JP2012187115A - Method for continuously producing ethanol - Google Patents

Abstract

An alcohol-fermenting yeast having resistance to a fermentation-inhibiting substance limonene and a method for producing ethanol using the same are provided.
An alcohol-fermenting yeast which is a Saccharomyces cerevisiae (accession number NITE P-890) having resistance to limonene and capable of growing in the presence of limonene at a concentration of 0.1 to 0.5 wt%, and the same Ethanol production method using
[Selection] Figure 2

Description

The present invention relates to an alcohol-fermenting yeast having resistance to a fermentation inhibitory substance limonene and an ethanol production method using the same.

Bioethanol, which is an alternative liquefied fuel, can be produced by adding yeast to the fruit juice and subjecting it to ethanol fermentation. The conversion technology to bioethanol by fermentation of waste waste juice is very beneficial because it uses biomass that does not compete with food as a raw material.
As a technology for producing ethanol using this juice, there is a technology for producing a juice from citrus fruits, removing pulp by centrifuging citrus molasses obtained by concentrating the juice and performing ethanol fermentation with Saccharomyces yeasts, etc. It is known (see, for example, Patent Document 1).

JP 2002-153231 A

However, citrus fruits contain 0.2 to 0.5 wt% of limonene (chemical formula: C ₁₀ H ₁₆ ), which is a terpenoid oil component. This limonene is known to inhibit ethanol fermentation and is mostly contained in the skin. However, by squeezing the fruit including the fruit skin mechanically in the squeezing process and the brewing process, a part of the fruit is released into the liquid and is present mainly in micellar form in the juice. According to the measurement results of the inventor, the limonene concentration in the micelle form of limonene (0.2-0.5 wt%) in the juice is as small as 0.01-0.04 wt%. is there.
However, according to the results of an experiment in which micellar (oily) limonene was added to a YPD medium and ethanol fermentation was performed using general yeast, the ethanol production rate rapidly decreased as the added limonene concentration increased. For example, when 0.1% v / v of limonene was added, the ethanol production rate was greatly reduced to about 20%. In general, yeast is present as solid fine particles in a sugar solution and tends to adsorb oily substances. Therefore, the reason for such an experimental result is presumed that the added small amount (0.05% v / v) of limonene (oil) adsorbed to the yeast and caused fermentation inhibition. Therefore, in order to remove limonene, which is a fermentation inhibitor, from the juice, the solid content that accounts for 75% or more of the limonene is removed, and a micellar form that exists as a light liquid (oily substance). Limonene also had to be removed. However, even if limonene was removed from the raw material in advance by a treatment such as three-phase centrifugation, the conventional general yeast had an induction period, so the fermentation was not stable and the fermentation rate was slow. Therefore, fermentability tends to be unstable due to the influence of contamination and the like, and it has been difficult to maintain high fermentability over a long period of time.
This invention is made | formed in view of this situation, and it aims at providing the alcohol fermentative yeast which has tolerance to fermentation inhibitory substance limonene, and the ethanol manufacturing method using the same.

The alcohol-fermenting yeast according to the first invention meeting the above object is a genus Saccharomyces having resistance to limonene.

The alcohol-fermenting yeast according to the first invention further has high-temperature resistance.

The alcohol-fermenting yeast according to the first invention is Saccharomyces cerevisiae.

In the alcohol-fermenting yeast according to the first invention, Saccharomyces cerevisiae (Accession No. NITE P-890) is used.

The ethanol production method according to the second aspect of the invention that uses the above object uses the alcohol-fermentable yeast according to the first aspect of the invention.

In the ethanol production method according to the second invention, citrus fruits can be used as a raw material.

In the method for producing ethanol according to the second invention, a heavy liquid obtained by three-phase centrifugation of the citrus juice can be used as a raw material.

In the method for producing ethanol according to the second invention, citrus juice with an acidic substance added can be used as a raw material.

In the ethanol production method according to the second invention, the acidic substance is preferably nitric acid.

In the alcohol fermentable yeast of Claims 1-4, since limonene tolerance is higher than general yeast, ethanol can be produced | generated efficiently.

In particular, since the alcohol-fermentable yeast according to claim 2 has higher high-temperature resistance than general yeast, ethanol can be efficiently produced at high temperatures.

In the method for producing ethanol according to claims 5 to 9, ethanol can be generated more efficiently from a raw material containing limonene than when general yeast is used.

In particular, in the ethanol production method according to claim 6, when citrus fruits containing limonene are used as raw materials, ethanol can be generated more efficiently than when general yeast is used.

In particular, in the method for producing ethanol according to claim 7, since the limonene concentration becomes low, ethanol can be generated more efficiently.

In particular, in the method for producing ethanol according to claim 8, since propagation of miscellaneous bacteria is suppressed, ethanol can be generated more efficiently.

In particular, in the ethanol production method according to claim 9, there is no fear of corroding the steel material used in the ethanol production apparatus.

It is explanatory drawing which shows the base sequence of P-890 stock | strain which concerns on Example 1 of this invention. It is a microscope picture (1000-times multiplication factor) of the P-890 stock. It is a graph which shows the limonene tolerance of the P-890 strain. It is a graph which shows the high temperature tolerance of the P-890 strain. (A) and (B) are the graph which shows the batch fermentation characteristic of the said P-890 stock | strain, and the graph which shows the batch fermentation characteristic of general yeast, respectively. It is explanatory drawing which shows the ethanol fermentation characteristic by the fed-batch culture | cultivation of the P-890 strain. It is process drawing which shows each process of the ethanol manufacturing method which concerns on Example 3 of this invention. It is a block diagram which shows the outline | summary of the continuous fermentation apparatus used by an ethanol fermentation process. It is a graph (1) which shows an ethanol manufacturing result. It is a graph (2) which shows an ethanol manufacturing result. (A) and (B) are a graph (3) showing the ethanol production results of general yeast and a graph (4) showing the ethanol production results of the P-890 strain, respectively.

Subsequently, an embodiment of the present invention will be described with reference to the accompanying drawings for understanding of the present invention. The alcohol-fermenting yeast according to one embodiment of the present invention belongs to the genus Saccharomyces having limonene resistance. This alcohol-fermenting yeast further has high temperature resistance. When ethanol is produced using the alcohol-fermentable yeast according to the present embodiment, mandarin orange (an example of citrus fruits) is used as a raw material.
Hereinafter, “limonene resistance” refers to the property of yeast capable of ethanol fermentation at a yield of 86% or more in the presence of limonene at a concentration of 0.1 to 0.5 wt% in the raw material. “High temperature tolerance” refers to the property of yeast that can be fermented with ethanol in a yield of 86% or higher in an environment where the fermentation temperature is 40 ° C. or higher. Further, Saccharomyces cerevisiae having no limonene resistance and high temperature resistance is also referred to as “general yeast”.
Hereinafter, the present invention will be described with reference to examples.

(Separation of new yeast)
Tangerine juice was collected from the production line of a citrus juice factory harvested in Ehime Prefecture. This tangerine juice was diluted 1000-fold, spread on a YPD agar medium (containing 1% yeast extract, 2% peptone, and 2% glucose) and cultured at 30 ° C. for about 2 days.
Various yeasts colonized in the culture dish were picked up and purely cultured in a YPD medium (yeast extract 2%, peptone 2%, glucose 10% contained, pH 6.5-7.0).

(Yeast screening)
From each purely cultured yeast, yeast having limonene resistance was screened.
Specifically, ethanol fermentation was performed using several different types of sugar solutions as raw materials in the range of limonene concentration of 0.02 to 0.2% v / v. As a result, the limonene resistant strain was selected as a strain excellent in ethanol fermentability for each limonene concentration sugar solution. Among these limonene resistant strains, a strain with particularly high limonene resistance was deposited (Accession Number NITE P-890). Hereinafter, this deposited strain is referred to as “P-890 strain” in the present specification.

(Identification of P-890 strain)
DNA was extracted from the P-890 strain, and the D2LSUrDNA region was amplified by PCR. The base sequence of the obtained PCR product was determined by direct sequencing (see FIG. 1). Based on this base sequence, a blast (BLAST) search with a D2LSUrDNA sequence of a known microorganism on the database was performed to identify microorganisms presumed to be related species. As a result, as shown in Table 1, it was revealed that the P-890 strain is a yeast of the genus Saccharomyces cerevisiae.

(Mycological properties)
The P-890 strain has the following mycological properties.
1. Cell shape: spherical (see Fig. 2)
2. 2. Colony shape: white (no gloss), bowl-shaped Breeding mode: Multipolar budding 4. Optimal growth temperature: 30 ° C
5. Optimum growth pH: 4.0
6). Cohesiveness: None Utilization sugar: sucrose, glucose, fructose

(Limonene resistance test)
About P-890 stock | strain, limonene of arbitrary density | concentrations was added, batch fermentation (shaking culture) was performed, and ethanol fermentability was investigated. The experimental conditions are as follows.
<Experimental conditions>
1. Fermentation temperature: 30 ° C
2. Number of shakes: 120 rpm (amplitude 10 mm)
3. Fermentation time: 24 hours Ingredients: YPD medium

The results are shown in FIG. In the figure, the horizontal axis represents the amount of limonene added to the YPD medium (% v / v), and the vertical axis represents the ethanol production rate (%).
As is clear from the figure, for general yeast, the ethanol production rate decreases as the limonene concentration increases. On the other hand, for the P-890 strain, the ethanol production rate exceeded 90% and the ethanol production rate did not decrease until the limonene addition concentration reached about 0.1% v / v.

(High temperature resistance test)
Using a YPD medium, a batch fermentation experiment was conducted for 24 hours at fermentation temperatures of 30 ° C., 37 ° C., 40 ° C., 42 ° C., and 45 ° C. The experimental conditions are as follows.
<Experimental conditions>
1. Number of shakes: 120 rpm (amplitude 10 mm)
2. 2. Fermentation time: 24 hours Ingredients: YPD medium

The result is shown in FIG. In the figure, the horizontal axis represents temperature, and the vertical axis represents the ethanol production rate. Although there is a portion where the ethanol production rate slightly exceeds 100%, it is considered that the ethanol production rate was calculated to be large due to a measurement error.

As is clear from the figure, the general yeast was able to ferment only up to a fermentation temperature of 37 ° C., but the P-890 strain could be fermented at a high yield of 90% or higher up to the fermentation temperature of 40 ° C. That is, the P-890 strain was found to have high temperature resistance. Moreover, it became clear that P-890 strain | stump | stock has an ethanol production rate of about 70% even at 42 degreeC, and can ferment with a comparatively high yield.

(Ethanol fermentation test [1])
Batch culture was performed in the presence of limonene, and ethanol production and yeast growth were examined. The experimental conditions are as follows.
<Experimental conditions>
1. Fermentation temperature: 30 ° C
2. Stirring speed: 120rpm
3. Fermentation time: 24 hours Ingredients: Heavy liquid obtained by three-phase centrifugation of mandarin orange (Unshu mandarin) juice (adjusted to pH 3.5 by adding nitric acid)
The results for the P-890 strain are shown in FIG. In the figure, the horizontal axis represents time, and the vertical axis represents sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), fructose (fructose) concentration (g / L), ethanol concentration ( g / L) and yeast concentration (cells / ml).
For the general yeast shown in FIG. 5 (B), there was an induction period of about 8 hours. However, the P-890 strain did not have an induction period and started to grow after the start of culture. In addition, the P-890 strain had higher yeast growth rate and ethanol production rate than general yeast. Due to such characteristics, when the P-890 strain is used for ethanol fermentation, stable culture can be performed in a shorter period of time compared to general yeast, and efficient fermentation with a short average residence time is possible.

Furthermore, the conditions for the presence or absence of three-phase centrifugation and the presence or absence of nitric acid addition to the tangerine juice were changed, and ethanol production was similarly examined for the following three raw materials.
1) Tangerine juice that was adjusted to pH 3.5 by adding nitric acid (no three-phase centrifugation)
2) Heavy liquid obtained by three-phase centrifugation of tangerine juice (no pH adjustment)
3) Tangerine juice (no three-phase centrifugation, no pH adjustment)
The effect of the three-phase centrifugation is removal of limonene. Here, since P-890 strain has limonene resistance, it seems unnecessary to remove limonene. However, 1) Although the P-890 strain has limonene resistance, if the limonene concentration is low, further improvement of the ethanol production rate can be expected, and 2) limonene cannot be completely removed by three-phase centrifugation. Therefore, the presence or absence of the three-phase centrifugation for the orange juice juice is considered as a condition. Moreover, the effect of nitric acid addition is suppression of miscellaneous bacteria propagation. Details of the effects of the three-phase centrifugation and the addition of nitric acid will be described later.
The results under these conditions are shown in Tables 2 to 4, respectively.

Table 2 shows sucrose concentration (g / L), glucose concentration (g / L), fructose concentration (g / L), ethanol concentration (g / L) before and after fermentation for general yeast and P-890 strain, respectively. The ethanol production rate (%) was measured.

Table 3 shows sucrose concentration before and after fermentation (g / L), glucose concentration (g / L), fructose concentration (g / L), ethanol concentration (g / L), and general yeast and P-890 strain, respectively. The ethanol production rate (%) was measured.
In addition, about after fermentation, data are measured twice as after fermentation (1) and after fermentation (2). The average ethanol production rate (%) is an average of the ethanol production rates (%) measured twice.

Table 4 is the same data as Table 3.

As is apparent from Tables 2 to 4, all of the P-890 strains had a higher ethanol production rate than general yeast. In particular, in the tangerine juice (unprocessed raw material) with neither centrifugation nor pH adjustment, when the P-890 strain was used, the ethanol production rate was 15% higher than that of general yeast (see Table 4).

(Ethanol fermentation test [2])
Fed-batch culture was carried out using a heavy liquid obtained by three-phase centrifugation of a mandarin orange juice as a raw material, and ethanol production and yeast growth were examined. The experimental conditions are as follows.
<Experimental conditions>
1. Temperature: 30 ° C
2. Stirring speed: 150 rpm
3. Raw material supply: 3.3 ml / min
4). Reactor capacity: 5L
5. Air blowing amount: 0.05vvm
6). Amount of added yeast: 3.0% v / v
7). Ingredients: Tangerine (Unshu tangerine) dessert solution results are shown in FIG. In the figure, the horizontal axis represents time, and the vertical axis represents ethanol concentration (g / L) and yeast concentration (cells / tank).
As is apparent from the figure, there is an induction period of about 4 hours for general yeast in the limonene-concentrated solution subjected to the three-phase centrifugation treatment. In contrast, the P-890 strain does not have an induction period, and starts to grow immediately after the start of culture. In addition, the P-890 strain started to produce ethanol immediately after the start of the culture, and ethanol production reached its peak at 15 hours. That is, the P-890 strain was found to have a higher ethanol production rate than general yeast. That is, the P-890 strain does not have an induction period and can be stably fermented with respect to the raw material having a low limonene concentration that has been subjected to three-phase centrifugation.

(Ethanol production using P-890 strain [1])
P-890 strain was used, and ethanol was produced using Iyokan as an example of the raw material. First, the manufacturing method will be described.
As shown in FIG. 7, the ethanol production method includes a pre-process and a post-process. The pre-process has a squeezing process P1, a mixing process P2, and a brewing process P3. The post-process includes a three-phase centrifugal separation process P4, an acid mixing process P5, a fermentation process P6, and a distillation process P7. Hereinafter, each step will be described.

The squeezing step P1 is a step of squeezing Iyokan with a squeezing machine such as an inline method or a chopper pulper method. By this step, juice residue 11 and juice 12 are generated.

The mixing process P2 is a process of mixing slaked lime, which is an example of an alkaline substance, with the squeezed residue 11 generated in the squeezing process P1. Since the squeezed residue 11 produced | generated by the squeezing process P1 is a gel or a slurry form, it cannot press and it can drain efficiently. Therefore, it can be efficiently drained by adding and mixing slaked lime.

The de-juice process P3 is a process of pressing and dehydrating the juice residue 11 that has been easily pressed in the mixing process P2. By this step, a mash 13 and a mash 14 are produced.

The three-phase centrifugal separation step P4 is a step of three-phase centrifugal separation of the juice 13 generated in the juice removal step P3 into a heavy liquid portion 15, a light liquid portion 16, and a solid portion 17.
In the three-phase centrifugation step P4, limonene, which is a fermentation inhibiting substance contained in the juice 13, is removed together as a light liquid (oily substance) 16 and a solid content 17. As a result, the limonene concentration in the heavy liquid portion 15 can be 0.01 wt% or less, and the total limonene concentration including the solid content can be reduced to 0.1 wt% or less.

Thus, in this process, the growth property of the yeast at the time of ethanol fermentation improves by carrying out the three-phase centrifugation of the mash 13 and removing a fermentation inhibitor. As a result, the fermentability is stabilized and the ethanol production rate is increased.
In addition, since the three-phase centrifuge used at this process isolate | separates light liquid and heavy liquid with few specific gravity differences, it is preferable to use the disk-type centrifuge which can enlarge a sedimentation area. Separation is possible if the centrifugal force is 5000 G or more industrially.

The acid mixing step P5 is a step of mixing the heavy liquid portion 15 generated in the three-phase centrifugal separation step P4 with nitric acid, which is an example of an acidic substance, to generate the acid mixed solution 18. Specifically, it is a step of adding 60% concentrated nitric acid to the heavy liquid portion 15 generated in the three-phase centrifugal separation step P4, and stirring and mixing with a stirring pump or a stirrer. As a result, the pH of the heavy liquid 15 is adjusted to 3.5, and the acid mixture 18 is generated.
Since the specific gravity of nitric acid is heavier than the heavy liquid component 15 generated in the three-phase centrifugation step P4, the nitric acid is stirred constantly or periodically after the addition of nitric acid.

By this step, various germs in the acid mixed solution 18 are reduced to about 1/10 to 1/1000 before mixing with nitric acid. This pH is 1) the optimum pH for inhabiting various bacteria is 5.0 to 7.0, and 2) the optimum pH for growing yeast required for ethanol fermentation in the next step is 3. It is determined in consideration of 5 to 6.0. That is, in this step, the pH is adjusted so that yeast can grow in a state in which the propagation of various bacteria is suppressed. This pH is, for example, 3.0 to 4.0.

Fermentation process P6 is a process in which Saccharomyces cerevisiae P-890 strain is added to heavy liquid 15 (acid mixture 18) whose pH has been adjusted in acid mixing process P5, and ethanol fermentation is performed. This fermentation is continuous fermentation, but may be batch fermentation.

The distillation process P7 is a process of distilling the ethanol fermentation liquid produced in the fermentation process P6. By this step, ethanol 19 can be purified.

According to the said manufacturing process, ethanol production was performed using P-890 stock | strain.

First, Iyokan was squeezed as a raw material in the squeezing step P1. Next, slaked lime was mixed with the produced squeezed residue 11 in the mixing step P2. Next, the squeezed residue 11 in which slaked lime was mixed was pressed in the brewing process P3, and the brewing liquid 13 was produced | generated. Next, in the three-phase centrifugal separation process P4, the lysate 13 produced in the brewing process P3 was applied to a three-phase separator to separate the heavy liquid fraction 15. Next, in the acid mixing step P5, nitric acid was added to adjust the pH of the heavy liquid portion 15 to 3.5 and mixed for 2 hours to produce an acid mixed solution 18. And continuous fermentation was performed in fermentation process P6.

Here, the continuous fermentation apparatus 20 used in the fermentation process P6 will be described. As shown in FIG. 8, in the fermentation process P <b> 6, the acid mixed solution 18 (pH 3.5) as a raw material was sent from the pump 21 to the bioreactor 22. The bioreactor 22 was continuously fermented (average residence time: 24 hours). The fermentation liquid flows out from the upper part of the continuous fermentation apparatus 20 by overflow. During fermentation, sterilized air was blown into the fermentation broth in the bioreactor 22. Moreover, the fermented liquor was constantly stirred by the three-blade impeller 25. The internal temperature of the bioreactor 22 was maintained by a constant temperature bath 26.

Detailed fermentation conditions are as follows.
<Continuous fermentation conditions>
1. Fermentation temperature: 30 ° C
2. Stirring speed: 150 rpm
3. Fermentation time: 24 hours (residence time)
4). Amount of added yeast: 3.0% v / v
5. Reactor capacity: 5L
6). Dilution rate: 0.04 (1 / h)
7). Sterilization air blowing amount: 0.05vvm
8). Other: Change dilution ratio D in the range of 0.014 to 0.04 during continuous fermentation

The results are shown in FIG. In the figure, the horizontal axis represents elapsed time, and the vertical axis represents sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), fructose (fructose) concentration (g / L), total sugar. The concentration (g / L), ethanol concentration (g / L), and yeast concentration (cells / ml) are shown.
In this example, the dilution rate D was changed in the range of 0.014 to 0.04, but ethanol was stably generated regardless of the change of the dilution rate D. The average ethanol production rate was 105.4%. The average ethanol production rate exceeds 100%, and the following two reasons are considered. First, the sugars considered when calculating the average ethanol production rate are sucrose, glucose, and fructose, which is considered to be because the yeast utilized other sugars. Secondly, it is considered that the average ethanol production rate was calculated to be large due to the measurement error.

(Ethanol production using P-890 strain [2])
This embodiment is different from the third embodiment in that the centrifugation step P4 is omitted and the change range of the dilution rate D is two points. That is, after producing the brewing liquid in the brewing process P3, the centrifugal separation process P4 was omitted, and in the acid mixing process P5, nitric acid was added to the brewing liquid to produce an acid mixture having a pH of 3.5. The acid mixture was fed into the bioreactor 22 and the fermentation process P6 was performed. In addition, the limonene density | concentration (the total value of the limonene adhering to solid content and the limonene which exists in a liquid) of the acid liquid mixture which adjusted pH of the mash 13 was 0.2% v / v.

The results are shown in FIG. In the figure, the horizontal axis represents elapsed time (h), and the vertical axis represents sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), and fructose (fructose) concentration (g / L). , Total sugar concentration (g / L), ethanol concentration (g / L), and yeast concentration (cells / ml).
In this example, the dilution rate D was changed in the range of 0.04 to 0.08, but ethanol was stably generated regardless of the change of the dilution rate D. The average ethanol production rate was 88.5%.

(Ethanol production using P-890 strain [3])
In this embodiment, the operating conditions of the continuous fermentation apparatus 20 (see FIG. 8) are different from those in the third embodiment. Specifically, the general yeast and the P-890 strain were used, and each was continuously fermented under operating conditions in which the fermentation treatment and the stop of the fermentation treatment were repeated. In addition, the limonene density | concentration of the acid liquid mixture which adjusted pH of the mash 13 was about 0.03 vol%.

The details of the operating conditions of the continuous fermentation apparatus 20 are as follows.
<Operating conditions>
1. The fermentation period (12 hours) for ethanol fermentation and the stop period (12 hours) for stopping fermentation are repeated (the raw material is processed in half a day, and the process is stopped for the remaining half day).
2. The dilution rate D during the fermentation period is 0.08 (average residence time 12 hours).
3. During the shutdown period, the internal temperature of the bioreactor 22 was maintained at 30 ° C. Stirring and blowing of sterilized air continue (only the raw material supply is stopped).

The results for the general yeast and the P-890 strain are shown in FIGS. 11 (A) and 11 (B), respectively. In FIG. 5A, the horizontal axis indicates elapsed time (h), and the vertical axis indicates sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), and fructose (fructose) concentration ( g / L), total sugar concentration (g / L), ethanol concentration (g / L), influent total sugar concentration (g / L), and yeast concentration (cells / ml).
In FIG. 5B, the horizontal axis represents elapsed time (h), and the vertical axis represents sucrose concentration (g / L), glucose concentration (g / L), fructose concentration (g / L), and total sugar concentration. (G / L), ethanol concentration (g / L), total concentration of inflow trisaccharide (g / L) and yeast concentration (cells / ml) are shown.
In this example, for general yeast, in the stopped state, the yeast died and decreased due to lack of nutrition. Therefore, subsequent fermentability deteriorated. On the other hand, for the P-890 strain, no decrease in yeast was observed, and high fermentability was stably maintained. That is, the P-890 strain was found to have higher fermentation stability than general yeast.

In addition, this invention is not limited to the above-mentioned embodiment and Example, The change in the range which does not change the summary of this invention is possible.
In Example 3 and Example 4 described above, ethanol fermentation was performed from the juice 13 obtained in the juice removal process P3, but ethanol fermentation was performed using the juice residue 11 obtained in the juice extraction process P1 as a raw material. It is also possible to perform (solid fermentation).

11: Juice residue, 12: Juice, 13: Dehydrated liquid, 14: Dehydrated rice cake, 15: Heavy liquid, 16: Light liquid, 17: Solid, 18: Acid mixture, 19: Ethanol, 20: Continuous fermentation equipment, 21: pump, 22: bioreactor, 25: three-blade impeller, 26: thermostatic bath

The present invention relates to a continuous ethanol production method.

Bioethanol, which is an alternative liquefied fuel, can be produced by adding yeast to the fruit juice and subjecting it to ethanol fermentation. The conversion technology to bioethanol by fermentation of waste waste juice is very beneficial because it uses biomass that does not compete with food as a raw material.
As a technology for producing ethanol using this juice, there is a technology for producing a juice from citrus fruits, removing pulp by centrifuging citrus molasses obtained by concentrating the juice and performing ethanol fermentation with Saccharomyces yeasts, etc. It is known (see, for example, Patent Document 1).

JP 2002-153231 A

However, citrus fruits contain 0.2 to 0.5 wt% of limonene (chemical formula: C ₁₀ H ₁₆ ), which is a terpenoid oil component. This limonene is known to inhibit ethanol fermentation and is mostly contained in the skin. However, by squeezing the fruit including the fruit skin mechanically in the squeezing process and the brewing process, a part of the fruit is released into the liquid and is present mainly in micellar form in the juice. According to the measurement results of the inventor, the limonene concentration in the micelle form of limonene (0.2-0.5 wt%) in the juice is as small as 0.01-0.04 wt%. is there.
However, according to the results of an experiment in which micellar (oily) limonene was added to a YPD medium and ethanol fermentation was performed using general yeast, the ethanol production rate rapidly decreased as the added limonene concentration increased. For example, when 0.1% v / v of limonene was added, the ethanol production rate was greatly reduced to about 20%. In general, yeast is present as solid fine particles in a sugar solution and tends to adsorb oily substances. Therefore, the reason for such an experimental result is presumed that the added small amount (0.05% v / v) of limonene (oil) adsorbed to the yeast and caused fermentation inhibition. Therefore, in order to remove limonene, which is a fermentation inhibitor, from the juice, the solid content that accounts for 75% or more of the limonene is removed, and a micellar form that exists as a light liquid (oily substance). Limonene also had to be removed. However, even if limonene was removed from the raw material in advance by a treatment such as three-phase centrifugation, the conventional general yeast had an induction period, so the fermentation was not stable and the fermentation rate was slow. Therefore, fermentability tends to be unstable due to the influence of contamination and the like, and it has been difficult to maintain high fermentability over a long period of time.
An object of this invention is to provide the continuous ethanol manufacturing method which can produce | generate ethanol efficiently .

The continuous ethanol production method according to the present invention that meets the above-described object includes a squeezing step of squeezing citrus fruits,
A mixing step of mixing an alkaline substance into the squeezed residue produced in the squeezing step;
A dehydration step of dehydrating the juice residue mixed with the alkaline substance to produce a juice, and a continuous ethanol production method comprising:
Without passing through a three-phase centrifugal separation step that separates the lysate into a heavy liquid, a light liquid, and a solid, an acid mixing step that mixes nitric acid with the mash and produces an acid mixture; and
A fermentation step of adding yeast to the acid mixture and subjecting it to alcohol fermentation.

In the continuous ethanol production method according to the present invention,
It is preferable that the acid mixture has a pH of 3.0 to 4.0.

In the continuous ethanol production method according to the present invention,
In the fermentation step, continuous fermentation can be performed within a range of a dilution rate of 0.04 to 0.08.

In the continuous ethanol production method according to the present invention,
It is preferable that the yeast is an alcohol-fermenting yeast having resistance to limonene.

In the continuous ethanol production method according to the present invention,
After the desiccation step and before the acid mixing step,
And further comprising a three-phase centrifugation step of separating the lysate into a heavy liquid, a light liquid and a solid using a centrifuge,
In the acid mixing step, the nitric acid can be mixed into the heavy liquid instead of the mash.

In the continuous ethanol production method according to the present invention,
In the three-phase centrifugation step, the limonene concentration in the heavy liquid is preferably 0.01 wt% or less.

In the continuous ethanol production method according to the present invention,
The centrifuge may be a disk-type centrifuge.

In the continuous ethanol production method according to the present invention,
The centrifugal force of the disk type centrifuge is preferably 5000 G or more.

In the continuous ethanol production method according to the present invention,
The alcohol-fermenting yeast is preferably Saccharomyces cerevisiae (Accession Number NITE P-890).

In the continuous ethanol manufacturing method of Claims 1-9, since a post process has the acid mixing process which mixes nitric acid, and yeast can grow in the state which suppressed propagation of miscellaneous bacteria, ethanol can be produced | generated efficiently. Nitric acid does not have to worry about corroding the steel used in the ethanol production equipment.

Particularly, in the continuous ethanol production method according to claim 4, since yeast has higher limonene resistance than general yeast, ethanol can be produced efficiently.

In the continuous ethanol production method according to claims 5 and 6, the growth of yeast during ethanol fermentation is improved by removing the fermentation inhibitor using a centrifuge.

In the continuous ethanol production method according to claims 7 and 8, since the centrifuge is a disk-type centrifuge, the sedimentation area can be increased.

In the continuous ethanol production method according to claim 9, since the yeast is Saccharomyces cerevisiae (Accession No. NITE P-890) and has higher limonene resistance than general yeast, ethanol can be produced efficiently.

It is explanatory drawing which shows the base sequence of P-890 stock | strain which concerns on Example 1 of this invention. It is a microscope picture (1000-times multiplication factor) of the P-890 stock. It is a graph which shows the limonene tolerance of the P-890 strain. It is a graph which shows the high temperature tolerance of the P-890 strain. (A) and (B) are the graph which shows the batch fermentation characteristic of the said P-890 stock | strain, and the graph which shows the batch fermentation characteristic of general yeast, respectively. It is explanatory drawing which shows the ethanol fermentation characteristic by the fed-batch culture | cultivation of the P-890 strain. It is process drawing which shows each process of the ethanol manufacturing method which concerns on Example 3 of this invention. It is a block diagram which shows the outline | summary of the continuous fermentation apparatus used by an ethanol fermentation process. It is a graph (1) which shows an ethanol manufacturing result. It is a graph (2) which shows an ethanol manufacturing result. (A) and (B) are a graph (3) showing the ethanol production results of general yeast and a graph (4) showing the ethanol production results of the P-890 strain, respectively.

Subsequently, an embodiment of the present invention will be described with reference to the accompanying drawings for understanding of the present invention. The alcohol-fermenting yeast according to one embodiment of the present invention belongs to the genus Saccharomyces having limonene resistance. This alcohol-fermenting yeast further has high temperature resistance. When ethanol is produced using the alcohol-fermentable yeast according to the present embodiment, mandarin orange (an example of citrus fruits) is used as a raw material.
Hereinafter, “limonene resistance” refers to the property of yeast capable of ethanol fermentation at a yield of 86% or more in the presence of limonene at a concentration of 0.1 to 0.5 wt% in the raw material. “High temperature tolerance” refers to the property of yeast that can be fermented with ethanol in a yield of 86% or higher in an environment where the fermentation temperature is 40 ° C. or higher. Further, Saccharomyces cerevisiae having no limonene resistance and high temperature resistance is also referred to as “general yeast”.
Hereinafter, the present invention will be described with reference to examples.

(Separation of new yeast)
Tangerine juice was collected from the production line of a citrus juice factory harvested in Ehime Prefecture. This tangerine juice was diluted 1000-fold, spread on a YPD agar medium (containing 1% yeast extract, 2% peptone, and 2% glucose) and cultured at 30 ° C. for about 2 days.
Various yeasts colonized in the culture dish were picked up and purely cultured in a YPD medium (yeast extract 2%, peptone 2%, glucose 10% contained, pH 6.5 to 7.0).

(Yeast screening)
From each purely cultured yeast, yeast having limonene resistance was screened.
Specifically, ethanol fermentation was performed using several different types of sugar solutions as raw materials in the range of limonene concentration of 0.02 to 0.2% v / v. As a result, the limonene resistant strain was selected as a strain excellent in ethanol fermentability for each limonene concentration sugar solution. Among these limonene resistant strains, a strain with particularly high limonene resistance was deposited (Accession Number NITE P-890). Hereinafter, this deposited strain is referred to as “P-890 strain” in the present specification.

(Identification of P-890 strain)
DNA was extracted from the P-890 strain, and the D2LSUrDNA region was amplified by PCR. The base sequence of the obtained PCR product was determined by direct sequencing (see FIG. 1). Based on this base sequence, a blast (BLAST) search with a D2LSUrDNA sequence of a known microorganism on the database was performed to identify microorganisms presumed to be related species. As a result, as shown in Table 1, it was revealed that the P-890 strain is a yeast of the genus Saccharomyces cerevisiae.

(Mycological properties)
The P-890 strain has the following mycological properties.
1. Cell shape: spherical (see Fig. 2)
2. 2. Colony shape: white (no gloss), bowl-shaped Breeding mode: Multipolar budding 4. Optimal growth temperature: 30 ° C
5. Optimum growth pH: 4.0
6). Cohesiveness: None Utilization sugar: sucrose, glucose, fructose

(Limonene resistance test)
About P-890 stock | strain, limonene of arbitrary density | concentrations was added, batch fermentation (shaking culture) was performed, and ethanol fermentability was investigated. The experimental conditions are as follows.
<Experimental conditions>
1. Fermentation temperature: 30 ° C
2. Number of shakes: 120 rpm (amplitude 10 mm)
3. Fermentation time: 24 hours Ingredients: YPD medium

The results are shown in FIG. In the figure, the horizontal axis represents the amount of limonene added to the YPD medium (% v / v), and the vertical axis represents the ethanol production rate (%).
As is clear from the figure, for general yeast, the ethanol production rate decreases as the limonene concentration increases. On the other hand, for the P-890 strain, the ethanol production rate exceeded 90% and the ethanol production rate did not decrease until the limonene addition concentration reached about 0.1% v / v.

(High temperature resistance test)
Using a YPD medium, a batch fermentation experiment was conducted for 24 hours at fermentation temperatures of 30 ° C., 37 ° C., 40 ° C., 42 ° C., and 45 ° C. The experimental conditions are as follows.
<Experimental conditions>
1. Number of shakes: 120 rpm (amplitude 10 mm)
2. 2. Fermentation time: 24 hours Ingredients: YPD medium

The result is shown in FIG. In the figure, the horizontal axis represents temperature, and the vertical axis represents the ethanol production rate. Although there is a portion where the ethanol production rate slightly exceeds 100%, it is considered that the ethanol production rate was calculated to be large due to a measurement error.

As is clear from the figure, the general yeast was able to ferment only up to a fermentation temperature of 37 ° C., but the P-890 strain could be fermented at a high yield of 90% or higher up to the fermentation temperature of 40 ° C. That is, the P-890 strain was found to have high temperature resistance. Moreover, it became clear that P-890 strain | stump | stock has an ethanol production rate of about 70% even at 42 degreeC, and can ferment with a comparatively high yield.

(Ethanol fermentation test [1])
Batch culture was performed in the presence of limonene, and ethanol production and yeast growth were examined. The experimental conditions are as follows.
<Experimental conditions>
1. Fermentation temperature: 30 ° C
2. Stirring speed: 120rpm
3. Fermentation time: 24 hours Ingredients: Heavy liquid obtained by three-phase centrifugation of mandarin orange (Unshu mandarin) juice (adjusted to pH 3.5 by adding nitric acid)
The results for the P-890 strain are shown in FIG. In the figure, the horizontal axis represents time, and the vertical axis represents sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), fructose (fructose) concentration (g / L), ethanol concentration ( g / L) and yeast concentration (cells / ml).
For the general yeast shown in FIG. 5 (B), there was an induction period of about 8 hours. However, the P-890 strain did not have an induction period and started to grow after the start of culture. In addition, the P-890 strain had higher yeast growth rate and ethanol production rate than general yeast. Due to such characteristics, when the P-890 strain is used for ethanol fermentation, stable culture can be performed in a shorter period of time compared to general yeast, and efficient fermentation with a short average residence time is possible.

Furthermore, the conditions for the presence or absence of three-phase centrifugation and the presence or absence of nitric acid addition to the tangerine juice were changed, and ethanol production was similarly examined for the following three raw materials.
1) Tangerine juice that was adjusted to pH 3.5 by adding nitric acid (no three-phase centrifugation)
2) Heavy liquid obtained by three-phase centrifugation of tangerine juice (no pH adjustment)
3) Tangerine juice (no three-phase centrifugation, no pH adjustment)
The effect of the three-phase centrifugation is removal of limonene. Here, since P-890 strain has limonene resistance, it seems unnecessary to remove limonene. However, 1) Although the P-890 strain has limonene resistance, if the limonene concentration is low, further improvement of the ethanol production rate can be expected, and 2) limonene cannot be completely removed by three-phase centrifugation. Therefore, the presence or absence of the three-phase centrifugation for the orange juice juice is considered as a condition. Moreover, the effect of nitric acid addition is suppression of miscellaneous bacteria propagation. Details of the effects of the three-phase centrifugation and the addition of nitric acid will be described later.
The results under these conditions are shown in Tables 2 to 4, respectively.

Table 2 shows sucrose concentration (g / L), glucose concentration (g / L), fructose concentration (g / L), ethanol concentration (g / L) before and after fermentation for general yeast and P-890 strain, respectively. The ethanol production rate (%) was measured.

Table 3 shows sucrose concentration before and after fermentation (g / L), glucose concentration (g / L), fructose concentration (g / L), ethanol concentration (g / L), and general yeast and P-890 strain, respectively. The ethanol production rate (%) was measured.
In addition, about after fermentation, data are measured twice as after fermentation (1) and after fermentation (2). The average ethanol production rate (%) is an average of the ethanol production rates (%) measured twice.

Table 4 is the same data as Table 3.

As is apparent from Tables 2 to 4, all of the P-890 strains had a higher ethanol production rate than general yeast. In particular, in the tangerine juice (unprocessed raw material) with neither centrifugation nor pH adjustment, when the P-890 strain was used, the ethanol production rate was 15% higher than that of general yeast (see Table 4).

(Ethanol fermentation test [2])
Fed-batch culture was carried out using a heavy liquid obtained by three-phase centrifugation of a mandarin orange juice as a raw material, and ethanol production and yeast growth were examined. The experimental conditions are as follows.
<Experimental conditions>
1. Temperature: 30 ° C
2. Stirring speed: 150 rpm
3. Raw material supply: 3.3 ml / min
4). Reactor capacity: 5L
5. Air blowing amount: 0.05vvm
6). Amount of added yeast: 3.0% v / v
7). Ingredients: Tangerine (Unshu tangerine) dessert solution results are shown in FIG. In the figure, the horizontal axis represents time, and the vertical axis represents ethanol concentration (g / L) and yeast concentration (cells / tank).
As is apparent from the figure, there is an induction period of about 4 hours for general yeast in the limonene-concentrated solution subjected to the three-phase centrifugation treatment. In contrast, the P-890 strain does not have an induction period, and starts to grow immediately after the start of culture. In addition, the P-890 strain started to produce ethanol immediately after the start of the culture, and ethanol production reached its peak at 15 hours. That is, the P-890 strain was found to have a higher ethanol production rate than general yeast. That is, the P-890 strain does not have an induction period and can be stably fermented with respect to the raw material having a low limonene concentration that has been subjected to three-phase centrifugation.

(Ethanol production using P-890 strain [1])
P-890 strain was used, and ethanol was produced using Iyokan as an example of the raw material. First, the manufacturing method will be described.
As shown in FIG. 7, the ethanol production method includes a pre-process and a post-process. The pre-process has a squeezing process P1, a mixing process P2, and a brewing process P3. The post-process includes a three-phase centrifugal separation process P4, an acid mixing process P5, a fermentation process P6, and a distillation process P7. Hereinafter, each step will be described.

The squeezing step P1 is a step of squeezing Iyokan with a squeezing machine such as an inline method or a chopper pulper method. By this step, juice residue 11 and juice 12 are generated.

The mixing process P2 is a process of mixing slaked lime, which is an example of an alkaline substance, with the squeezed residue 11 generated in the squeezing process P1. Since the squeezed residue 11 produced | generated by the squeezing process P1 is a gel or a slurry form, it cannot press and it can drain efficiently. Therefore, it can be efficiently drained by adding and mixing slaked lime.

The de-juice process P3 is a process of pressing and dehydrating the juice residue 11 that has been easily pressed in the mixing process P2. By this step, a mash 13 and a mash 14 are produced.

The three-phase centrifugal separation step P4 is a step of three-phase centrifugal separation of the juice 13 generated in the juice removal step P3 into a heavy liquid portion 15, a light liquid portion 16, and a solid portion 17.
In the three-phase centrifugation step P4, limonene, which is a fermentation inhibiting substance contained in the juice 13, is removed together as a light liquid (oily substance) 16 and a solid content 17. As a result, the limonene concentration in the heavy liquid portion 15 can be 0.01 wt% or less, and the total limonene concentration including the solid content can be reduced to 0.1 wt% or less.

Thus, in this process, the growth property of the yeast at the time of ethanol fermentation improves by carrying out the three-phase centrifugation of the mash 13 and removing a fermentation inhibitor. As a result, the fermentability is stabilized and the ethanol production rate is increased.
In addition, since the three-phase centrifuge used at this process isolate | separates light liquid and heavy liquid with few specific gravity differences, it is preferable to use the disk-type centrifuge which can enlarge a sedimentation area. Separation is possible if the centrifugal force is 5000 G or more industrially.

The acid mixing step P5 is a step of mixing the heavy liquid portion 15 generated in the three-phase centrifugal separation step P4 with nitric acid, which is an example of an acidic substance, to generate the acid mixed solution 18. Specifically, it is a step of adding 60% concentrated nitric acid to the heavy liquid portion 15 generated in the three-phase centrifugal separation step P4, and stirring and mixing with a stirring pump or a stirrer. As a result, the pH of the heavy liquid 15 is adjusted to 3.5, and the acid mixture 18 is generated.
Since the specific gravity of nitric acid is heavier than the heavy liquid component 15 generated in the three-phase centrifugation step P4, the nitric acid is stirred constantly or periodically after the addition of nitric acid.

By this step, various germs in the acid mixed solution 18 are reduced to about 1/10 to 1/1000 before mixing with nitric acid. This pH is 1) the optimum pH for inhabiting various bacteria is 5.0 to 7.0, and 2) the optimum pH for growing yeast required for ethanol fermentation in the next step is 3. It is determined in consideration of 5 to 6.0. That is, in this step, the pH is adjusted so that yeast can grow in a state in which the propagation of various bacteria is suppressed. This pH is, for example, 3.0 to 4.0.

Fermentation process P6 is a process in which Saccharomyces cerevisiae P-890 strain is added to heavy liquid 15 (acid mixture 18) whose pH has been adjusted in acid mixing process P5, and ethanol fermentation is performed. This fermentation is continuous fermentation, but may be batch fermentation.

The distillation process P7 is a process of distilling the ethanol fermentation liquid produced in the fermentation process P6. By this step, ethanol 19 can be purified.

According to the said manufacturing process, ethanol production was performed using P-890 stock | strain.

First, Iyokan was squeezed as a raw material in the squeezing step P1. Next, slaked lime was mixed with the produced squeezed residue 11 in the mixing step P2. Next, the squeezed residue 11 in which slaked lime was mixed was pressed in the brewing process P3, and the brewing liquid 13 was produced | generated. Next, in the three-phase centrifugal separation process P4, the lysate 13 produced in the brewing process P3 was applied to a three-phase separator to separate the heavy liquid fraction 15. Next, in the acid mixing step P5, nitric acid was added to adjust the pH of the heavy liquid portion 15 to 3.5 and mixed for 2 hours to produce an acid mixed solution 18. And continuous fermentation was performed in fermentation process P6.

Here, the continuous fermentation apparatus 20 used in the fermentation process P6 will be described. As shown in FIG. 8, in the fermentation process P <b> 6, the acid mixed solution 18 (pH 3.5) as a raw material was sent from the pump 21 to the bioreactor 22. The bioreactor 22 was continuously fermented (average residence time: 24 hours). The fermentation liquid flows out from the upper part of the continuous fermentation apparatus 20 by overflow. During fermentation, sterilized air was blown into the fermentation broth in the bioreactor 22. Moreover, the fermented liquor was constantly stirred by the three-blade impeller 25. The internal temperature of the bioreactor 22 was maintained by a constant temperature bath 26.

Detailed fermentation conditions are as follows.
<Continuous fermentation conditions>
1. Fermentation temperature: 30 ° C
2. Stirring speed: 150 rpm
3. Fermentation time: 24 hours (residence time)
4). Amount of added yeast: 3.0% v / v
5. Reactor capacity: 5L
6). Dilution rate: 0.04 (1 / h)
7). Sterilization air blowing amount: 0.05vvm
8). Other: Change dilution ratio D in the range of 0.014 to 0.04 during continuous fermentation

The results are shown in FIG. In the figure, the horizontal axis represents elapsed time, and the vertical axis represents sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), fructose (fructose) concentration (g / L), total sugar. The concentration (g / L), ethanol concentration (g / L), and yeast concentration (cells / ml) are shown.
In this example, the dilution rate D was changed in the range of 0.014 to 0.04, but ethanol was stably generated regardless of the change of the dilution rate D. The average ethanol production rate was 105.4%. The average ethanol production rate exceeds 100%, and the following two reasons are considered. First, the sugars considered when calculating the average ethanol production rate are sucrose, glucose, and fructose, which is considered to be because the yeast utilized other sugars. Secondly, it is considered that the average ethanol production rate was calculated to be large due to the measurement error.

(Ethanol production using P-890 strain [2])
This embodiment is different from the third embodiment in that the centrifugation step P4 is omitted and the change range of the dilution rate D is two points. That is, after producing the brewing liquid in the brewing process P3, the centrifugal separation process P4 was omitted, and in the acid mixing process P5, nitric acid was added to the brewing liquid to produce an acid mixture having a pH of 3.5. The acid mixture was fed into the bioreactor 22 and the fermentation process P6 was performed. In addition, the limonene density | concentration (the total value of the limonene adhering to solid content and the limonene which exists in a liquid) of the acid liquid mixture which adjusted pH of the mash 13 was 0.2% v / v.

The results are shown in FIG. In the figure, the horizontal axis represents elapsed time (h), and the vertical axis represents sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), and fructose (fructose) concentration (g / L). , Total sugar concentration (g / L), ethanol concentration (g / L), and yeast concentration (cells / ml).
In this example, the dilution rate D was changed in the range of 0.04 to 0.08, but ethanol was stably generated regardless of the change of the dilution rate D. The average ethanol production rate was 88.5%.

(Ethanol production using P-890 strain [3])
In this embodiment, the operating conditions of the continuous fermentation apparatus 20 (see FIG. 8) are different from those in the third embodiment. Specifically, the general yeast and the P-890 strain were used, and each was continuously fermented under operating conditions in which the fermentation treatment and the stop of the fermentation treatment were repeated. In addition, the limonene density | concentration of the acid liquid mixture which adjusted pH of the mash 13 was about 0.03 vol%.

The details of the operating conditions of the continuous fermentation apparatus 20 are as follows.
<Operating conditions>
1. The fermentation period (12 hours) for ethanol fermentation and the stop period (12 hours) for stopping fermentation are repeated (the raw material is processed in half a day, and the process is stopped for the remaining half day).
2. The dilution rate D during the fermentation period is 0.08 (average residence time 12 hours).
3. During the shutdown period, the internal temperature of the bioreactor 22 was maintained at 30 ° C. Stirring and blowing of sterilized air continue (only the raw material supply is stopped).

The results for the general yeast and the P-890 strain are shown in FIGS. 11 (A) and 11 (B), respectively. In FIG. 5A, the horizontal axis indicates elapsed time (h), and the vertical axis indicates sucrose (sucrose) concentration (g / L), glucose (glucose) concentration (g / L), and fructose (fructose) concentration ( g / L), total sugar concentration (g / L), ethanol concentration (g / L), influent total sugar concentration (g / L), and yeast concentration (cells / ml).
In FIG. 5B, the horizontal axis represents elapsed time (h), and the vertical axis represents sucrose concentration (g / L), glucose concentration (g / L), fructose concentration (g / L), and total sugar concentration. (G / L), ethanol concentration (g / L), total concentration of inflow trisaccharide (g / L) and yeast concentration (cells / ml) are shown.
In this example, for general yeast, in the stopped state, the yeast died and decreased due to lack of nutrition. Therefore, subsequent fermentability deteriorated. On the other hand, for the P-890 strain, no decrease in yeast was observed, and high fermentability was stably maintained. That is, the P-890 strain was found to have higher fermentation stability than general yeast.

In addition, this invention is not limited to the above-mentioned embodiment and Example, The change in the range which does not change the summary of this invention is possible.
In Example 3 and Example 4 described above, ethanol fermentation was performed from the juice 13 obtained in the juice removal process P3, but ethanol fermentation was performed using the juice residue 11 obtained in the juice extraction process P1 as a raw material. It is also possible to perform (solid fermentation).

11: Juice residue, 12: Juice, 13: Dehydrated liquid, 14: Dehydrated rice cake, 15: Heavy liquid, 16: Light liquid, 17: Solid, 18: Acid mixture, 19: Ethanol, 20: Continuous fermentation equipment, 21: pump, 22: bioreactor, 25: three-blade impeller, 26: thermostatic bath

Claims (9)

An alcohol-fermenting yeast belonging to the genus Saccharomyces having resistance to limonene. 2. The alcohol fermentable yeast according to claim 1, further having high temperature resistance. The alcohol-fermenting yeast according to claim 1 or 2, which is Saccharomyces cerevisiae. The alcohol-fermentable yeast according to claim 3, which is Saccharomyces cerevisiae (Accession No. NITE P-890). The ethanol manufacturing method which uses the alcohol fermentable yeast of any one of Claims 1-4. 6. The method for producing ethanol according to claim 5, wherein citrus is used as a raw material. 6. The ethanol production method according to claim 5, wherein a heavy liquid obtained by three-phase centrifugation of the citrus juice is used as a raw material. 6. The method for producing ethanol according to claim 5, wherein the citrus juice containing an acidic substance is used as a raw material. The ethanol production method according to claim 8, wherein the acidic substance is nitric acid.