SU1541260A1 - Apparatus for cultivating microorganisms on gaseous substrates - Google Patents

Abstract

The invention relates to the microbiological industry and research practice in this area and is used in the cultivation of methane-acidifying bacteria in a gas-closed circuit. The purpose of the invention is to increase productivity. The apparatus contains a fermenter 1, a pressure regulator 21, a gas concentration regulator 29, 31, a gas mixture recirculation loop 9 with a variable volume tank 2, a gas mixture flow booster 10, a desiccant 6, 12 to 14 gas analyzers, an absorber 8 CO ₂ and device 16, 18 feed gases. A variable volume tank 2 is made of an elastic or resilient material, enclosed in a sealed casing 25 and provided with a pressure follower 3 as a compensator for its deformation, and the pressure sensor setter 26 cavity to provide some delay in equalizing the pressures inside the variable volume 2 and its casing 25 is connected to the output of the gas mixture from the tank 2 of variable volume through an adjustable air throttle 5, and the actuating cavity 27 of this repeater 3 is connected to the hermetic casing 25, the tank is variable Volume 2 may be equipped with an anti-contraction spring 24 to increase the elasticity of this tank 2 as the deviation of its volume increases from the neutral position, gas analyzers 12-14 are connected in parallel to the main gas recirculation loop 9, which is entered through an adjustable throttle 11 from the gas cavity of the fermenter 1, and the output is connected to the inlet of the flow booster 10

Description

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, (21) 4372026 / 31-13 (22) 01.27.88 (46) 07.02.90. Bul № 5

(71) Special Design Bureau for Biological Instrument Making

USSR Academy of Sciences

(72) B.F.Nesterov

(53) 663.1 (088.8)

(56) .Patent of France No. 1526746, cl. From the 12th, 1968.

(54) APPARATUS FOR CULTIVATING MICROORGANISMS ON GASEOUS SUBSTRATES

(57) The invention relates to the microbiological industry and research practice in this area and is used in the cultivation of methacidic acid bacteria in a gas-enclosed scheme. The purpose of the invention is to increase productivity. Apparatus

contains the fermenter 1, pressure regulator 21, gas concentration regulators 20, 31, gas mixture recirculation circuit with variable volume tank 2, gas mixture consumption booster 10, desiccant 6, gas analyzers 12-14, 8 CO absorber and device 16, 18 feed gas. A variable volume tank 2 is made of an elastic or resilient material, enclosed in a hermetic casing 25 and equipped with a pressure follower 3, as a compensator for its deformation, the cavity of the setting device 26 of the pressure follower 3 to provide some delay in equalizing the pressures inside the vessel 2 / belt volume and its casing 25 is connected with the release of the gas mixture from the tank 2 of variable volume through re

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a controllable air throttle 5, and the executive cavity 27 of this repeater 3 is connected to a hermetic casing 25, the tank of variable volume 2 can be equipped with an expansion-strut spring 24 to increase the elasticity of this tank 2 with an increase in its volume from

This invention relates to the microbiological industry.

The aim of the invention is to increase productivity.

The drawing shows a schematic diagram of an apparatus for cultivating microorganisms on gaseous substrates.

The apparatus contains a fermenter 1 and a gas mixture recirculation circuit, which includes a variable volume tank 2 connected with a pressure follower 3 and pneumatic channels 4 and 5, a dryer 6, a controlled valve 7 and a carbon dioxide absorber 8, parallel to them a throttle 9, a flow booster 10 . Parallel to the main recirculation circuit, a line is connected with an adjustable air throttle 11 and serially connected analyzers 12-14 at CIL, at 0 and CO-g (in principle, analyzers 12-14 can be connected in parallel), closes the recirculation circuit of the bubbler 15 installed in fermenter 1.

To the inlet of the recirculation circuit to the bubbler 15, a device for feeding the gas mixture is connected, which consists of controlled valves 16-18 for supplying nitrogen, methane and oxygen, respectively, and the biofilter 19.

In the gas cavity of the fermenter 1, a pressure sensor 20 is installed connected to an overpressure regulator 21, the control circuits from which are connected to the nitrogen supply valve 16 and to the gas discharge valve 22 from the fermenter to the atmosphere, in which line a biofilter 23 is installed.

A variable volume tank 2 is made of an elastic or resilient material (rubber, rubber fabric, polymer films, etc.) and a template of the spacer-tensioning spring 24 inside the neutral position, gas analyzers 12-14 are connected in parallel to the main gas recirculation circuit, the entrance to them made through an adjustable air throttle 11 directly from the gas cavity of the fermenter 1, and the output is connected to the inlet to the flow booster 10. 1 ep f-ly, 1 ill.

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At that, the container is located in a rigid hermetic casing 25.

The spring 24 is fixed at both ends on the ends of the container 2 and has the property when expanding the container 2 is greater than some of its average position of tightening this container, and when compressing it less than the average position - expansion of this container. When this spring 24 has a low stiffness.

The pressure follower 3 has a controller cavity 26 and an actuator cavity 27 separated by an elastic membrane 28. The corresponding regulators 29-31 of CH4, 0 and COj are connected to the gas analyzers 12-14 and connected to control valves with valves 16-18 and 7

The device works as follows.

The fermenter 1 is filled with the culture suspension in the nutrient medium, the concentration of methane and oxygen in the gas phase, and the excess pressure in the fermenter is adjusted to the specified values using regulators 29-31. The booster 10 is turned on and the gas mixture begins to be recirculated along the main closed loop and in parallel through the line of gas analyzers 12-14. Both of these flows are provided by the operation of one booster 10, while the fraction of the flow of the gas mixture through the gas analyzers 12-14 gases (this fraction is significantly less than the flow through the main recirculation circuit) is set by an adjustable throttle 11.

If the technological reasons require changing the amount of recirculation along its main circuit, the adjustment by means of the throttle valve 11 ensures that the flow of the gas mixture through the analyzers 12-14 remains within the limits required by their technological requirements.

Connecting the entrance to the gas analyzers to the gas cavity of the fermenter 1 provides the shortest way to deliver the sample gas mixture directly from the fermenter to these analyzers, which significantly speeds up the flow of relevant information from the analyzers 12-14 to the regulators 29-31 and thereby improves the accuracy of their regulation.

At the initial stage of operation of the fermenter 1 and its recirculation circuit, the control valves 7, 16-18 and 22 are closed, the gas mixture constantly passes through the dryer 6, where it is freed from excessive moisture, which in turn facilitates the work of the CO absorber, the booster 10 and the bubbler 15, the variable volume tank 2 and its spring 24 occupy an average, neutral position, the pressures in it and in the case 25 are balanced.

The principle of operation of a variable volume tank 2 in combination with a pressure follower 3 is as follows. With the slightest increase or decrease in pressure in the fermenter 1 and, consequently, in the tank 2 of variable volume, it does not have time to transfer to the cavity 26 of the repeater 3 due to the resistance of the pneumogrowth 5. As a result, the air pressure of the cavity 27 of the repeater 3 and in the casing 25 that time is the same. At the same time, the tank reacts to this pressure change in it, expands or contracts, and thus compensates for an attempt to change the pressure in the fermenter 1. Possible increase or decrease in air pressure in the rigid hermetic casing 25 due to such compensating deformations of the tank is immediately eliminated by opening the membrane 28 with atmospheric air discharge in the cavity 27 or by closing it with the same membrane and feeding the cavity 27 with air through the air throttle 4.

Spring 24 gives tank 2 some weak resilience. When the vessel expands or contracts from the middle, neutral position, the spring 24 tends to compress it (the tank) or expand it and thus creates a small or excessive pressure inside it, which is transferred to the cavity 26 and then through

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repeater 3 in the housing 25, which balances the position of the tank.

As the biochemical process in the fermenter proceeds, 1 part of methane and oxygen is gradually assimilated by the culture cells, and C02 is released into the gas mixture. The analyzer 14 C02 signals an increase in the content of C0.2 in the mixture to the regulator 31, at the command of which the control valve 7 opens and part of the main recirculation flow, detected by the air throttle, passes through an absorber 8 of carbon dioxide, resulting in the content of COi in the mixture is reduced. As soon as the CO value in the gas mixture reaches the lower predetermined level, the regulator 31 closes the valve 7 and the absorption of C0a stops until the level of the concentration of CO 3 is set again in the regulator 31.

At the same time, according to information from analyzers 12 and 13 of methane and oxygen about the fall in the concentration of these gases below a predetermined level, the regulators 29 and 30 (together or separately) open valves 17 and 18 and feed the mixture of gases in the fermenter 1 to the required concentration of methane and oxygen through biofilter 19, then, the corresponding commands of the regulators 29 and 30 close the valves 17 and 18.

However, such feeding with methane and oxygen to a predetermined level of their concentration does not always correspond to the simultaneous maintenance of a given pressure in the fermenter. As a rule, it leads to an excess of the predetermined pressure level in the fermenter, also because of the inertia of the control systems (the capacity of the pipelines, the response time of the analyzers, etc.). Capacity 2 eliminates this disadvantage. With the introduction of volumes of gases into the fermentation system, which may cause an undesirable increase in pressure in it, the capacity expands, and the pressure follower 3 compensates for the decrease in air space in the casing 25 by releasing a portion of air from it through the cavity to the atmosphere.

The adjustable throttle 5 provides a small time delay in the equalization of pressure in the cavity 26 of the repeater 3, following its initial change in the tank 2, thereby enabling this elastic

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The capacity of the vessel is expanded or contracted due to fluctuations or slight pressure drifts in the fermentation system. The adjustability of the pneumatic distributor 5 is necessary in order to be able to adjust on the fly the entire system of joint control of gas concentration and pressure when there is a change in the volume of filling the fermenter with liquid or gas flow rates through valves 16-18 when they are opened. In this case, if the increase or decrease in pressure in the fermentation system is associated with a change in the setpoint of the pressure regulator 21 and is of a long-term nature, the air throttle does not prevent the repeater 3 from operating and the corresponding pressure equalization of the air in the casing 25.

The pressure regulator 21 and the relief and make-up valves 22 and 16 come into operation when capacity 2 exhausts its capabilities, i.e. shrinks or expands to its limit and ceases to be a compensator for pressure changes.

This mode of operation may be caused by a change in the setpoint of the value of the specified overpressure in the regulator 21 or a change in the setpoints of the value specified by the concentration of CH4 or Oi (or both) in regulators 29 and 30, or by discharging from the fermenter a sufficiently large amount of suspension or topping up there is also a large amount of nutrient medium, or emergency microexplosions (pops) of the gas mixture inside the fermentation system.

In such cases, the pressure sensor 20 supplies information to the pressure regulator 21 and, if the actual pressure in the fermenter 1 diverges from the setpoint value in the controller 21, the latter sends commands to its actuators: when the pressure in the fermenter exceeds the preset level, the controlled one opens the valve 22 and the excess gas mixture is discharged from the fermenter 1 through the biofilter 23 to the atmosphere to a predetermined pressure value. In this case, a possible overshoot (a slight delay in closing the valve 22) is compensated for by compressing the container, which is previously in the extended position. It encourages her to stretch the spring 24 and a little

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delayed in equalizing the excess air pressure in the casing 25. When the pressure drops below a predetermined level, the control valve 16 for supplying nitrogen to the fermenter opens.

Raising the pressure in the fermenter 1, nitrogen simultaneously begins to decrease the concentration of CH4 and 02 in it, therefore, following the supply of nitrogen, at the commands of the regulators 29 and 30, valves 17 and 18 of the supply of CH are opened. and 02. This process continues until the pressure reaches a predetermined value, while the gas concentrations are within the prescribed limits.

A possible overshoot of the pressure, due to the fact that the regulators 29 and 30 continue for some time to feed the mixture with methane or oxygen, bringing their concentration to the desired level, is compensated by the expansion of the tank 2, which is previously in a compressed position. This is caused by a compressed spring 24 and a slight negative pressure (as compared with the capacity) of the air in the casing 25, which is slightly late in alignment.

If the concentrations of CH and Oz are exceeded above the preset levels, the regulators 29 and 30 turn on (together or separately) the control valve 16 and supply nitrogen to reduce these concentrations. In this case, the vessel 2 of variable volume compensates the pressure similarly to the indicated one.

The proposed apparatus makes it possible, by leading the cultivation process in an economical, closed scheme of providing the culture with gases, to achieve the precision of the joint control of the overpressure and concentration of gases in the fermenter and thereby increase the productivity of the apparatus.

Claims (2)

1. An apparatus for cultivating microorganisms on gaseous substrates containing a fermenter, pressure regulators and gas concentrations, a gas mixture recirculation loop with a variable volume tank, a gas mixture booster, a desiccant, gas analyzers, a CO absorber. and a make-up device, characterized in that, in order to increase productivity, it is equipped with a pressure follower, three adjustable pneumatic channels and a sealed casing, wherein the variable volume container is enclosed in a sealed casing and made of an elastic or resilient material, and the follower cavity of the follower is through one From adjustable air throttles, it is connected to the gas outlet from the variable volume tank; the actuator cavity of this repeater is connected to a sealed casing and a second regulator uemym Unidirectional, the analyzers' input through the third adjustable air throttle is connected directly to the output gas cavity of the fermenter, and the analyzers output to the suction nozzle to impel the flow of the gas mixture, and the gas analyzers are installed parallel to the gas mixture recirculation circuit. 2. The apparatus pop. 1, which differs from the fact that the variable volume tank is equipped with a spring.