CS254601B1 - Cooling box control circuit with temperature signaling, especially box for storing blood cans and medicines - Google Patents

Abstract

The device increases operational reliability. Therefore, the connecting contact of the double switch is connected to the network in parallel with the disconnecting contact of the contactor of the refrigeration unit and the connecting contact of the defrost timer with the coil of the defrosting electrovalve, the connecting contact of the contactor is connected to the first lead of the compressor electric motor, connected to the first pole of the network via the connecting contact of the defrost timer, while the second lead is connected to the second pole, at the power source the first pole is connected via the second signaling bulb with the fixed contact part of the first position of the switching contact of the first relay /upper limit temperature/, via the third signaling bulb, the connecting contact of the second relay /lower limit temperature/ with the fixed contact part of the switching contact of the first relay, the fixed contact part of which is connected via the connecting contact of the second relay, the disconnecting contact of the first relay with the fixed contact part of the first position of the switching contact of the double switch and via the first signaling bulb with the movable contact part of the switching contact of the double switch and the second pole via the connecting contact of the relay /upper nominal temperature/ with the fixed contact part double switch, with the movable contact part of the switching contact of the first relay and via the disconnecting contact of the second relay with the fixed contact part of the first position of the switching contact of the first relay /upper limit temperature/.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a control cabinet circuit with temperature signaling, in particular a canister for storing blood and medicaments, comprising a refrigerant contactor and a temperature controller for controlling the output voltage of the high limit relay, high rated relay, low rated relay and low limit relay .

The defrosting hours of the cooling cabinet control the defrosting time and the defrosting frequency within 24 hours. Therefore, defrosting may occur just after the cooling cabinet has been put into operation at a time when the cooling cabinet has not yet been sufficiently cooled, thereby seriously damaging the cooling cabinet equipment and spoiling objects stored in the cooling cabinet, particularly blood cans. For this reason, the cooling cabinets are equipped with an automatic blocking of the defrost process. This blockage always occurs when the so-called upper limit temperature of the refrigerator compartment of the refrigerator cabinet, which is set by the operator on the controller, usually an electronic control unit, is exceeded.

The automatic unlocking, and thus the defrosting process of the evaporator icing, only occurs when the condition of the first cooling off of the cabinet cooling unit is fulfilled, i.e. when the lower nominal temperature in the cabinet cooling space is reached. However, the upper limit temperature is always exceeded even when the refrigerator cabinet door is opened for a short time. Due to the partial freezing of the evaporator, the switch-off temperature can no longer be reached, thereby blocking the automatic defrost and further freezing of the evaporator part of the refrigeration cabinet, which causes further warming of the refrigeration compartment of the cabinet. Frequent opening of the refrigerator cabinet door at higher ambient temperatures, especially in summer and at elevated ambient air humidity, also causes such blockage.

However, frequent opening of the refrigerator cabinet door is necessary, especially when storing blood cans, due to the mandatory regular inspection of the products stored in these cabinets. Of course, the air exchange in the cooling compartment of the cabinet also occurs during the actual handling of the stored contents of the cooling cabinet.

To restore the refrigeration box, the refrigeration box must be completely emptied, put out of operation and naturally defrosted to allow the evaporator to return to its original state under ambient temperature, which is time consuming. Therefore, it is necessary to transfer the contents of the cooling cabinet to another cooling cabinet or to ensure the transfer of chilled products, in particular blood cans, elsewhere to another blood bank.

These drawbacks are eliminated in the temperature control circuit of the refrigeration box according to the invention, which is based on the fact that in a double switch with a two-position changeover contact and a make contact, the make contact is connected in parallel to the open contact of the contactor. connected through the first signal lamp to the first pole of the power supply, the fixed contact portion of the first position of the changeover contact of the double switch is connected to the second pole of the power supply via a serial circuit consisting of the break contact of the high limit relay; the break contact of the lower limit temperature relay and the connection where the movable contact part and the fixed contact part of the first position of the two-position changeover contact lie in the case of the high limit relay, the junction and the break contact of the low limit relay, and the fixed contact portion of the first changeover contact position, the high limit relay is connected to the first pole of the power supply and the fixed contact portion of the second changeover contact position. the high limit relay is connected to the first pole of the power supply via a series contact formed by the low terminal relay contact and the third signal lamp, and the fixed contact portion of the second switch contact position of the double switch is connected to the second pole of the power source via nominal temperature.

The invention achieves automatic defrosting of the evaporator even if the condition of first reaching the lower nominal temperature after the upper limit temperature is not met, for example due to the exchange of stored articles, opening of the refrigerator cabinet door or excessive freezing of the refrigerant evaporator. The need for moving the movable contact part of the double switch is signaled by the first signal lamp by its lighting. Timely signaling and thus timely intervention by the operator allows automatic defrosting, which is still controlled by the time switch, thus keeping the temperature in the refrigerator compartment within the specified limits ´. When the set operating temperature in the cabinet cooling compartment has been reached - below the upper nominal temperature - the upper nominal temperature relay contact is connected, the changeover contact of the double switch and the upper nominal temperature relay contact is energized to the first signaling lamp, . By relocating the movable contact portion of the double switch changeover contact by the operator, the signaling system returns to the standby state.

Perfect and timely signaling of the temperature in the refrigerator compartment of the refrigerator cabinet prevents damage to the contents of the cabinets, in particular blood, blood products and the like, stored in these cabinets at inappropriate temperatures. At the same time, savings in electricity and transport costs are achieved, as well as economical operation of the refrigerator. The failure rate of the cooling unit is substantially reduced, since the cooling unit does not overheat and thus the electric motor burns out when the evaporator freezes excessively, when the control circuit stops shutting down and therefore the cooling unit operates continuously.

An advantage of the invention is also the fact that unprofessional intervention of the operator cannot cause a dangerous temperature fluctuation in the refrigerator cabinet and thus impair the contents of the refrigerator cabinet. The solution according to the invention is of great importance in the summer, when the ambient temperature is high, at higher ambient humidity, at high load of the refrigerator, for example by frequent opening of the door, excessive contents of the refrigerator or frequent replacement of the contents of the refrigerator.

It is not necessary to react immediately to the signals of the signal bulbs by moving the double switch, since all processes, including defrosting, are still fully automatic in both positions of the double switch and therefore moving the double switch to the second position after about three hours or during normal handling of the contents of the refrigerator.

An exemplary embodiment of a refrigeration box control circuit with state-of-the-art signaling circuits, which is very suitable for refrigerated boxes for storing blood cans and medicaments, is schematically shown in the drawings, in which Fig. 1 shows a practical embodiment and Fig.

The circuit according to the invention comprises a cooling unit contactor A and an electronic temperature controller for controlling the output voltage of the upper limit temperature relay, the upper rated temperature relay C, the lower rated temperature relay and the lower limit temperature relay E, the electric motor M of the refrigerating compressor a first inlet 16 and its second inlet 17 to the AC single-phase network.

In the first inlet 16 of the electric motor M of the refrigerant compressor, the connection contact 6 of the contactor A of the refrigerant compressor is connected and the connection contact 13 of the defrost clock O connected in parallel. The second inlet 17 of the electric motor M of the refrigeration compressor is connected directly to the AC. Between the two poles of the AC network, there is still a series circuit consisting of the NO contact 12 of the cooling unit contactor A, the NO contact 14 of the defrost clock O, and the solenoid valve S of the solenoid valve for supplying hot vapors to the evaporator for defrosting.

The switching contact 2 of the double switch T is connected in parallel to the opening contact 12 of the contactor A of the cooling unit, the movable contact portion 18 of the switching contact 2 of the double switch T is connected to the first pole 2 of the power source 11. In the embodiment described, this is a transformer whose primary winding is connected to an AC single-phase network. The fixed contact portion 20 of the changeover contact position 2 of the double switch T is then connected to the second pole 10 of the power supply 11 via the connection contact 5 of the upper nominal temperature relay C and the fixed contact portion 19 of the first position of the changeover contact 2 of the double switch T is the upper limit temperature break contact 2, the lower limit temperature relay E contact 2, and the parallel circuit formed by the lower limit temperature relay E contact 2 and the connection where the movable contact portion 21 and the fixed contact portion 22 of the first position of the two-position changeover contact 2 the upper limit temperature relay B is also connected to the second pole 10 of the power source 11.

The node of the contact contact 2 and the lower contact temperature contact 2 of the lower limit temperature E and the fixed contact portion 22 of the first position of the upper limit temperature change contact j of the upper limit temperature B are connected to the first pole 2 of the power source 11. The fixed contact portion 23 of the second switch contact position 2 of the upper limit temperature relay B is connected to the first pole 2 of the power source 11 via a serial circuit formed by the contact contact 15 of the low limit relay E and the third signal lamp 2, the fixed contact portion 20 of the second switch position. The contact 2 of the double switch T is connected to the rainbow pole 10 of the power supply 11 via the connection contact 2 of the relay C of the upper nominal temperature.

In the control circuit according to the invention, it is advantageous to use non-wired relay contacts used by some refrigeration cabinet manufacturers in the refrigeration cabinet control circuit designs.

The control circuit according to the invention operates as follows:

The movement of the relay provides the output voltage from the thermal electronic controller controlled by the thermal sensor in the refrigerator compartment of the refrigerator.

When the temperature in the cabinet cooling compartment drops below the lower rated temperature set on the controller, the lower nominal temperature relay coil no longer receives power.

When the temperature in the cabinet refrigerator compartment drops below the lower limit set on the controller, the coil of the lower limit relay E stops receiving current.

When the temperature in the cabinet cooling compartment rises above the upper set temperature set on the controller, the coil of the upper set temperature relay no longer receives current.

When the temperature in the cabinet refrigerator compartment rises above the upper limit set on the controller, the coil of relay B of the upper limit temperature stops receiving current.

Conversely, at the temperature in the cabinet cooling space lying within the set operating range, i.e. between the upper nominal temperature and the lower nominal temperature, the coil contactor coil A, the coil relay B of the upper limit temperature, and the coil of relay C of the upper nominal temperature receive voltage.

At normal operating temperatures in the refrigerator compartment, the contact 4 of the lower limit relay E is closed and current is applied to the open contact 2 of the upper limit temperature relay B, whose coil is also energized and therefore the open contact 2 of the upper limit temperature relay also disconnected. Thereby, no voltage is applied to the movable contact portion 18 of the changeover contact 2 of the double switch T, and therefore there is no voltage on the first signaling lamp X and it is not lit. The double switch T is in the position shown in the drawings. Since the connection contact 2 of the double switch T is open, the open contact 12 of the cooling unit contactor A is not short-circuited. Therefore, the refrigerator cabinet operates in normal mode.

When the upper limit temperature is exceeded, the upper limit temperature relay coil no longer receives voltage, thereby opening contact 3 of the upper limit temperature relay B and, via the fixed contact portion 19 of the first position and the movable contact portion 18 of the changeover contact 2 of the double switch T bulb X and therefore it shines.

At the same time, the movable part 21 and the fixed part 22 of the first position of the changeover contact 8 of the upper limit temperature relay B are connected and therefore the second signaling lamp Y receives voltage and also illuminates, i.e. indicates that the cooling chamber temperature is outside the set temperature range.

The operator switches the double switch T at the earliest inspection. This switches the changeover contact 2 and the switch contact 2 of the double switch T and the first signal lamp X goes out, since it does not receive any current through the switch contact 2 of the upper nominal temperature relay. The contact 5 of the upper nominal temperature relay C has already been opened when the upper nominal temperature has been exceeded. However, the second signaling lamp Y remains lit and continues to indicate an inappropriate temperature. Temperature outside the set cabinet range required by the operator.

At the same time, the double switch T connects its connection contact 2, which bridges the break contact 12 of the cooling unit contactor A and from there flows current via the contact 14 of the defrost clock 0 to the solenoid valve coil 2 to supply the hot vapor to the defrost evaporator. evaporator cooling cabinet. The defrosting proceeds fully automatically according to the time set on the defrosting clock O in terms of duration and frequency, even if the defrost was initially blocked.

After the operating temperature of the refrigerator cabinet has been reached again - below the upper rated temperature set on the controller - the connection 2 of the upper rated temperature relay C is connected, bringing the current through the changeover contact of the double switch T into the first signal lamp X lights up again. The first signaling lamp X indicates that the desired function has been achieved, i.e. the operating temperature of the cabinet has been reached again. On the occasion of further inspection, the refrigerator operator returns the double switch T to the original position, thereby moving the movable contact portion 18 of the changeover contact 2 of the double switch T to the first position and attaching the first signal lamp X to the break contact 2 of the upper limit temperature relay. However, the break contact 2 of the upper limit temperature relay B is already open, as the upper limit temperature relay coil B is energized again. Therefore, the first signal lamp X is not energized and does not light.

At the same time, the changeover contact 2 of the upper limit temperature relay B is moved to the second position and therefore the second signaling lamp Y goes out and current is applied to the connection contact 21 of the lower limit temperature relay E which is connected. therefore, the third signal lamp Z is energized and illuminates. The third signal lamp Z indicates the correct temperature in the cabinet cooling compartment required by the set temperature controller.

By switching the double switch T to the original position, the connection contact 2 of the double switch T is simultaneously disconnected and the cooling cabinet continues to operate according to the original program.

If, for some reason, the temperature in the cabinet cooling compartment drops below the lower limit temperature set on the temperature controller, the connection contact 15 of the lower limit temperature relay E opens. This removes the voltage of the third signaling lamp Z, which therefore goes out. At the same time, the break contact 7 of the lower limit temperature relay E is closed, by which the voltage is applied to the second signaling lamp Y, which therefore lights up. This again signals an inadequate temperature in the refrigerator compartment, but the break contact 2 of relay B of the upper limit temperature is open because the upper limit temperature has not been exceeded but the lower limit temperature has been exceeded and the X signal light bulb is not illuminated.

This prevents signaling and switching of the double switch T and thus the changeover contact 2 ^{and the} connection contact 2 of the double switch T when the temperature in the cabinet cooling room is too low and therefore it is unnecessary to achieve a defrosting cycle. A case without strong icing and defrosting is not desirable.

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The invention is applicable to all refrigeration cabinets of this kind, but is highly suitable for refrigeration cabinets for storing blood cans, as it increases the operational safety and reliability of the refrigerator and thus completely eliminates the spoilage of blood cans, blood products and medicaments usually found in these types. refrigerated cabinets kept. However, the invention can also be used wherever more precise temperature control is required in the cabinet refrigeration space or where the temperature of stored products requiring a certain constant temperature must be uncompromisingly guarded.

Early signaling and hence defrost control of any type of refrigeration device reduces power consumption, as the heat transfer from the evaporator to the refrigeration compartment is perfectly utilized. Insufficient defrosting of the evaporator part of the refrigeration device leads to a considerable prolongation of the running time of the refrigerating machine or its continuous operation, and thus an increase of the electric energy consumption, because the set temperatures in the refrigeration space of the plant cannot be reached. The use of hermetic motor compressors in refrigeration equipment will greatly reduce the failure rate of these condensing units, since cold vapors of refrigerant returning from the evaporator to the motor compressors usually cool the motor compressor windings.

If the evaporator is too freezing, this winding of the motor-compressors does not cool and at the same time the winding of the motor-compressors increases due to the excessively long running of the condenser unit and eventually its burning.

A further advantage of the refrigeration box control circuit according to the invention is that even unprofessional intervention by the operator cannot cause a dangerous fluctuation in the temperature of the refrigeration compartment, since the entire cycle, including defrosting, is completely automatic, independent of the operator.

SUBJECT OF THE INVENTION

Claims (1)

SUBJECT OF THE INVENTION Temperature control cabinet control circuit, in particular cans for storing blood and medicaments, comprising a cooling unit contactor and a temperature controller for controlling the output voltage of the upper limit relay, the upper rated temperature relay, the lower rated temperature relay and the lower limit temperature relay the first connection of the refrigerant compressor electric motor connected to the power supply of the connected electric motor is the connection contact of the cooling unit contactor and the connecting contact of the defrost clock is connected in parallel and there is a serial circuit solenoid valve coil for supplying hot vapor to the evaporator for defrosting, characterized in that for a double switch (T) with a two-position changeover contact (1) and a connection the switching contact (2) is connected in parallel to the break contact (12) of the contactor (A) of the cooling unit, the movable part (18) of the changeover contact (1) of the double switch (T) is connected via the first signaling lamp (X) to the first pole (9) of the power source (11), the fixed contact portion (19) of the first switch contact position (1) of the double switch (T) is connected to the second pole (10) of the power source (11) via a serial circuit formed contact / 3 / relay / B / upper limit temperature, connection contact / 4 / relay / E / lower limit temperature and parallel circuit consisting of normally open contact / 7 / relay / E / lower limit temperature and connection with movable contact part / 21) and the fixed contact part (22) of the first position of the on / off changeover contact (8) of the relay (B) of the upper limit temperature, the contact contact node (4) and the break contact (7) of the relay (E) temperature limit and fixed contact portion (22) of the first changeover contact position (8) of the relay (B) the upper limit temperature is connected via a second signal lamp (Y) to the first pole (9) of the power supply (11) and fixed contact portion (23) the second position of the changeover contact (8) of the relay (B) of the upper limit temperature is connected to the first pole (9) of the source (11) via a serial circuit formed by the contact contact (15) of the relay of the lower limit temperature and the third signaling lamp (2). The fixed contact portion (20) of the second switch contact position (1) of the double switch (T) is connected to the second pole (10) of the power source (11) via the connection contact (5) of the relay (C) of the upper rated temperature.