SU1504247A1 - Arrangement for mainaining gas phase in cell cultivator - Google Patents

Abstract

The invention relates to a biological technique, namely, devices for maintaining the gas phase when growing cells in a cultivator, and may find application in both the medical and microbiological industries. The purpose of the invention is to improve the accuracy of maintaining CO ₂ in the gas phase by reducing the time of the transition process. The device is equipped with a CO ₂ concentration sensor, made in the form of two bridge circuits, and contains two temperature-sensitive elements, measuring and comparative, each of which is included in one of the arms of the corresponding bridge circuit, the output of the sensor is connected to an amplifier, the output of which is connected to serially connected analog -digital converter and display unit. 1 il.

Description

The invention relates to a biological technique, namely, devices for maintaining the gas phase when growing cells in a cultivator, and may find application in both the medical and microbiological industries.

The purpose of the invention is to improve the accuracy of maintaining the CO concentration in the gas phase by reducing the time of the transient process.

FIG. Figure 1 shows a block diagram of a device for maintaining the gas phase in a cell cultivator.

The device contains a CO concentration sensor 1 installed outside the cultivator 2 and connected to an amplifier 3, the output of which is connected to serially connected analog-to-digital converter 4 and the display unit 5, power supply unit 6, setting device 7, switch 8, connected to solenoid valve 9, installed on the CO supply line, and a pump 10 installed on the supply line of the controlled mixture from the cultivator 2 to the CO concentration sensor 1, and a cooler II installed on the supply line of the controlled gas mixture.

In addition, the device has two operational amplifiers 12 and 13, two emitter repeaters 14 and 15 on transistors, a comparison unit 16, the first input of which is connected to the setpoint 7, the second input to the output of the amplifier 3, and the output to the key input 8. Sensor 1 of CO concentration contains two bridge circuits and is made on two temperature-sensitive elements - measuring

17 and comparative 18, each of which is included in one of the shoulders of the corresponding bridge circuit. The measuring diagonals of the bridge circuits are connected to the inputs of the respective operational amplifiers 12 and 13, the outputs of which are connected to the bases of the transistors of the emitter followers 14 and 15, and the emitters of these transistors are connected to the inputs of the amplifier 3 and the corresponding points of these diagonals are connected between and are connected to one of the poles of the power supply unit 6, the second pole of which is connected to the common connection point of the emitter follower collectors 14 and 15.

The device works as follows.

The working gas mixture in the cultivator is formed from two components — air and CO. The CO is supplied through the solenoid valve 9. With the help of the pump 10, the sample of the gas mixture is pumped to the CO concentration sensor 1. The mixture diffuses into the working chamber of the measuring thermosensitive element 17, included in the measuring bridge circuit. The next system, consisting of the operational amplifier 13 and the emitter follower 15, maintains a constant imbalance at the inputs of the operational amplifier 13. At the same time, with the thermal conductivity of the analyzed gas, the resistance (temperature) of the measuring temperature-sensitive ale. Step 17 remains unchanged, and the voltage across the supply circuit of the bridge circuit changes.

Similarly, the second bridge circuit works with the comparative element 18, enclosed in a sealed chamber with air. The mode of this bridge circuit is provided by the operational amplifier 12 and the emitter follower 14. The supply voltages of these bridge circuits with the output of the repeaters 14 and 15 simultaneously arrive at the inputs of the amplifier 3, where the signals are subtracted and their difference is amplified.

From the output of this amplifier, the signal goes to analog-to-digital converter 4 and further to display unit 5, from which the digital reading of the volume fraction of CO-j in the gas mixture is taken. Besides.

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from the output of the amplifier 3, the signal is fed to the second input of the reference unit 16. A control unit 7 is connected to the first input of this unit. The comparison unit 16 generates a command signal for the electromagnetic valve 9 to operate from the output through the switch 8. The command to supply CO2 to the cultivator 2 through the electromagnetic valve 9 is output if the signal value at the input of the reference unit 16 corresponds to the volume fraction of CO in the analyzed mixture is below a predetermined value at setting point 7.

Drainage of the analyzed sample entering the CO concentration sensor 1 is performed using a thermoelectric cooler 10.

Comparative tests of this device with the known showed that the transition time was reduced by a factor of 9-12 (from 180 s to 15-20 s). This makes it possible to increase the accuracy of maintaining the volume fraction of CO in the gas phase of the cell cultivator.

Claims (1)

Claims. A device for maintaining the gas phase in a cell cultivator, containing a CO concentration sensor, installed outside the cultivator and connected to an amplifier, the output of which is connected to the serially connected analog-digital converter and the display unit, the power supply unit, the setpoint switch, the key connected to the solenoid valve installed on the CO supply line, and a pump installed on the supply line of the controlled gas mixture from the cultivator to the COj concentration sensor, made in the form of a bridge circuit, characterized in that The goal of maintaining the accuracy of maintaining the CO concentration in the gas phase by reducing the transient time, it is additionally equipped with two operational amplifiers, two emitter followers, a cooler installed on the supply line of the controlled gas mixture, and a comparison unit, the first input of which is connected to the sensor, the second input is to the amplifier output, and the output is to the key input, while the CO concentration sensor is provided with an additional bridge circuit and is made on two heat-sensitive elements, measuring and comparative, each of which is included and one of the arms of the corresponding bridge circuit, the measuring diagonals of the bridge circuits are connected to the inputs of the corresponding operational amplifiers, the outputs of which are connected to the bases of the transistors of the emitter followers, and the emitters of these transistors connected to the amplifier inputs and to the corresponding points of the supply diagonals of the bridge circuits; other points of these diagonals are interconnected and connected to one of the poles of the power supply unit, the other pole of which is connected to the common connection point of the emitter follower collectors.  Have