KR0113230Y1 - Defrosting and refrigeration control circuit of showcase - Google Patents

Abstract

The present invention relates to a showcase defrosting / freezing operation control circuit, and in the related art, when the defrosting operation is started, the defrosting return thermostat is turned on / off according to the high temperature so that the inside temperature of the high temperature becomes unstable because the rising / falling of the high temperature is repeated. There was a problem that does not properly maintain the freshness of frozen foods.

In order to improve this problem, the present invention performs defrost return refrigeration operation when the internal temperature rises above the set value during the defrosting operation and defrost operation is performed again when the internal temperature drops below the set value by performing the defrost recovery refrigeration operation. It is designed to maintain at an appropriate temperature, the present invention can maintain the internal temperature at a proper temperature by performing a defrost return refrigeration operation if the defrost operation is performed and the internal temperature rises above the set temperature can maintain the freshness of the frozen food .

Description

Showcase defrost / freeze operation control circuit

1 is a conventional showcase defrost / frozen operation control circuit diagram.

FIG. 2 is a timing diagram of each part in FIG.

3 is a defrost / freezing operation control circuit diagram of the present invention showcase.

4 is a timing diagram of each part in FIG.

FIG. 5 is a signal flow diagram for controlling defrost / freezing operation in FIG.

* Explanation of symbols for main parts of the drawings

DEF-T: Defrost Timer DPS: High Low Voltage Circuit Breaker

MC1: Compressor Relay MC2: Condenser Relay

RH1: Relay for defrost heater TC1: Thermostat thermostat

DTH: Defrost Return Thermo SV: Solenoid Valve

X1: auxiliary relay NFB: breaker

The present invention relates to a refrigerator control applied to refrigeration and freezing showcases. In particular, by detecting the internal temperature in the defrosting operation, when the temperature rises above the proper temperature, the defrosting heater is shut off, and then the refrigeration operation is performed to adjust the internal temperature to the proper temperature. The present invention relates to a showcase defrosting / freezing operation control circuit for maintaining and maintaining food freshness at maximum.

1 is a defrost / freezing operation control circuit diagram of a conventional showcase, and as shown therein, a three-phase power supply RST is passed through a breaker NFB to a compressor relay contact MC1a and a condenser relay contact MC2a. The three-phase power supply (RST) is connected to the heater relay contact (RH1a) through the common contact and the relay contact (MC1a) (MC12a) through the compressor overcurrent relay (TN1) and the condenser overcurrent relay (TH2), respectively. After connecting the heater relay contact (RH1a) to the defrost heater (DH1) through each of the overheat prevention thermostats (O1), the single-phase power source (RT) is sequentially passed through the fuses (F1, F2) and the operation switch (S1). The power supply T is connected to a high / low voltage circuit breaker (DPS) through a compressor overcurrent relay contact (TH1c) and a condenser overcurrent relay contact (TH2c) in sequence, and then a high voltage break contact (HP) of the high / low voltage breaker (DPS). ) To the defrost timer (DEF-T) and at the same time the high / low voltage breaker (DPS) ), The voltage through the high and low voltage breaking contact point HP (SP) is sequentially connected to the compressor switch MC1, the condenser switch MC2, and the operation lamp L1, and the relay contact TH1c (TH2c). The other side of the over-voltage blocking contact HP is connected to the abnormal lamp L2 in common, and the temperature control thermostat is applied to the refrigeration selection terminal of the defrost timer DEF-T to which the output of the high / low voltage breaker DPS is applied. After connecting to TC), the solenoid valve SV is connected to the temperature control thermostat TC, and the defrost selection terminal of the defrost timer DEF-T is connected to the defrost lamp L3 through the compressor relay contact MC1b. The defrosting return thermostat DTH and the heater relay RH1 are connected in series and connected to the defrost lamp L3 in parallel.

The operation of the conventional circuit will be described with reference to the timing diagram of FIG.

When the breaker NFB or the fuses F1 and F2 are turned off even when the three-phase power supply RST is supplied, the power supply is stopped. When the breaker NFB and the fuses F1 and F2 are turned on, the operation switch ( When S1) is off, the operation of the refrigerator is stopped and when the operation switch S1 is on, the overcurrent relay TH1 for the compressor and the condenser TH1 or the high pressure cut-off contact HP are tripped. When it is turned on, the abnormal state is displayed and the refrigerator is stopped.

At this time, after the three-phase power supply (RS T) is supplied, the overcurrent relay contact (TH1c) for the overload protection device, the overcurrent relay contact (TH2c) for the condenser, and the high voltage blocking contact (HP) of the high / low voltage breaker (DPS) When the defrost timer DEF-T is in operation and the freezing operation time is reached, the contact point C is connected to the freezing operation terminal.

Accordingly, when the temperature control thermostat TC is turned on, the refrigerant supply / blocking solenoid valve SV is turned on, and the refrigerant supply / blocking solenoid valve SV is turned on to turn on the high / low pressure circuit breaker. When the low pressure blocking contact LP is turned on, the compressor relay MC1, the condenser relay MC2, and the operation lamp L1 are turned on.

Accordingly, the compressor relay contact MC1a and the condenser relay contact MC2a to which the three-phase power supply RST is applied are turned on through the breaker NFB, so that the compressor motor CM and the fan motor FM for the condenser are turned on. Will start freezing operation.

In addition, since refrigeration operation is performed by setting the proper internal temperature, when the internal temperature falls below the set value of the temperature control thermostat TC, the temperature control thermostat TC is turned off, so that the solenoid valve SV is turned off and the low pressure shutoff contact The LP is turned off and the compressor relay MC1 and the condenser relay MC2 are turned off by turning off the low pressure cutoff contact LP, so the compressor motor CM and the condenser fan motor FM are turned off. Freezing operation is stopped.

At this time, after the refrigeration operation is stopped, if the internal temperature of the refrigerator rises above the set value of the temperature control thermostat TC, the temperature control thermostat TC is turned on to restart the freezing operation.

Therefore, when the refrigeration operation is started, the operation of the compressor motor CM and the condenser fan motor FM is turned on / off by turning on / off the temperature control thermo TC.

On the other hand, when the defrost time is reached according to the operation of the defrost timer DEF-T, the contact point C is connected to the defrosting operation terminal, so the solenoid valve SV for refrigerant supply / blocking is turned off and the low pressure shutoff contact LP is turned off. Since the compressor relay MC1 and the condenser relay MC2 are turned off, the compressor motor CM and the condenser fan motor FM are turned off to stop the freezing operation.

At this time, since the relay contact MC1b is turned on by the compressor relay MC1 being turned off, the defrost lamp L3 is turned on and the defrost return sensor DTH is turned on by the internal temperature of the heater relay RH1. Since the relay contact RH1a is turned on and the power source RST is applied to the defrosting heater DH1, the defrosting operation is started by heating the inside of the refrigerator.

Accordingly, when the defrosting operation is continuously performed and the temperature inside the high rises above the set value of the defrosting return thermostat DTH, the defrosting return sensor DTH is turned off so that the heater relay RH1 is turned off and thus the defrosting heater DH1. Since the defrosting operation is stopped by turning off, the internal temperature of the refrigerator is lowered.

In addition, when the defrosting operation is stopped and the temperature inside the refrigerator is lower than the set value, the defrosting return thermostat DTH is turned on so that the heater relay RH1 is turned on so that the heater DH1 is operated again.

Accordingly, when the defrosting operation is continuously performed and the temperature inside the high rises above the set value of the defrosting return thermostat DTH, the defrosting return sensor DTH is turned off so that the heater relay RH1 is turned off and thus the defrosting heater DH1. Since the defrosting operation is stopped to turn off, the internal temperature of the refrigerator is lowered.

In addition, when the defrosting operation is stopped and the temperature inside the refrigerator is lower than the set value, the defrosting return thermostat DTH is turned on so that the heater relay RH1 is turned on so that the heater DH1 is operated again.

That is, when the defrosting operation is performed, the heater DH1 is turned on / off by turning on / off the defrost return sensor DTH according to the inside temperature of the refrigerator to adjust the inside temperature of the refrigerator.

When the defrost time ends, the terminal C of the defrost timer DEF-T is connected to the freezing operation terminal, so the freezing operation is restarted.

When the defrost time ends, the terminal C of the defrost timer DEF-T is connected to the freezing operation terminal, so the freezing operation is restarted.

The above operation is performed as in the timing of FIG.

However, in the related art, the defrosting return thermostat is turned on / off according to the high temperature in the defrosting operation, and thus the inside temperature of the high temperature becomes unstable due to repeated increase / fall of the high temperature. Therefore, the freshness of the frozen food may not be properly maintained.

The present invention performs a defrosting operation when the internal temperature rises above the set value when the defrosting operation is started in order to improve the conventional problems as described above, and performs the defrosting operation by performing the defrost return refrigeration operation. Thus, the defrost / freezing operation control circuit of the showcase was designed to maintain the high temperature inside.

This will be described in detail with reference to the accompanying drawings.

3 is a defrost / freezing operation control circuit diagram of the present invention showcase, after the three-phase power supply (RST) through the breaker (NFB) to the compressor relay contact (MC1a) and condenser relay contact (MC2a) Common connection is made to connect the relay contacts MC1s MC2a to the compressor CM and the condenser FM through the compressor relay TH1 and the condenser relay TH2, respectively, and simultaneously through the breaker MFB. After connecting the three-phase power supply (RST) to the defrosting heater (DH1) via the relay contact (RH1a) for the defrost heater, the single-phase power (RT) through the fuse (F1, F2) and the operation switch (S1) in sequence The power supply T is connected to the high / low voltage circuit breaker (DPS) through a compressor over-current relay contact (TH1c) and a condenser over-current relay contact (TH2c) in sequence, and the high-voltage breaker contact (HP) of the high / low voltage breaker (DPS) is connected. ) Is connected to the DEF-T and auxiliary relay contact (X12a) and The common voltage to the compressor switch MC1, the condenser switch MC2, and the operation lamp L1 in order to connect the voltage through the high voltage / low voltage break contact HP / LP of the low voltage circuit breaker DPS. The temperature at which the other side of TH1c) TH2c and the high voltage interrupting contact HP are commonly connected to the abnormal lamp L2, and the refrigeration selection terminal of the defrost timer DEF-T and the auxiliary relay contact X12a are commonly connected. The adjustment thermostat TC1 is connected to the solenoid valve SV, the defrost selection terminal of the defrost timer DEF-T is connected to the switch contact MC1b, and the switch contact MC1a is connected to the auxiliary relay contact X1b. It is connected to the defrost heater relay RH1 sequentially and connected to the defrost lamp L3, and at the same time, the defrost selection terminal is connected to the auxiliary relay X1 through the defrost return thermostat DTH and the auxiliary relay contact X11a, respectively. To configure.

Reference numerals O1 and O2 in the drawings are thermal protection thermostats connected between the defrost heater relay contact RH1a and the defrost heater DH1.

Referring to the operation and effect of the present invention configured in this way in detail as follows.

If the breaker (NFB) or fuses (F1, F2) are off when the three-phase power (RST) is being supplied, the operation switch is stopped when the power supply is stopped and the breakers (NFB) and the fuses (F1, F2) are on. If (S1) is off, the operation of the refrigerator is stopped, and if the overcurrent relay (TH1) (TH2) or the high-voltage blocking contact (HP) is tripped when the operation switch (S1) is on, the abnormal lamp (L2) is stopped. Is turned on to indicate an abnormal condition.

At this time, after the three-phase power supply (RST) is supplied, the overcurrent relay contact (TH1c) for the overload protection device, the overcurrent relay contact (TH2c) for the condenser, and the high voltage blocking contact (HP) of the high / low voltage breaker (DPS) are normal. When the defrost timer DEF-T operates during the freezing operation time, the contact point C is connected to the freezing operation terminal to operate the solenoid valve SV through the temperature control thermostat TC1.

Accordingly, the solenoid valve (SV) for supplying / closing the refrigerant from the condenser to the evaporator is operated so that the low pressure blocking contact LP of the high / low pressure circuit breaker (DPS) is turned on by the high pressure, so that the compressor relay (MC1), The condenser relay MC2 and the operation lamp L1 are turned on.

Accordingly, the compressor relay contact MC1a and the condenser relay contact MC2a to which the three-phase power supply RST is applied are turned on through the breaker NFB, so the compressor motor CM and the fan motor FM for the condenser are turned on. Since the operation of the cold air is supplied to the inside of the refrigeration operation starts.

In addition, if the internal temperature of the high temperature falls below the set value of the temperature control thermostat TC1 during the refrigeration operation, the temperature of the temperature control thermostat TC1 is turned off and the solenoid valve SV is turned off, thereby reducing the refrigerant pressure supplied from the condenser to the evaporator. When the low pressure blocking contact LP is turned off due to the decrease in the refrigerant pressure, the compressor relay MC1, the condenser relay MC2, and the operation lamp L1 are turned off, so that the compressor motor CM and the fan motor condenser are turned off. Since the FM) is turned off, the freezing operation is stopped.

At this time, if the temperature inside the high rises above the set value of the temperature control thermostat TC1 after the refrigeration operation is stopped, the temperature control thermostat TC1 is turned on and the low pressure cutoff contact LP is turned on. Since the fan motor FM for the condenser operates, refrigeration operation is restarted by supplying cold air into the refrigerator.

Therefore, when the refrigeration operation is started, the operation of the compressor motor (Tsu) and the condenser fan motor (FM) is turned on and off by turning on / off the temperature control thermostat TC1 according to the internal temperature of the refrigerator to perform the intermittent operation.

On the other hand, when the defrost set time is reached by the operation of the defrost timer DEF-T, the contact point C is connected to the defrosting operation terminal, and thus the refrigerant supply / blocking solenoid valve SV is turned off to supply the refrigerant supplied from the condenser to the evaporator. Since the pressure is lowered and the low pressure blocking contact LP is turned off due to the pressure drop of the refrigerant, the compressor relay MC1 and the condenser relay MC2 are turned off, and thus the freezing operation is stopped.

Then, the defrost heater relay RH1 to which power is applied is sequentially turned on through the switch contact MC1a and the auxiliary relay contact X1b, and the relay contact RH1a is turned on, and the power is supplied through the relay contact RH1a. The interior of the refrigerator is heated by the applied heater DH1 to start the defrosting operation.

At this time, when the temperature inside the refrigerator rises above the set value of the defrosting return thermostat DTH by performing the defrosting operation, the defrosting return thermostat DTH turns on and power is applied to the auxiliary relay X1 so that the relay contact X1b is turned off. At the same time, since the relay contact X1a is turned on and the relay contact X1b is turned off, and the defrost heater relay RH1 is turned off, the defrosting operation is stopped.

Accordingly, when the temperature control thermostat TC1 supplied with power through the relay contact X1a rises above the set value and the temperature control thermostat TC1 turns on, the solenoid valve SV turns on and the condenser When the refrigerant is supplied to the compressor, the low pressure blocking contact LP of the high / low pressure circuit breaker (DPS) is turned on, and when the compressor relay MC1 and the condenser relay MC2 are turned on, the compressor motor CM and the condenser are turned on. Since the fan motor FM operates, cold air is supplied into the refrigerator to start the defrost return refrigeration operation.

When the internal temperature falls below the set value of the temperature control thermostat TC1, the temperature control thermostat TC1 is turned off and the solenoid valve SV is turned off, so that the refrigerant pressure becomes low and the low pressure shutoff valve LP is turned off. Lose.

Accordingly, the switch MC1 (MC2) is turned off by the low pressure shut-off valve LP turned off, and the defrosting return refrigeration operation is stopped because the switch condenser contact MC1a and the compressor switch contact MC2a are turned off.

That is, even during the defrosting operation, the contactor contacts MC1a and MC2a are turned on by the defrosting return thermostat DTH regardless of the defrosting timer DEF-T. Thus, the compressor motor CM and the fan motor for the condenser are turned on. The defrost return refrigeration operation is performed by operating (FM).

When the defrost time ends by the operation of the timer DEF-T, the refrigeration operation is started again.

The above operation is performed in accordance with the timing diagram of FIG. 4 and the operation is performed in accordance with the signal flowchart of FIG.

As described in detail above, the present invention has the effect of maintaining the freshness of the frozen foods by maintaining the temperature in the high temperature by performing the defrost return freezing operation when the temperature inside the high temperature is set higher than the set temperature.

Claims (1)

A defrost timer for selecting a freezing operation or a defrosting operation according to the set time, a temperature control thermostat TC1 for supplying or cutting off power to the solenoid valve SV according to the set temperature if the freezing operation is selected by the defrosting timer, When the defrosting operation is selected by the defrosting timer, the defrosting heater relay RH1 supplies power to the defrosting heater DH1, and when the defrosting operation is selected by the defrosting timer and the internal temperature reaches the defrosting return temperature, the defrosting operation is performed. When the defrost return thermostat (DTH) and the defrost return thermostat (DTH) is turned on, the power supplied to the defrost heater relay (RH1) for the defrost return refrigeration operation is cut off and at the same time the temperature regulating thermostat (TC1). A defrost / freezing operation control circuit of a showcase, comprising: an auxiliary relay (X1) for continuously supplying power to the apparatus.