SU1634961A1 - Apparatus for cryogenic preservation of biological products - Google Patents

Abstract

The invention relates to a cryogenic technique and can be used, for example, in creating blood banks. The aim of the invention is to increase the preservation of bioproducts by maintaining a stable temperature in the chambers. The chambers 3 communicate with the tank 1 for the cryoagent through pipelines 2 connected to the collector 15. The signal from the sensors 5 and 6 of the upper and lower levels of the cryoagent in the chambers 3 is fed to the chamber filling control unit 4. The cryoagent pairs generated during chilling of the collector 15 enter into the steam collector 10. At the end of the cooling down, a liquid cryoagent enters the steam collector 10. The signal of the sensor 12 of the lower level of the block 14 of the control valve 13 of the discharge of the vapor of the cryoagent from the steam collector 10 gives a signal to the block 4, which issues a command for simultaneous refueling of all the chambers 3. The supply of the cryoagent in each of the chambers 3 is turned off automatically liquid cryoagent in it. When the ratio of the intervals between refueling and the duration of refueling recorded by the diagnostic block 16 is changed, the more permissible value of the block 16 gives information about the quality violation of the thermal insulation of the corresponding chamber 3, I il. (L a oo 4 CO 05

Description

The invention relates to a cryogenic technique, in particular to installations for cryocong biological products, and can be used, for example, in creating blood banks.

The aim of the invention is to increase the preservation of bioproducts by maintaining a stable temperature in the chambers.

The drawing shows a setup for cryopreservation of bio-products.

The unit for cryopreservation of boproducts contains a tank 1 for a liquid agent, connected by pipelines 2 of its supply with chambers 3 for biological products, unit 4 controls the charging of chambers 3 cryo-

placed in chambers 3, sensors 5 and 6, respectively, of the upper and lower levels of the cryoagent, installed on pipelines 2 shut-off valves 70 Capacity I communicated with the device 8 to maintain the pressure in the tank 1 necessary to extrude the cryoagent, for example, by evaporating part of the liquid Cryo-installation The unit is equipped with a synchronizer unit 9, the input of which is connected with the output of the unit 4 to control the charging of chambers 3, with a steam collector 10 in the form of a vertical vessel with sensors 11 and 12, respectively, located at the top and bottom liquid cryoagent levels, a cryoagent vapor discharge valve 13 and a valve control unit 14 associated with level sensors 11 and 12 in the steam collector 10, and with block 4 filling the chambers 3 "Piping 2 for supplying the liquid cryoagent to chambers 3 are connected to common collector 15, one end of which is connected to the tank 1 and the other to the bottom of the steam collector 100 Sensors 6 of the lower level of the cryoagent of all chambers 3 are connected to the inputs of the control unit 4, and shut-off valves 7 of all chambers 3 to the output of the unit - synchronizer 9

The installation contains a diagnostic unit 16 associated with a unit 4 controlling the charging of chambers 4 and through unit 14 with a sensor 11 of the upper level of a cryoagent in a steam collection chamber 10 "

Installation for cryopreservation of bioproducts works as follows.

When the cryoagent level in any of the chambers 3 drops to the permissible level — the minimum by the signal of the sensor 6 of the lower level of this chamber — device 8 is turned on, and the control unit 14 opens the valve 13 and turns on the sensor 12 of the lower level of the liquid cryoagent in the steam collector 10 " the liquid cryoagent begins to flow from the tank 1 into the collector 15, and the cryoagent steam formed during cooling down of the collector 15 is discharged from the steam collector 10 through the valve 13. After the cooling of the collector 15, the steam collector 10 begins to flow

liquid cryoagent0 But the signal of the sensor 12 of the lower level unit 14 closes the valve 13, turns off the sensor 12 and gives the corresponding signal to the unit 4 of the automatic control of filling the cryoagent into the chamber 3, which issues a command to simultaneously load all the 3 cells

In this case, the synchronizer block 9 turns on the valves 7 of all the involved chambers 30 Shutting off the supply of the cryoagent to each of the chambers 3 occurs automatically according to a signal from the sensor 5 of the upper level of the liquid cryoagent of the corresponding chamber 3

The diagnostic unit 16 fixes the number of the camera 3, which gave a signal for refueling, the time interval between refueling and the duration of refueling of each of the cameras 3, and also compares this data with the corresponding data recorded in the initial period of operation. When the ratio of the intervals between refueling and the duration of refueling is changed more than acceptable The diagnostics unit values 16 provide information on the quality violation of thermal insulation.

In case of valve leakage 13, the liquid cryoagent fills the steam collector 10 and, according to a signal from the upper level sensor 11, the block 14 provides information to the diagnostics block 16 about the leakage of the valve 13 of the vapor discharge

 The application of the invention allows to ensure a stable temperature of the cryopreservation chambers 3 by preventing the flow of warm gas into the chambers when they are refilled with a cryoagent; reduce the number of cooling reservoirs and pipelines for supplying the cryogen to the chambers and, accordingly, reduce the consumption of cryo. agent for cooling down.

In addition, the simultaneous refueling of cameras based on signals from one of them allows one to diagnose the state of thermal insulation of chambers and to predict possible violations of the convenience mode due to the deterioration of the quality of thermal insulation.

All this ensures the maintenance of a stable temperature regime in the chambers and an increase in the safety of bio-products.

Claims (1)

Invention Formula The installation for cryopreservation of bio-products containing for liquid cryoagent, connected to supply pipelines with chambers for bioproducts, chamber filling control unit, sensors of the upper and lower levels of the cryoagent installed in chambers and shut-off valves installed on pipelines, characterized in that, in order to increase the safety of bioproducts by maintaining a stable temperature regime in the chambers, the installation is equipped with a synchronizing unit, the input of which is connected with the output of the chamber filling control unit, with a steam collector in the form of a vertical vessel with sensors in it j 4961b the first and lower levels of the liquid cryogenic agent and the cryoagent vapor discharge valve, and the control unit of this valve associated with the level sensors in the steam collector and the chamber charge control unit, while the pipelines for supplying the liquid cryoagent to the chambers are connected to a common collector, one end of which is connected to the tank for the liquid cryoagent, and the other end to the lower part of the steam collector, sensors of the lower level of the cryoagent of all chambers are connected to the inputs of the block, control, and shut-off valves of all chambers are connected to the output of the block ka-synchronizer ten it