JP2011142888A - Bioreactor and method for operating the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a bioreactor capable of relieving problems of gas shortage during the starting initial period of a reaction and gas excess during promotion of the reaction by making flow rate circulated by a gas lift controllable, and to provide a method for operating the bioreactor. <P>SOLUTION: The bioreactor includes: a body part 1 composing a reaction vessel; a gas-liquid separation tank 2 disposed on the outside of the body part 1; a discharge pipe 3 having one end 3a thereof immersed in the interior of the body part 1 and the other end 3b thereof connected to the gas-liquid separation tank 2; a return pipe 4 having one end 4a thereof connected to the bottom 2a of the gas-liquid separation tank 2 and the other end 4b thereof connected to the body part 1 below the discharge pipe 3; a feed port 5 for charging a raw material M into the body part 1; a takeout port 6 disposed above the feed port 5 for taking out a treated liquid U from the body part 1; a separator 7 disposed between the feed port 5 and takeout port 6 for collecting a biocatalyst C; and a flow controlling means 8 for controlling the flow rate of the discharge pipe 3. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a bioreactor that reacts a raw material and a biocatalyst in a solution to produce a useful substance and takes out a treatment liquid containing the useful substance, and an operation method thereof, and in particular, controls a flow rate circulated by a gas lift. The present invention relates to a bioreactor configured and an operation method thereof.

  A bioreactor is an apparatus that can extract various useful substances by combining raw materials and biocatalysts, and is an important apparatus in the biochemical industry. One useful substance extracted by such a bioreactor is bioethanol. Bioethanol is ethanol produced by fermentation and distillation of biomass resources (plant resources) such as sugarcane and corn. Such bioethanol is a renewable energy that can be used as a fuel. Currently, the mainstream gasoline and heavy oil are fossil fuels and cannot be regenerated if they are depleted, but bioethanol can be regenerated as much as possible by growing plants that are raw materials. Moreover, since bioethanol uses plants as a raw material, it can absorb carbon dioxide by photosynthesis in its growing stage. That is, even if carbon dioxide is generated by combustion of bioethanol, carbon dioxide is absorbed at the growth stage, and it can be considered that there is no subtraction. Therefore, bioethanol does not increase carbon dioxide even when burned, and is a fuel that greatly contributes to the prevention of global warming, and is a fuel that has attracted international attention.

  There are various types of such bioreactors, which can be roughly classified into batch type and continuous type. The batch method is a method in which a biocatalyst and a raw material are put into a bioreactor to start the reaction, and the reaction is performed in the bioreactor to the final stage while controlling temperature, pH and the like. On the other hand, the continuous method is a method in which a raw material is continuously supplied to a bioreactor and a product is continuously taken out from the bioreactor. The current bioreactor is the batch type in view of risk avoidance due to contamination with bacteria, but the continuous type is superior from the viewpoint of scale merit and production efficiency. As the continuous bioreactor, for example, those described in Patent Documents 1 to 3 have been proposed.

  The bioreactor described in Patent Document 1 is a continuous fluidized bed bioreactor, and in order from the bottom, a tube body in which a plurality of cylindrical members of an introduction unit, a biological treatment unit, and a solid-liquid separation unit are connected, and a tube A supply port provided in the lower part of the body, a small hole plate for partition provided in the biological treatment part of the tubular body, an outlet provided in the upper part of the tubular body, and a solid-liquid separating part of the tubular body And a cylindrical partition wall provided at the center. Such a bioreactor performs biological treatment such as fermentation of the raw material, while flowing the biocatalyst by filling the raw material and the biocatalyst inside and supplying air, and removing the obtained treatment liquid from the outlet. It is discharging. In this process, the biocatalyst and the treatment liquid rise to the upper part of the tubular body by the water flow generating means, but the biocatalyst and the treatment liquid flow inside the partition wall, and the treatment liquid and some of the biocatalysts are It flows out of the partition wall and is pushed out to the outlet side. Since the outside of the partition wall is not easily affected by the upward water flow generated by the water flow generating means, the biocatalyst is lowered by its own weight in the middle, and only the processing liquid moves to the outlet, separating the processing liquid and the biocatalyst. Yes.

  The bioreactor described in Patent Document 2 is connected to a fluidized bed bioreactor that treats wastewater flowing in from an inflow pipe in an anaerobic atmosphere and flows out from an overflow weir, and an upper part of the bioreactor. A desulfurization tower, an air lift pipe installed at the liquid level in the bioreactor, and a blower for returning the processing gas from the desulfurization tower to the lower end of the air lift pipe, and the waste water at the upper part of the air lift pipe is supplied to the bioreactor An anaerobic bioreactor device characterized by being led to an inflow pipe. And the wastewater which flows in into a bioreactor from an inflow pipe is processed in an anaerobic atmosphere, and it flows out of the system from a overflow weir as treated water. In addition, hydrogen sulfide generated in the bioreactor is guided to the desulfurization tower and processed, and the processing gas is returned to the air lift pipe by the blower to raise the waste water by the air lift action, and the hydrogen sulfide in the waste water is expelled by stripping. Yes.

  Moreover, the bioreactor described in Patent Document 3 includes a reaction vessel having a fermentation reaction chamber, a mechanism for introducing inflow water into the reaction chamber, an overflow groove for recovering purified water by overflow, A recovery device that is disposed at a level lower than the overflow groove and recovers the liquid containing sludge and gas, a separation chamber that separates the gas from the recovered liquid, and returns the liquid containing sludge to the lower bottom portion of the reaction vessel And a descending pipe. Such a bioreactor can be called a self-circulating bioreactor because the sludge that has been lifted by the gas lift action is separated and returned to the reaction vessel.

JP 2002-281958 A JP-A-6-142683 JP-A-61-71896

  However, in the expansion type bioreactor in which a fluidized bed is formed by the biocatalyst floating and sinking as described in Patent Document 1, the amount of gas generated is low at the beginning of the reaction due to the relationship with the gas generation rate generated by biological treatment. There is a problem that sufficient stirring is not obtained and it takes time to reach a steady state. In addition, if the amount of gas generated increases due to the acceleration of the reaction and the liquid flow rate becomes excessive, microbial particles will flow out of the system, requiring replenishment of microorganisms and cleaning of facilities contaminated with microorganisms, etc. There was a problem of causing trouble in recovery and maintenance. Furthermore, as in Patent Document 1, a bioreactor using a gas generated by biological treatment as a lift gas has a problem that it is difficult to control the amount of gas generated. In addition, although it is conceivable to introduce external air as a supply source of lift gas, there has been a problem that equipment such as a pump has to be provided, resulting in an increase in cost and a decrease in energy efficiency.

  Further, as in Patent Document 2, even when the processing gas of the gas generated in the bioreactor is circulated to form a lift gas, the amount of gas generated is small at the beginning of the reaction, and sufficient lift gas is supplied to the air lift pipe. There is a problem that it takes time to reach a steady state. Further, since the lift gas is returned to the air lift pipe by the blower, there are problems such as an increase in cost and a decrease in energy efficiency.

  Further, even in a self-circulating bioreactor such as Patent Document 3, as in Patent Document 1 and Patent Document 2, there is a problem of gas shortage at the beginning of the reaction. Furthermore, since the sludge is lowered by its own weight, there is a problem if the flow rate and concentration circulated due to the sludge properties and the like are not stable. In addition, since the descending pipe is arranged inside the reaction vessel, there is a problem that it is difficult to control the sludge properties and flow rate as well as to check the properties and flow rate of the sludge.

  The present invention has been devised in view of the above-mentioned problems, and by controlling the flow rate circulated by the gas lift, it is possible to alleviate the problem of gas shortage at the beginning of the reaction and excessive gas at the time of promoting the reaction. It is an object of the present invention to provide a bioreactor capable of operating and a method of operating the same.

  According to the present invention, a bioreactor that reacts a raw material substance and a biocatalyst in a solution to produce a useful substance and takes out a treatment liquid containing the useful substance, comprising a main body part constituting a reaction vessel, A gas-liquid separation tank disposed outside the main body, a discharge pipe having one end immersed in the main body and the other end connected to the gas-liquid separation tank, and one end at the bottom of the gas-liquid separation tank A return pipe connected at the other end to the main body below the discharge pipe, a supply port for introducing the raw material into the main body, and the main body disposed above the supply port An outlet for taking out the processing liquid from, a separator that is arranged between the supply port and the outlet and collects the biocatalyst, and a flow rate adjusting means for adjusting the flow rate of the discharge pipe, The raw material introduced from the supply port and the biocatalyst in the main body A solution containing the biocatalyst produced by reacting to produce useful substances, raising the solution containing them by buoyancy of the reaction gas, discharging the treatment liquid that has passed through the separator from the outlet, and collecting by the separator Is sent from the discharge pipe to the gas-liquid separation tank while the flow rate is controlled by the flow rate adjusting means, the reaction gas is separated in the gas-liquid separation tank, and the residual solution is sent from the return pipe to the main body. A bioreactor is provided that is characterized by being returned.

  The flow rate adjusting means is either a depth of the discharge pipe immersed from the liquid level of the main body part, a height of the discharge pipe protruding from the liquid level of the main body part, or a channel cross-sectional area of the discharge pipe. It is preferable that it is a means to adjust.

  For example, the means for adjusting the depth is configured to change the height of the outlet, and the means for adjusting the height is configured to change the height of the gas-liquid separation tank. Or a means for changing the height of the connection portion between the discharge pipe and the gas-liquid separation tank, and the means for adjusting the cross-sectional area of the flow path is configured so that the number of the discharge pipes to be used can be switched. Or means for switching the pipe diameter of the discharge pipe to be used.

  Further, according to the present invention, there is provided a method of operating a bioreactor in which a raw material substance and a biocatalyst are reacted in a solution to produce a useful substance, and a treatment liquid containing the useful substance is taken out, including the biocatalyst. The raw material is introduced into the solution, the reaction solution is raised by the reaction gas generated by the reaction between the raw material and the biocatalyst, and the treatment liquid from which the biocatalyst is removed from the reaction solution is discharged out of the system, The collected solution containing the biocatalyst is sent to the gas-liquid separation unit while adjusting the flow rate according to the operation state of the bioreactor, and the reaction gas is removed by the gas-liquid separation unit to react the residual solution with the reaction. There is provided a method of operating a bioreactor characterized in that it is sent back to a container.

  For example, in the bioreactor, the flow rate sent to the gas-liquid separation unit is increased at the start of operation or when the reaction is promoted, and the flow rate sent to the gas-liquid separation unit is maintained substantially constant during steady operation or when the reaction is maintained. Then, control is performed so that the flow rate sent to the gas-liquid separation unit is reduced when the operation is stopped or when the reaction is suppressed.

  According to the bioreactor of the present invention and the operation method thereof described above, the flow rate circulated by the gas lift by the flow rate adjusting means even in the self-circulation type bioreactor that circulates the solution in the reaction vessel by the gas lift action of the reaction gas. Can be controlled, and the problem of gas shortage at the beginning of the reaction and excess gas at the time of promoting the reaction can be alleviated. In particular, the flow rate circulated by the gas lift can be easily controlled by using the flow rate adjusting means as means for adjusting the depth and height of the discharge pipe and the flow path cross-sectional area.

  Further, according to the present invention, the circulation flow rate is increased when the gas generation amount is small, the circulation flow rate is maintained constant when it is desired to maintain a steady state, and the circulation flow rate is decreased when the gas generation amount is excessive. The circulation flow rate can be controlled according to the operating conditions of the bioreactor, the solution can be agitated without depending on the amount of gas generated, and there is a shortage of gas at the beginning of the reaction or excess gas at the time of promoting the reaction. This problem can be effectively alleviated.

It is side surface sectional drawing which shows 1st embodiment of the bioreactor which concerns on this invention. It is a figure which shows the relationship between the gas flow rate Qg of a discharge pipe, the liquid flow rate Qf, and immersion depth ratio Hs / (Hs + H). It is a figure which shows the effect | action of 1st embodiment, (A) has shown the state which raised the liquid level of the main-body part, (B) has shown the case where the liquid level of a main-body part is made low. It is a figure which shows other embodiment of the bioreactor which concerns on this invention, (A) is 2nd embodiment, (B) is 3rd embodiment, (C) is 4th embodiment, (D) is 5th. 1 shows an embodiment. It is a figure which shows other embodiment of the bioreactor which concerns on this invention, (A) is 6th embodiment, (B) is 7th embodiment, (C) has shown 8th embodiment. It is a figure which shows 9th embodiment of the bioreactor which concerns on this invention. It is a figure which shows the relationship between the gas flow rate Qg of a discharge pipe, the liquid flow rate Qf, and the discharge pipe diameter D. FIG. It is a figure which shows the effect | action of 9th embodiment, (A) has shown the flow-path area of a discharge pipe: Medium state, (B) has shown the flow-path area of a discharge pipe: Large state. It is a figure which shows other embodiment of the bioreactor which concerns on this invention, (A) is 10th embodiment, (B) is the modification of 9th embodiment, (C) is the modification of 10th embodiment, Is shown.

  Hereinafter, embodiments of the present invention will be described with reference to FIGS. Here, FIG. 1 is a side sectional view showing a first embodiment of the bioreactor according to the present invention.

  The bioreactor shown in FIG. 1 is a bioreactor that produces a useful substance by reacting a raw material substance M and a biocatalyst C in a solution, and takes out a processing liquid U containing the useful substance, and constitutes a reaction vessel. 1, a gas-liquid separation tank 2 disposed outside the main body 1, a discharge pipe 3 having one end 3 a immersed in the main body 1 and the other end 3 b connected to the gas-liquid separation tank 2, one end A return pipe 4 having 4a connected to the bottom 2a of the gas-liquid separation tank 2 and the other end 4b connected to the main body 1 below the discharge pipe 3, and a supply port 5 for introducing the raw material M into the main body 1 And an outlet 6 that is disposed above the supply port 5 and that extracts the processing liquid U from the main body 1, a separator 7 that is disposed between the supply port 5 and the outlet 6 and collects the biocatalyst C, and a discharge A flow rate adjusting means 8 for adjusting the flow rate of the pipe 3, and a raw material introduced from the supply port 5 And a biocatalyst C in the main body 1 are reacted to generate useful substances, a solution containing these is raised by the buoyancy of the reaction gas g, and the processing liquid U that has passed through the separator 7 is discharged from the outlet 6. The solution containing the biocatalyst C collected by the separator 7 is sent from the discharge pipe 3 to the gas-liquid separation tank 2 while controlling the flow rate by the flow rate adjusting means 8, and the reaction gas g is separated in the gas-liquid separation tank 2 The solution is sent back from the return pipe 4 to the main body 1. In FIG. 1, for convenience of explanation, the biocatalyst C is indicated by ◯ and the reaction gas g is indicated by ●.

  The main body 1 is a reaction container having a cylindrical shape with both ends closed, and a space below the separator 7 forms a main reaction processing layer. Although FIG. 1 illustrates a tower shape whose height direction is longer than the width direction, a tank shape whose width direction is longer than the height direction may be used. Moreover, since the main-body part 1 comprises a reaction container, it is formed with the raw material which does not corrode easily with the biocatalyst C and the reaction product (The process liquid U containing a useful substance, reaction gas g, etc.). Such a material is selected according to the use of the bioreactor. For example, a metal material such as a glass material or stainless steel is used.

  The gas-liquid separation tank 2 is a device that separates the reaction gas g (for example, carbon dioxide) from the solution fed through the discharge pipe 3. Since the solution sent to the gas-liquid separation tank 2 is sent by the buoyancy of the reaction gas g, the gas-liquid separation tank 2 is arranged above the liquid level of the solution in the main body 1. The gas-liquid separation tank 2 has, for example, a funnel shape in which the bottom portion 2a is gradually reduced in diameter, and a solution containing the biocatalyst C (◯) released from the side surface into the gas-liquid separation tank 2 is applied to the bottom portion 2a by its own weight. The reaction gas g (●) is collected and collected in the upper space 2b of the gas-liquid separation tank 2 so that the reaction gas g can be separated. An exhaust port 2c is connected to the upper part of the gas-liquid separation tank 2, and the separated reaction gas g is discharged out of the system. A gas flow meter for measuring the flow rate of the reaction gas g may be disposed at the exhaust port 2c. In addition, the gas-liquid separation tank 2 used for the bioreactor of the present invention is not limited to the illustrated one, and may be any device that can separate gas and liquid.

  The discharge pipe 3 forms a flow path for sending a solution containing the biocatalyst C collected by the separator 7 to the gas-liquid separation tank 2. Since the buoyancy of the reaction gas g is used for the flow of the solution, the discharge pipe 3 is preferably arranged so as not to have a meandering portion. Further, since the principle of a so-called gas lift pump is used, the size, length, shape, etc. of the diameter of the discharge pipe 3 are designed in a range that allows the gas lift pump according to the bioreactor used. In FIG. 1, the discharge pipe 3 is formed in a substantially L shape, and one end 3a side is arranged in the vertical direction and the other end 3b side is arranged in the horizontal direction. In addition, one end 3 a of the discharge pipe 3 is immersed in the solution in the main body 1 and connected to the separator 7. The other end 3 b of the discharge pipe 3 is connected to the side surface of the gas-liquid separation tank 2.

  The return pipe 4 forms a flow path for returning the solution separated in the gas-liquid separation tank 2 back into the main body 1. Such a return pipe 4 is a flow path for returning the biocatalyst C to the main body 1, and an upward flow is formed in the main body 1, so that the other end 4 b is connected to the lower part of the main body 1 as much as possible. It is preferable. In FIG. 1, the other end 4 b of the return pipe 4 is inserted into the inside from the side surface of the main body 1 and immersed in the solution, and is disposed above the supply port 5 for the raw material M. However, the arrangement is not limited to the illustrated arrangement, and the other end 4 b of the return pipe 4 may be arranged below the supply port 5. Note that the other end 4 b of the return pipe 4 is formed with a plurality of discharge holes in the peripheral surface of the portion immersed in the solution in the main body 1 or expanded in diameter so as to approach the side surface of the main body 1. The biocatalyst C may be sent back almost uniformly within the main body 1 by connecting a nozzle.

  In addition, as shown in FIG. 1, a replenishment port 4c through which a gas or liquid (for example, air, oxygen, water, oxygen water, etc.) for adjusting the concentration and activity of the biocatalyst C is introduced into the return pipe 4. May be connected, or a meter 4d for monitoring the situation in the main body 1 may be connected. The instrument 4d is, for example, a flow meter, a thermometer, a pH (hydrogen ion exponent) meter, an oxidation-reduction potential (ORP) meter, a concentration meter, a flow meter, a pressure meter, a viscometer, a light intensity meter, or a sampling for collecting a circulating solution. It is an apparatus or the like, and any instrument that is necessary for monitoring the characteristics in the bioreactor, the characteristics of the circulating solution, the characteristics of the biocatalyst C, and the like may be used, and a plurality of instruments 4d may be arranged. In the present invention, since it is necessary to measure the flow rate of the return pipe 4, it is preferable to arrange at least a flow meter as the meter 4d.

  The supply port 5 forms a flow path through which the raw material M is introduced into the main body 1. In the supply port 5 shown in FIG. 1, the tip of the supply port 5 is immersed in the solution in the main body 1 so that the material material M can be introduced into the substantially central portion of the main body 1. Further, the tip portion may be curved downward so that the material M is easily introduced. The supply port 5 is preferably connected to the lower part of the main body 1 in order to secure a wider layer where the raw material M and the biocatalyst C react. A plurality of supply ports 5 may be connected to the main body 1. At this time, each supply port 5 is eccentrically connected to the main body 1 to generate a swirl flow in the main body 1 and improve the stirring efficiency. Further, a stirrer may be disposed in the vicinity of the supply port 5, a plurality of discharge holes may be formed on the peripheral surface of the portion immersed in the solution in the main body 1, You may connect the discharge nozzle expanded in diameter so that it may approach an inner surface.

  The outlet 6 forms a flow path for taking out the processing liquid U containing useful substances out of the system. The outlet 6 is disposed at the upper part of the side surface of the main body 1 and is configured to discharge the overflow of the solution in the main body 1. In the first embodiment shown in FIG. 1, a plurality of outlets 6 (for example, a first outlet 61, a second outlet 62, and a third outlet 63) are connected, and the first outlet 61 to the first outlet. A valve 64 is connected to each of the three outlets 63 so that the outlet 6 to be used can be switched. Here, the valve 64 of the second outlet 62 is opened, the valves 64 of the first outlet 61 and the third outlet 63 are closed, and the processing liquid U is taken out of the system from the second outlet 62. In this manner, by arranging the plurality of outlets 6 at the main body 1 with different heights, the height of the outlet 6 can be changed, and the liquid level in the main body 1 can be changed. Can be controlled. A flow meter for measuring the flow rate of the processing liquid U may be disposed at the outlet 6. An apparatus for a process of performing distillation or purification for concentrating useful substances is connected downstream of the outlet 6.

  The separator 7 has a function of separating the reaction gas g and the biocatalyst C from the solution that rises due to the buoyancy of the reaction gas g. The solution rising in the main body 1 contains a medium such as a biocatalyst C, a useful substance, a reactive gas g, and water. In order to take out the useful substance, at least the reactive gas g and the biocatalyst C are separated. There is a need to. In the separator 7 shown in FIG. 1, the separator 7 has a truncated conical side surface shape, and the upper end is connected to the discharge pipe 3 so that the lower end has a predetermined gap with the main body 1. ing. In this way, by forming the separator 7 into a shape with a diameter reduced upward, an upward flow is formed along the separator 7, and the solution blocked by the separator 7 is collected and guided to the discharge pipe 3. It is burned. Since the bioreactor of the present invention is a circulating fluidized bed type, the solution circulated by the discharge pipe 3 may contain useful substances. The configuration of the separator 7 is not limited to the illustrated one, and the separator 7 may be formed in multiple stages, or may be a filtration filter that allows the treatment liquid U to pass therethrough.

The flow rate adjusting means 8 has a function of adjusting the flow rate of the discharge pipe 3. In the first embodiment shown in FIG. 1, the first outlet 61 to the third outlet 63 and the valve 64, which can change the height of the outlet 6, correspond to the flow rate adjusting means 8. The solution in the main body 1 is pumped from the discharge pipe 3 to the gas-liquid separation tank 2 by the action of a so-called gas lift pump. The gas lift pump raises the solution in the discharge pipe 3 by using the density difference generated between the inlet side and the outlet side of the discharge pipe 3 by supplying gas into the solution and transports it. Here, Equation 1 is a relational expression showing the gas lift pump.

  Hs (pump underwater length) in Equation 1 corresponds to the depth (immersion depth) Hs of the discharge pipe 3 immersed from the liquid surface of the main body 1 in FIG. 1, and H (Gas lift length) in Equation 1 is 1 corresponds to the height (projection height) H of the discharge pipe 3 projecting from the liquid surface of the main body 1 in FIG. As is clear from Equation 1, the immersion depth Hs of the discharge pipe 3 and the protrusion height H of the discharge pipe 3 affect the liquid flow rate Qf fed by the discharge pipe 3. In the present invention, Hs / (Hs + H) in Equation 1 is referred to as the immersion depth ratio of the discharge pipe 3.

  Here, FIG. 2 is a diagram showing the relationship between the gas flow rate Qg, the liquid flow rate Qf, and the immersion depth ratio Hs / (Hs + H) in the discharge pipe. In this figure, the horizontal axis indicates the gas flow rate Qg (liter / minute), and the vertical axis indicates the liquid flow rate Qf (liter / minute). FIG. 2 shows a result of measuring the gas flow rate Qg and the liquid flow rate Qf of the discharge pipe 3 in increments of 0.1 within the range of 0.5 to 1 of the immersion depth ratio Hs / (Hs + H) of the discharge pipe 3. It is. And the smaller the value of the height H of the discharge pipe 3 protruding from the liquid surface of the main body 1, that is, the closer the value of Hs / (Hs + H) is to 1, the smaller the solution in the main body 1 with a gas flow rate Qg. It can be seen that the liquid flow rate Qf with respect to the gas flow rate Qg also increases. Therefore, the circulation of the solution is started with a small gas flow rate Qg by increasing the liquid level of the main body 1 to increase the immersion depth Hs of the discharge pipe 3 and reducing the protruding height H of the discharge pipe 3. The circulation flow rate (liquid flow rate Qf) can also be increased. On the contrary, the circulation of the solution can be delayed by lowering the liquid level of the main body 1 to reduce the immersion depth Hs of the discharge pipe 3 and increasing the protruding height H of the discharge pipe 3. (Liquid flow rate Qf) can also be reduced. Thus, the liquid flow rate Qf circulated through the discharge pipe 3 and the circulation start time are adjusted by adjusting the liquid level of the main body 1 to change the immersion depth Hs and the protrusion height H of the discharge pipe 3. Can be controlled.

  For example, at the beginning of the reaction when the amount of gas generated is small, the solution level can be circulated at an early stage by increasing the liquid level (increasing the immersion depth Hs of the discharge pipe 3 or decreasing the protruding height H of the discharge pipe 3). Even if the gas flow rate Qg is small, a sufficient liquid flow rate Qf can be ensured, and the solution in the main body 1 can be effectively stirred to promote the reaction. When the gas generation amount is excessive, the liquid level is lowered (the immersion depth Hs of the discharge pipe 3 is reduced or the protrusion height H of the discharge pipe 3 is increased), thereby increasing the gas flow rate Qg. Even if it exists, the liquid flow volume Qf circulated can be decreased and the reaction in the main-body part 1 can be suppressed.

  Here, FIG. 3 is a figure which shows the effect | action of 1st embodiment, (A) shows the state which raised the liquid level of the main-body part, (B) shows the case where the liquid level of a main-body part is made low. Yes. As shown in FIG. 3A, by opening the valve 64 of the first outlet 61 and closing the valves 64 of the second outlet 62 and the third outlet 63, the liquid level of the main body 1 is changed. The processing liquid U is discharged from the first outlet 61. 3B, the valve 64 of the third outlet 63 is opened and the valves 64 of the first outlet 61 and the second outlet 62 are closed, so that the liquid in the main body 1 The surface can be lowered, and the processing liquid U is discharged from the third outlet 63. In the steady state, as shown in FIG. 1, the valve 64 of the second outlet 62 may be opened, and the valves 64 of the first outlet 61 and the third outlet 63 may be closed. Thus, according to the flow rate adjusting means 8 (first outlet 61 to third outlet 63 and valve 64) shown in the first embodiment, the height of the outlet 6 can be changed, and the discharge pipe 3 can be adjusted, and the liquid flow rate Qf circulated by the discharge pipe 3 can be controlled.

  Next, another embodiment of the bioreactor according to the present invention will be described. FIG. 4 is a diagram showing another embodiment of the bioreactor according to the present invention, in which (A) is the second embodiment, (B) is the third embodiment, (C) is the fourth embodiment, (D ) Shows the fifth embodiment. Moreover, FIG. 5 is a figure which shows other embodiment of the bioreactor which concerns on this invention, (A) is 6th embodiment, (B) is 7th embodiment, (C) is 8th embodiment, Is shown. In addition, in each figure, about the same component as 1st embodiment shown in FIG. 1, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  In the second embodiment shown in FIG. 4A, the configuration of the outlet 6 is changed. Specifically, one outlet 65 is connected to the side surface of the main body 1, the outlet 65 is branched into a plurality of downstream sides, and a valve 64 is connected to each branch pipe 65a, 65b, 65c. . The branch pipes 65 a to 65 c are arranged in the vertical direction in the same manner as the first outlet 61 to the third outlet 63 of the first embodiment, and the liquid level of the main body 1 is increased by opening and closing the valve 64. It is configured so that the height can be adjusted. Therefore, the immersion depth Hs and the protruding height H of the discharge pipe 3 can be adjusted by the flow rate adjusting means 8 (the outlet 65, the branch pipes 65a to 65c and the valve 64). The liquid flow rate Qf can be controlled.

  In the third embodiment shown in FIG. 4B, the outlet 6 is constituted by a flexible tube 66. The flexible tube 66 can be moved up and down by a slider 67. The flexible tube 66 has flexibility and can be deformed following the vertical movement of the slider 67. The slider 67 is movably disposed along a rail 68 disposed on a pillar member or wall member (not shown), and is configured to be moved up and down automatically or manually by a driving means (not shown). Therefore, by moving the slider 67 up and down, the height of the outlet portion of the flexible tube 66 can be adjusted, and the liquid level of the main body 1 can be adjusted. That is, the immersion depth Hs and the protrusion height H of the discharge pipe 3 can be adjusted also by the flow rate adjusting means 8 (flexible tube 66, slider 67, rail 68, etc.). The flow rate Qf can be controlled.

  In the fourth embodiment shown in FIG. 4C, the immersion depth Hs of the discharge pipe 3 can be adjusted without changing the height of the liquid level of the main body 1. Specifically, one outlet 6 is disposed on the side surface of the main body 1, and the height of the connection position between the discharge pipe 3 and the separator 7 can be changed by expanding and contracting the discharge pipe 3. . The expansion / contraction mechanism of the discharge pipe 3 may be configured such that the discharge pipe 3 itself has a bellows shape, or may be configured to be slidable by connecting a plurality of pipes. Also by the flow rate adjusting means 8 (the discharge pipe 3 and its expansion / contraction mechanism), the immersion depth Hs of the discharge pipe 3 can be arbitrarily adjusted, and the liquid flow rate Qf circulated by the discharge pipe 3 can be controlled. .

  In the fifth embodiment shown in FIG. 4D, a liquid level gauge 69 is installed in the main body 1. Specifically, the liquid level gauge 69 is installed on the inner surface of the upper part of the main body 1, and only one outlet 6 is connected to the side of the main body 1 as in the prior art. 64 is connected. The valve 64 is controlled so as to be opened and closed in conjunction with the liquid level gauge 69, and the opening and closing timing and the opening degree are adjusted so that the level of the liquid level becomes a predetermined value. Therefore, the immersion depth Hs and the protruding height H of the discharge pipe 3 can be adjusted by the flow rate adjusting means 8 (the outlet 6, the valve 64, and the liquid level gauge 69), and are circulated by the discharge pipe 3. The liquid flow rate Qf can be controlled.

  In the sixth embodiment shown in FIG. 5 (A), the protruding height H of the discharge pipe 3 can be changed by the discharge pipe 3 used by arranging a plurality of discharge pipes 3 on the upper part of the main body 1. It is. Specifically, a plurality of discharge pipes 3 (for example, the first discharge pipe 31, the second discharge pipe 32, and the third discharge pipe 33) are connected to the upper part of the main body 1 and the first discharge pipe 31 to the third discharge pipe. A valve 34 is disposed in each of the tubes 33. The first discharge pipe 31 to the third discharge pipe 33 are arranged so as to have different heights in the vertical direction, and are configured so that the discharge pipe 3 to be used can be selected by opening and closing the valve 34. Thus, the value of Hs / (Hs + H) can also be controlled by changing the protrusion height H of the discharge pipe 3. For example, if the first discharge pipe 31 having a large protruding height H of the discharge pipe 3 is used, the denominator of Hs / (Hs + H) becomes large, so that the liquid flow rate Qf circulated by the discharge pipe 3 is suppressed. However, if the third discharge pipe 33 having a small protruding height H of the discharge pipe 3 is used, the denominator of Hs / (Hs + H) becomes small, so that the liquid flow rate Qf circulated by the discharge pipe 3 is increased. To do. Accordingly, the flow rate adjusting means 8 in the sixth embodiment is a means for adjusting the height H of the discharge pipe 3 protruding from the liquid surface of the main body 1, and the discharge pipe 3 (first discharge pipe 31 to third discharge pipe). 33) and a valve 34, and means for changing the height of the connecting portion between the discharge pipe 3 and the gas-liquid separation tank 2.

  In the seventh embodiment shown in FIG. 5 (B), the configuration of the discharge pipe 3 is changed. Specifically, one main discharge pipe 35 is connected to the upper part of the main body 1 and is branched into a plurality of downstream sides of the main discharge pipe 35, and a valve 34 is connected to each branch pipe 35a, 35b, 35c. In addition, a valve 36 is connected between the branch pipes 35 a to 35 c in the main discharge pipe 35. The branch pipes 35a to 35c are arranged in the vertical direction in the same manner as the first discharge pipe 31 to the third discharge pipe 33 of the sixth embodiment, and the discharge pipe 3 protrudes by opening and closing the valves 34 and 36. The height H can be adjusted. Therefore, the projection height H of the discharge pipe 3 can be adjusted by the flow rate adjusting means 8 (the main discharge pipe 35, the branch pipes 35a to 35c and the valves 34 and 36), and the liquid circulated by the discharge pipe 3 can be adjusted. The flow rate Qf can be controlled.

  In the eighth embodiment shown in FIG. 5C, the discharge pipe 3 is configured by a flexible tube 37. Moreover, the slider 21 is connected to the gas-liquid separation tank 2, and it is comprised so that it can move up and down along the rail 22 arrange | positioned at the column member or the wall member. The flexible tube 37 has flexibility and can be deformed following the vertical movement of the gas-liquid separation tank 2. Therefore, the protrusion height H of the discharge pipe 3 can be adjusted by moving the gas-liquid separation tank 2 up and down and changing its height. The protruding height H of the discharge pipe 3 can also be adjusted by the flow rate adjusting means 8 (flexible tube 37, slider 21, rail 22, etc.), and the liquid flow rate Qf circulated by the discharge pipe 3 can be controlled. it can.

  Next, a ninth embodiment of the bioreactor according to the present invention will be described. FIG. 6 is a view showing a ninth embodiment of the bioreactor according to the present invention. In addition, in this figure, about the same component as 1st embodiment shown in FIG. 1, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

In the ninth embodiment shown in FIG. 6, the gas-liquid separation tank 2 side of the discharge pipe 3 is constituted by one main discharge pipe 38, and the main body 1 side of the discharge pipe 3 is a plurality of branch pipes 38a, 38b, 38c. Each of the branch pipes 38a to 38c is connected to valves 39, 39 at both ends. Here, the valves 39 and 39 of the branch pipe 38b are opened, the remaining valves 39 are closed, and the solution in the main body 1 is circulated using only the central branch pipe 38b. In the ninth embodiment, the liquid flow rate Qf is controlled by adjusting the number of branch pipes 38a to 38c to be used without changing the immersion depth Hs and the protrusion height H of the discharge pipe 3. is there. The slip ratio S and the constant K in the relational expression shown in Expression 1 can be converted into a form including the discharge pipe diameter D by using the following relational expressions (Expression 2 and Expression 3).

  Here, FIG. 7 is a diagram showing the relationship between the gas flow rate Qg, the liquid flow rate Qf, and the discharge pipe diameter D of the discharge pipe. In this figure, the horizontal axis indicates the gas flow rate Qg (liter / minute), and the vertical axis indicates the liquid flow rate Qf (liter / minute). FIG. 7 shows the results of measuring the gas flow rate Qg and the liquid flow rate Qf of the discharge pipe 3 in increments of 5 mm within the range of the discharge pipe diameter D in the range of 10 to 30 (mm). It can be seen that the smaller the discharge pipe diameter D, the more the flow of the solution in the main body 1 starts with a smaller gas flow rate Qg. It can also be seen that the larger the discharge pipe diameter D, the later the timing at which the flow of the solution in the main body 1 starts, but the liquid flow rate Qf increases. Therefore, if it is desired to increase the liquid flow rate Qf circulated through the discharge pipe 3, the discharge pipe diameter D may be increased. If it is desired to decrease the liquid flow rate Qf, the discharge pipe diameter D should be reduced. What is necessary is just to make the discharge pipe diameter D small when it is desired to advance the circulation start time by the discharge pipe 3, and it is only necessary to increase the discharge pipe diameter D when the circulation start time by the discharge pipe 3 is to be delayed. By adjusting the discharge pipe diameter D, the liquid flow rate Qf circulated through the discharge pipe 3 and the circulation start timing can be controlled. The adjustment of the discharge pipe diameter D may be performed by increasing or decreasing the diameter of the discharge pipe 3 itself or indirectly by increasing or decreasing the flow path cross-sectional area. .

  For example, at the beginning of the reaction when the amount of gas generated is small, circulation of the solution can be started at an early stage by reducing the discharge pipe diameter D of the discharge pipe 3. Further, by increasing the discharge pipe diameter D of the discharge pipe 3 gradually or stepwise, a sufficient liquid flow rate Qf can be secured even with a small gas flow rate Qg, and the solution in the main body 1 is effective. The reaction can be promoted by stirring. In addition, when the gas generation amount is excessive, by reducing the discharge pipe diameter D of the discharge pipe 3, the circulated liquid flow rate Qf can be reduced even when the gas flow rate Qg is large. The reaction in part 1 can be suppressed.

  Here, FIG. 8 is a diagram showing the operation of the ninth embodiment, where (A) shows the flow passage area of the discharge pipe: the middle state, and (B) shows the flow passage area of the discharge pipe: the large state. Show. As shown in FIG. 8A, by using only two branch pipes 38a and 38b by closing only the valve 39 of the branch pipe 38c and opening the valve 39 of the other branch pipes 38a and 38b. The solution in the main body 1 can be circulated. Therefore, compared with the case where only one branch pipe 38b shown in FIG. 6 is used, the cross-sectional area of the discharge pipe 3 can be increased, and the discharge pipe diameter D of the discharge pipe 3 can be indirectly increased. It is possible to increase the circulating liquid flow rate Qf. Further, as shown in FIG. 8B, if all the valves 39 of the branch pipes 38a to 38c are opened, the solution in the main body 1 is circulated using all the branch pipes 38a to 38c. Can do. Therefore, the flow passage cross-sectional area of the discharge pipe 3 can be increased more than the state shown in FIG. 8A, the discharge pipe diameter D of the discharge pipe 3 can be increased indirectly, and the circulating liquid flow rate Qf can be increased. The flow rate adjusting means 8 (the discharge pipe 3 and the valve 39) is a means for adjusting the flow passage cross-sectional area of the discharge pipe 3, that is, the discharge pipe diameter D, and is configured so that the number of the discharge pipes 3 to be used can be switched. Means.

  Next, another embodiment of the bioreactor according to the present invention will be described. FIG. 9 is a diagram showing another embodiment of a bioreactor according to the present invention, in which (A) is a tenth embodiment, (B) is a modification of the ninth embodiment, and (C) is a tenth embodiment. The modification of is shown. In addition, in each figure, about the same component as 9th Embodiment shown in FIG. 6, the same code | symbol is attached | subjected and the overlapping description is abbreviate | omitted.

  In the tenth embodiment shown in FIG. 9A, the diameters of the branch pipes 38a to 38c in the ninth embodiment are changed. When the diameter of the branch pipe 38a is d1, the diameter of the branch pipe 38b is d2, and the diameter of the branch pipe 38c is d3, here, d1> d2> d3. Thus, by changing the diameter of the branch pipes 38a to 38c, for example, the branch pipe 38c alone → the branch pipe 38b alone → the branch pipe 38a alone → the branch pipe 38a + the branch pipe 38c → the branch pipe 38b + the branch pipe 38c → the branch. The flow passage cross-sectional area of the discharge pipe 3 can be adjusted like a pipe 38a + a branch pipe 38b + a branch pipe 38c, and finer adjustments can be made than in the ninth embodiment shown in FIG. The flow rate adjusting means 8 (discharge pipe 3 and valve 39) in the tenth embodiment is a means for adjusting the flow passage cross-sectional area of the discharge pipe 3, that is, the discharge pipe diameter D, and switches the number of discharge pipes 3 to be used. It is a means to comprise, and it is also a means to comprise so that the piping diameter of the discharge pipe 3 can be switched.

  In the modification of the ninth embodiment shown in FIG. 9B, the number of branches of the discharge pipe 3 is increased to nine (branch pipes 38a to 38i). Further, in the modification of the tenth embodiment shown in FIG. 9C, the main branch pipe 38a having a large diameter is formed at the center while the number of branches of the discharge pipe 3 is increased to nine (branch pipes 38a to 38i). The auxiliary branch pipes 38b to 38i having a small diameter are arranged around the auxiliary branch pipes 38b to 38i. By selecting the branch pipe to be used also by these configurations, the flow passage cross-sectional area of the discharge pipe 3 can be adjusted, and the discharge pipe diameter D of the discharge pipe 3 can be adjusted indirectly, and circulates. The liquid flow rate Qf can be controlled. 9B and 9C are drawings corresponding to a cross section taken along line XX in FIG. 9A.

  In the bioreactors of the first embodiment to the tenth embodiment described above, the raw material M is introduced into the solution containing the biocatalyst C, and the reaction solution is produced by the reaction gas g generated by the reaction between the raw material M and the biocatalyst C. The processing liquid U from which the biocatalyst C is removed from the reaction solution is released to the outside of the system, and the liquid containing the collected biocatalyst C is separated into gas and liquid while adjusting the liquid flow rate Qf according to the operating condition of the bioreactor. The operation is carried out by feeding to the tank 2 and removing the reaction gas g in the gas-liquid separation tank 2 and sending the residual solution back to the reaction vessel (main body part 1). In particular, the bioreactor according to the present invention is operated so that the liquid flow rate Qf sent to the gas-liquid separation tank 2 is increased at the start of operation or when the reaction is promoted, and the gas-liquid separation tank is maintained during steady operation or when the reaction is maintained. The liquid flow rate Qf sent to the gas-liquid separation tank 2 is operated so as to decrease when the operation is stopped or the reaction is suppressed.

For example, the liquid flow rate Qf during steady operation is the minimum liquid flow rate Qmf required for the solution containing the biocatalyst C to circulate between the main body 1 and the gas-liquid separation tank 2 to the biocatalyst C. 6 is controlled within the range of the liquid flow rate Qt that does not flow out of the fuel cell 6. The liquid flow rate Qmf is obtained by the equation (4). In order to stabilize fluidization, the liquid flow rate Qmf is actually operated so as to be about 2 to 5 times the liquid flow rate Qmf. Further, the liquid flow rate Qt is obtained by Equation 5. Specifically, in the case of a bioreactor having a main body 1 having an inner diameter of 100 mm and using biocatalyst C having a particle diameter of 0.3 to 0.5 mm and a specific gravity of 1.2, The liquid flow rate Qf is preferably controlled within a range of 0.5 to 5.0 liters / minute.

  The present invention is not limited to the above-described embodiments. For example, the present invention may be combined with the first embodiment to the tenth embodiment as appropriate in various gas generation processes such as methane fermentation and denitrification other than ethanol fermentation. Needless to say, various modifications can be made without departing from the spirit of the present invention, such as application.

DESCRIPTION OF SYMBOLS 1 ... Main-body part 2 ... Gas-liquid separation tank 2a ... Bottom 2b ... Upper space 2c ... Exhaust port 3 ... Exhaust pipe 3a ... One end 3b ... Other end 4 ... Return pipe 4a ... One end 4b ... Other end 4c ... Replenishment port 4d ... Meter 5 ... Supply port 6, 65 ... Take-out port 7 ... Separator 8 ... Flow rate adjusting means 21 and 67 ... Slider 22 and 68 ... Rail 31 ... First discharge pipe 32 ... Second discharge pipe 33 ... Third discharge pipes 34 and 36 , 39, 64 ... Valves 35, 38 ... Main discharge pipes 35a-35c, 38a-38i, 65a-65c ... Branch pipes 37, 66 ... Flexible tube 61 ... First outlet 62 ... Second outlet 63 ... Third outlet Exit 69 ... Level gauge

Claims (7)

A bioreactor that produces a useful substance by reacting a raw material and a biocatalyst in a solution and takes out a treatment liquid containing the useful substance,
A main body constituting the reaction vessel;
A gas-liquid separation tank disposed outside the main body,
A discharge pipe having one end immersed in the main body and the other end connected to the gas-liquid separation tank;
A return pipe having one end connected to the bottom of the gas-liquid separation tank and the other end connected to the main body below the discharge pipe;
A supply port for introducing the raw material into the main body;
An outlet that is disposed above the supply port and takes out the processing liquid from the main body;
A separator that is disposed between the supply port and the outlet and collects the biocatalyst;
Flow rate adjusting means for adjusting the flow rate of the discharge pipe,
The raw material introduced from the supply port reacts with the biocatalyst in the main body to produce a useful substance, the solution containing these is raised by the buoyancy of the reaction gas, and the treatment liquid that has passed through the separator is removed from the process. The solution containing the biocatalyst discharged from the outlet and collected by the separator is sent from the discharge pipe to the gas-liquid separation tank while the flow rate is controlled by the flow rate adjusting means, and the reaction gas is sent to the gas-liquid separation tank And a residual solution is sent back from the return pipe to the main body.   The flow rate adjusting means is either a depth of the discharge pipe immersed from the liquid level of the main body part, a height of the discharge pipe protruding from the liquid level of the main body part, or a channel cross-sectional area of the discharge pipe. The bioreactor according to claim 1, wherein the bioreactor is means for adjusting.   The bioreactor according to claim 2, wherein the means for adjusting the depth is a means for changing the height of the outlet.   The means for adjusting the height is a means for changing the height of the gas-liquid separation tank or a means for changing the height of a connection portion between the discharge pipe and the gas-liquid separation tank. The bioreactor according to claim 2.   The means for adjusting the cross-sectional area of the flow path is a means for configuring the number of the discharge pipes to be switchable or a means for configuring the pipe diameter of the discharge pipes to be switchable. Item 3. The bioreactor according to Item 2. A method for operating a bioreactor, in which a raw material and a biocatalyst are reacted in a solution to produce a useful substance, and a treatment liquid containing the useful substance is extracted.
Injecting the raw material into a solution containing the biocatalyst,
The reaction solution is raised by the reaction gas generated by the reaction between the raw material and the biocatalyst,
Release the treatment liquid from which the biocatalyst has been removed from the reaction solution to the outside of the system,
The collected solution containing the biocatalyst is sent to the gas-liquid separation unit while adjusting the flow rate according to the operation status of the bioreactor,
Removing the reaction gas in the gas-liquid separator and sending the residual solution back to the reaction vessel;
A method of operating a bioreactor characterized by the above.   In the bioreactor, the flow rate sent to the gas-liquid separation unit at the start of operation or reaction promotion is increased, and the flow rate sent to the gas-liquid separation unit during steady operation or reaction maintenance is maintained substantially constant, The method of operating a bioreactor according to claim 6, wherein the flow rate sent to the gas-liquid separation unit when the operation is stopped or when the reaction is suppressed is reduced.