SU1404523A1 - Apparatus for growing microorganisms - Google Patents

Abstract

The invention can be used when growing aerobic microorganisms and is aimed at reducing the specific energy consumption. The apparatus consists of a cylindrical tank with a zigzag and concentrically mounted diffuser and cup, under which. {And the aerator is located. In the diffuser and the glass there are recirculation slotted holes, fitted with a damper, connected to the actuators. The signal to actuators comes from the dissolved oxygen sensor located in the culture fluid. When the par tial pressure of dissolved oxygen deviates from the optimal value, the signal to the actuating mechanisms that close or open the recirculation holes changes the return of a part of the gas – liquid mixture to the aerator. This ensures optimal gas content in the culture fluid.,. specific energy consumption is reduced and exhaust gas emissions are reduced. 4 il. G C

Description

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The invention relates to microbiological equipment, namely, apparatus for growing aerobic. microorganisms such as yeast.

The circuit of the invention is the reduction of the specific energy consumption for fermentation.

FIG. 1 shows the proposed apparatus, a vertical section; in fig. 2 shows section A-A in FIG. one; in fig. 3 is a view B in FIG. one; FIG. 4 is a view B of FIG. 2

The device for growing microorganisms contains a cylindrical tank 1 with a lid 2, an aerator 3, a concentrically mounted diffuser 4 and a cup 5, a heat exchanger 6 located between the diffuser and the cup, feed nozzles 7-11, nutrient medium, exhaust gas exhaust, supply and exhaust cooling water, the sensor 12 of dissolved oxygen, the controller 13 and the actuators 14, located on the lid 2 of the device. The diffuser 4 and the beaker 5 have recirculation slotted openings 15, fitted with valves 16, connected by rods 17 to the actuators 14.

The device works as follows.

When the aerator 3 is rotated, a circulation one is installed in the apparatus. fluid movement. The fluid from the diffuser 4 and the space between the cup 5 and the wall of the container 1 is sucked in and ejected by the aerator 3. At the same time, the vacuum created by the fluid flowing at high speed draws atmospheric air through the nozzle 7. The gas-liquid mixture flows into the heat exchanger 6, where it is cooled . Part of the gas-liquid mixture enters through the recirculation holes 15 to the aerator 3. The other part is degassed.

Exhaust gas is discharged through the pipe 9. When the deviation of partial

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pressure of the oxygen dissolved in the -cultural fluid from a given value in the direction of decreasing or increasing the dissolved oxygen sensor 12 rotates the signal to the regulator 13, the signal from the regulator goes to the executive mezanizm 14, which, rotating the rods 17, cover or open recirculation orifices 15 change the return of a part of the gas-liquid mixture to the aerator 3. The amount of air sucked by the aerator varies depending on the gas content of the culture liquid. This reduces the power consumed by the aerator and reduces emissions to the atmosphere.

The presence of recirculation orifices with shutters that are electrically connected to the dissolved oxygen sensor in the liquid allows the gas content of the culture fluid to change in front of the aerator, which leads to a decrease in the specific air flow rate and specific energy consumption by 10-15%.

Claims (1)

Invention Formula An apparatus for growing microorganisms, containing a cylindrical container with a lid, an aerator, a diffuser, a cup mounted concentrically with it, a heat exchanger located between the diffuser and the cup, air inlets, nutrient medium, exhaust gas for supplying and discharging cooling water, distinguished by that, in order to reduce energy consumption, the device is equipped with a dissolved oxygen sensor, a regulator and actuators located on the lid of the device, and a diffuser and a glass have recirculation points left holes and fitted with valves connected by rods with actuators. Phi2.2 FIG. four