultaneous saccharification and fermentation. J. Chem. Technol. Biotechnol. 2014, 89, 104–110. [Google Scholar] [CrossRef]
  32. Gonçalves, F.A.; Ruiz, H.A.; Nogueira, C.C.; Santos, E.S.; Teixeira, J.A.; Macedo, G.R. Comparison of delignified coconuts waste and cactus for fuel-ethanol production by the simultaneous and semi-simultaneous saccharification and fermentation strategies. Fuel 2014, 131, 66–76. [Google Scholar] [CrossRef] [Green Version]
  33. Narra, M.; James, P.; Balasubramanian, V. Simultaneous saccharification and fermentation of delignified lignocellulosic biomass at high solid loadings by a newly isolated thermotolerant Kluyveromyces sp. for ethanol production. Bioresour. Technol. 2015, 179, 331–338. [Google Scholar] [CrossRef] [PubMed]
  34. Kumagai, A.; Kawamura, S.; Lee, S.-H.; Endo, T.; Rodriguez, M., Jr.; Mielenz, J.R. Simultaneous saccharification and fermentation and a consolidated bioprocessing for Hinoki cypress and Eucalyptus after fibrillation by steam and subsequent wet-disk milling. Bioresour. Technol. 2014, 162, 89–95. [Google Scholar] [CrossRef] [PubMed]
  35. Sonego, J.L.S.; Lemos, D.A.; Rodriguez, G.Y.; Cruz, A.J.G.; Badino, A.C. Extractive Batch Fermentation with CO2 Stripping for Ethanol Production in a Bubble Column Bioreactor: Experimental and Modeling. Energy Fuels 2014, 28, 7552–7559. [Google Scholar] [CrossRef]
  36. Ahmed, I.N.; Sutanto, S.; Huynh, L.H.; Ismadji, S.; Ju, Y.-H. Subcritical water and dilute acid pretreatments for bioethanol production from Melaleuca leucadendron shedding bark. Biochem. Eng. J. 2013, 78, 44–52. [Google Scholar] [CrossRef]
  37. Xue, C.; Zhao, J.; Liu, F.; Lu, C.; Yang, S.-T.; Bai, F.-W. Two-stage in situ gas stripping for enhanced butanol fermentation and energy-saving product recovery. Bioresour. Technol. 2013, 135, 396–402. [Google Scholar] [CrossRef] [PubMed]
  38. Manzanares, P.; Negro, M.J.; Oliva, J.M.; S´aez, F.; Ballesteros, I.; Ballesteros, M.J. Different process configurations for bioethanol production from pretreated olive pruning biomass. J. Chem. Technol. Biotechnol. 2011, 86, 881–887. [Google Scholar] [CrossRef]
  39. Zhang, J.; Chu, D.; Huang, J.; Yu, Z.; Dai, G.; Bao, J. Simultaneous Saccharification and Ethanol Fermentation at High Corn Stover Solids Loading in a Helical Stirring Bioreactor. Biotechnol. Bioeng. 2010, 105, 718–728. [Google Scholar] [CrossRef] [PubMed]
Figure 1. Schematic representation of the vacuum assisted in-situ gas stripping recovery system with the column bioreactor. 1. CO2 bottle; 2. Gas heater; 3. Column bioreactor; 4. Condenser; 5. Vacuum pump; 6. Gas rotor-flowmeter; 7. Peristaltic pump.
Figure 1. Schematic representation of the vacuum assisted in-situ gas stripping recovery system with the column bioreactor. 1. CO2 bottle; 2. Gas heater; 3. Column bioreactor; 4. Condenser; 5. Vacuum pump; 6. Gas rotor-flowmeter; 7. Peristaltic pump.
Fibers 06 00088 g001
Figure 2. Changes in sugar concentrations in the hydrolysis step with investigated factors (recycling ratio and solid concentration).
Figure 2. Changes in sugar concentrations in the hydrolysis step with investigated factors (recycling ratio and solid concentration).
Fibers 06 00088 g002
Figure 3. Changes of ethanol concentration in the fermentation step with investigated factors (recycling ratio, solid and carbohydrates concentration) (ac).
Figure 3. Changes of ethanol concentration in the fermentation step with investigated factors (recycling ratio, solid and carbohydrates concentration) (ac).
Fibers 06 00088 g003aFibers 06 00088 g003b
Figure 4. Changes of ethanol concentration in the vacuum assisted gas stripping recovery step with investigated factors (vacuum rate, solid and ethanol concentration) (ac).
Figure 4. Changes of ethanol concentration in the vacuum assisted gas stripping recovery step with investigated factors (vacuum rate, solid and ethanol concentration) (ac).
Fibers 06 00088 g004aFibers 06 00088 g004b
Figure 5. Contour plots of sugar- and ethanol concentrations during hydrolysis, fermentation and vacuum stripping as a function of (a) recycling ratio and solid concentration; (b) pressure and solid concentration.
Figure 5. Contour plots of sugar- and ethanol concentrations during hydrolysis, fermentation and vacuum stripping as a function of (a) recycling ratio and solid concentration; (b) pressure and solid concentration.
Fibers 06 00088 g005
Figure 6. Pareto charts for the effects of the vacuum ratio, recycling ratio and sugar beet pulp (SBP) concentration in the: hydrolysis step (a); fermentation step (b) and vacuum stripping step (c).
Figure 6. Pareto charts for the effects of the vacuum ratio, recycling ratio and sugar beet pulp (SBP) concentration in the: hydrolysis step (a); fermentation step (b) and vacuum stripping step (c).
Fibers 06 00088 g006
Table 1. Polynomial equations fitted to the results of the three-step hydrolysis, fermentation and in-situ gas stripping vacuum assisted process of ethanol production from sugar beet pulp.
Table 1. Polynomial equations fitted to the results of the three-step hydrolysis, fermentation and in-situ gas stripping vacuum assisted process of ethanol production from sugar beet pulp.
ResponseModel Equation
Hydrolysis step
cG (g L−1) against FLR (L h−1) and cDM,SBP (Hydrolysis) (g L−1)cG (g L−1) = −37.0244 + 95.9033 × x + 0.3898 × y − 48.7733 × x × x + 0.1716 × x × y − 0.0019 × y × y
Fermentation step
cEtOH (Fermenter) (g L−1) against FLR (L h−1) and cG (g L−1)cEtOH (Fermenter) (g L−1) = 1.0341 − 1.6724 × x + 0.4049 × y + 2.7967 × x × x − 0.0466 × x × y − 0.0017 × y × y
cEtOH (Fermenter) (g L−1) against FLR (L h−1) and cDM,SBP (Fermenter) (g L−1)cEtOH (Fermenter) (g L−1) = 2.095 + 18.942 × x + 0.0064 × y − 9.4392 × x × x + 0.0899 × x × y − 0.0005 × y × y
cEtOH (Fermenter) (g L−1) against cG (g L−1) and cDM,SBP (Fermenter) (g L−1)cEtOH (Fermenter) (g L−1) = 10.7033 + 0.1937 × x − 0.1385 × y 0.0032 × x × x + 0.0035 × x × y + 4.7931 × 10−5 × y × y
Vacuum-striping step
cEtOH (Condensate) (g L−1) against cEtOH (Fermenter) (g L−1) and Pressure (kPa)cEtOH (Condensate) (g L−1) = 6.9934 + 4.1873 × x − 0.0298 × y − 0.0484 × x × x − 0.0014 × x × y + 1.9843 × 10−5 × y × y
cEtOH (Condensate) (g L−1) against cEtOH (Fermenter) (g L−1) and cDM, SBP+yYeast (g L−1)cEtOH (Condensate) (g L−1) = −156.5581 + 24.9372 × x+0.4586 × y − 0.8373 × x × x − 0.021 × x × y + 0.0006 × y × y
cEtOH (Condensate) (g L−1) against Pressure (kPa) and cDM, SBP+Yeast (g L−1)cEtOH (Condensate) (g L−1) = 61.9621 − 0.1165 × x + 0.2763 × y + 7.2934 × 10−5 × x × x − 4.8328 × 10−6 × x × y − 0.0017 × y × y
Table 2. Ethanol yields (%) obtained after in-situ vacuum assisted gas stripping.
Table 2. Ethanol yields (%) obtained after in-situ vacuum assisted gas stripping.
Pressure (kPa)mEtOH (Fermenter) (g)mEtOH (Condensate) (g)% EtOH
2510.962.9426.82
10010.210.969.40
505.301.8234.34
10012.470.756.01
5014.521.9413.36
2517.305.4531.50
5013.701.5311.17
2515.603.0119.29
10018.201.035.66
Table 3. Optimal and critical values for parameters (factors) tested in gas striping vacuum assisted recovery system for ethanol removal from the column bioreactor.
Table 3. Optimal and critical values for parameters (factors) tested in gas striping vacuum assisted recovery system for ethanol removal from the column bioreactor.
FactorsHydrolysisFermentationVacuum-Striping
FLR (L h−1)1.251.45-
cDM,SBP (g L−1)156149191 (out of range)
cG (g L−1)50.6175.4 (out of the range)-
cEtOH (Fermenter) (g L−1)-13.215.5
cEtOH (Condensate) (g L−1) 62
Pressure (kPa)--<20 (out of range)
Table 4. Overview of literature reports on lignocellulosic biomass fermentation for bioethanol production.
Table 4. Overview of literature reports on lignocellulosic biomass fermentation for bioethanol production.
FeedstockPretreatment ConditionsFermentation ConditionsStrainTheoretical Ethanol Yield (%)Corresponding Ethanol Yield (g L−1)Literature
Sugar beet pulpEnzyme pretreatment with Ultrazym AFP-L (14.0 ± 0.1 g dm3) and Neurospora crassa crude extract (0.1 mg protein per g of SBP)Semi-solid fermentation in a column bioreactor at 30 °C and pH 4.5 for 24 hSaccharomyces cerevisiae Y9 (ATCC® MYA-49419762this study
Miscanthus1.5 M NaOH with stirring at 120 rpm and heated to 150 °C for 30 minLiquid-state saccharification and fermentation at 42 °C with shaking at 150 rpmSaccharomyces cerevisiae 792886.3029.50[29]
Sugarcane bagasseAcid hydrolysis of sugarcane bagasse in two stagesContinuous fermentation with cell recycle system at a temperature of 50 °C and a pH of 5.0thermotolerant yeast Kluyveromyces sp. IIPE4539656.30[30]
Rapeseed strawLiquid hot water pretreatment at 217 °C for 42 minLiquid-state simultaneous saccharification and fermentation in an orbital shaker at 150 rpmSaccharomyces cerevisiae, enzymes: Celluclast (NS50013) cellulases from Trichoderma reesei and β-glucosidase (NS50010) from Aspergillus niger66.6017.20[31]
Sweet sorghum stalkSterilization at 121 °C for 15 minTraditional static solid-state fermentation (TS-SSF) and gas stripping solid state fermentation (GS-SSF)Saccharomyces cerevisiae77.527[18]
Coconut fibreSequential alkaline hydrogen peroxide (Alk-H2O2)–sodium hydroxide (NaOH)Semi-simultaneous saccharification and fermentation at 30 °C for 40 hSaccharomyces cerevisiae, Pichia stipites and Zymomonas mobilis89.159.32[32]
Rice strawDilute acid pretreatment, then delignification with 0.5% NaOH at 121 °C for 30 minSimultaneous saccharification and fermentation with agitation at 120 rpm for 72 h at 42 °CKluyveromyces sp.84.6024.63[33]
Hinoki cypressSteam treatment (150 °C for 2 h) with wet disk millingYeast-based simultaneous saccharification and fermentation at 58 °C with shaking at 125 rpmS. cerevisiae D5A (ATCC 200062), C. thermocellum (ATCC27405)63.40-[34]
Sugar cane molassesSterilization at 121 °C and 15 psig for 30 minExtractive batch fermentation using CO2 as a stripping gascommercial lyophilized Saccharomyces cerevisiae25% higher compared with to the conventional fermentation43.30[35]
Paper bark treeSubcritical water at 180 °C for 30 minAnaerobic condition in an orbital shaker (150 rpm, 37 °C) for 120 hEthanol Red® Saccharomyces cerevisiae9124.70[36]
Fermentation P2 mediumSterilization at 121 °C and 15 psig for 30 minIntegrated fermentation system with intermittent gas stripping (CO2 and H2) at 37 °C and pH 5.0Clostridium acetobutylicum JB200 (ATCC 55025)29.66[37]
Olive tree pruningLiquid hot water pretreated at 210 °C with magnetic agitationLiquid-state simultaneous saccharification and fermentation at 35 °C for 72 h and 150 rpmSaccharomyces cerevisiae5031.10[38]
Corn stoverSteam explosion at 200 °C for 4 minSemi-continuous liquid-state simultaneous saccharification and fermentation (37 °C for 60 h)yeast mutant strain Saccharomyces cerevisiae DQ152.1040.60[39]

Share and Cite

MDPI and ACS Style

Andlar, M.; Oros, D.; Rezić, T.; Ludwig, R.; Šantek, B. In-Situ Vacuum Assisted Gas Stripping Recovery System for Ethanol Removal from a Column Bioreactor. Fibers 2018, 6, 88. https://0-doi-org.brum.beds.ac.uk/10.3390/fib6040088

AMA Style

Andlar M, Oros D, Rezić T, Ludwig R, Šantek B. In-Situ Vacuum Assisted Gas Stripping Recovery System for Ethanol Removal from a Column Bioreactor. Fibers. 2018; 6(4):88. https://0-doi-org.brum.beds.ac.uk/10.3390/fib6040088

Chicago/Turabian Style

Andlar, Martina, Damir Oros, Tonči Rezić, Roland Ludwig, and Božidar Šantek. 2018. "In-Situ Vacuum Assisted Gas Stripping Recovery System for Ethanol Removal from a Column Bioreactor" Fibers 6, no. 4: 88. https://0-doi-org.brum.beds.ac.uk/10.3390/fib6040088

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop