KR20120117704A - Refrigeration refrigerator for power outage - Google Patents

Abstract

PURPOSE: A refrigerator ready for blackout is provided to maintain the normal operation of the refrigerant regardless of blackout. CONSTITUTION: A refrigerator ready for blackout comprises a cold accumulation unit, a relay(1), and a relay switch(2). The cold accumulation unit is installed in a freezing chamber. The relay is connected to the power input terminal of the refrigerator. The relay switch is interacted with the relay comprising alternative contact points. The fan(3) in the freezing chamber is connected a chargeable battery(4) by the conversion of the relay switch. The electric power is controlled based on a temperature switch(8) in a cooling chamber. [Reference numerals] (AA) Power

Description

Refrigeration refrigerator against power outages

The present invention relates to a refrigeration refrigerator capable of preparing for a power failure that can prevent food in the refrigerator from spoiling for a predetermined time even during a power failure.

In countries with poor power conditions, sudden power outages often occur. If such a power outage lasts for a long time, the food in the refrigerator may be damaged. Especially in Southeast Asia, where the weather is hot, and in economically poor areas, power failures frequently occur due to lack of industrial infrastructure, causing food in the refrigerator to go bad.

As a conventional countermeasure proposed as a method to prepare for such a power failure, in the case of an unexpected power failure, the user removes the storage means stored in the freezer compartment and moves it directly to the refrigerating compartment. A method of maintaining the temperature for a little longer is proposed in Korean Patent Registration No. 0261982.

However, this method was inconvenient for the user to move the cold storage means in the freezer compartment to the refrigerating compartment. If the user was not at home, the power outage could not be dealt with at all, and even when the power failure occurred during bedtime, the cold storage means could not be moved from the freezer to the refrigerating compartment, resulting in a problem of food in the refrigerating compartment.

Another prior art proposed to solve the problems of the prior art as described above was the patent number 2012-0084857. This prior art has proposed to induce cold air stored in the refrigerating means of the freezer compartment to the refrigerating compartment by using a thermo siphon at the time of power failure. In Patent Publication No. 2012-0084857, in order to prevent cold air from the freezing chamber from flowing into the refrigerating chamber even during normal operation, not by power failure, a thermosiphon containing a material that changes phase at -20? -30 and freezes into a solid is used. It was made up. However, in the Patent Publication No. 2012-0084857, in order to prevent the thermosiphon from operating during power failure and the thermosiphon during normal operation, the thermosiphon is formed using a material that changes from -20 to -30 and freezes into a solid. However, there was a problem in the realization because it was not able to specify in detail what kind of material was changed into a solid at -20? -30 for actual realization.

In addition, although the thermo siphon has to move the cold air of the freezer compartment to the refrigerating compartment quickly, when the flow liquid in the thermo siphon is frozen, they do not function as a thermo siphon until all of them are completely dissolved. There was a problem that the temperature of the refrigerating chamber rises sharply at the beginning of the blackout. In particular, the door of the freezer compartment does not open and close frequently, so it takes a long time for the material in the frozen thermo siphon to melt. During this long time, the door of the refrigerator compartment frequently opens and closes, so that the temperature of the refrigerator compartment is constant after the blackout despite the presence of the thermo siphon. There was a problem of sharp rise during time. In order to solve this problem, if a thermo siphon having a liquid which does not freeze is formed, the cold storage of the refrigerating means in the freezer is continuously introduced into the refrigerating compartment even during normal operation, not a power failure. Occurs.

In addition, the technique proposed in the Patent Publication No. 2012-0084857 also has a problem that the thermosiphon does not easily open in actual operation. Because, when the conventional conventional refrigerator freezer is operated, the freezer compartment and the freezer compartment respectively decrease the temperature and the compressor stops when the set temperature is reached. However, in the above technique, the cold air of the freezer compartment is continuously thermostated by a thermosiphon installed in the freezer compartment and the refrigerator compartment. It is moved by the siphon to the fridge. If the performance of the thermo siphon is excellent, the flow liquid in the thermo siphon does not freeze because the liquid in the thermo siphon continuously absorbs heat from the refrigerating chamber and moves to the freezer side. If the fluid in the thermosiphon does not freeze at -20? -30 degrees, the cold air of the freezer compartment is continuously delivered to the refrigerating chamber, causing the fridge to overcool.

Of course, if you freeze the freezer at a rate faster than the thermosiphon's heat transfer rate, one day the liquid in the thermosiphon may eventually freeze, but this too may cause too much cold air to move into the fridge until it freezes, causing the fridge to overcool. There was this. Especially in refrigerators that defrost the evaporator defrost with a defrost heater at regular time intervals with a defrost timer, the thermosiphon frozen at the freezing temperature of the prior art is kept at a very slow rate because the thermosiphon continues to operate until it freezes. It takes a long time for the internal fluid to freeze, so after a long period of time, if the fluid that has only been cooled down takes a defrost time to begin, the temperature rises again, and in some cases it becomes a thermosiphon that does not freeze forever. do. In this case, as described above, the refrigerating compartment is over refrigerated.

As another conventional technique, a technique for installing cold storage means in a freezer compartment and moving cold air to a required place in a refrigerator by using a summer siphon has been proposed in Utility Model Publication No. 1992-0000790. However, this technology is configured to use the late-night power, there was a disadvantage that can not perform any function in case of power failure.

Even if a power failure occurs unexpectedly, the freezer compartment and the refrigerating compartment are continuously cooled for a predetermined time after the power failure by using cold air that is normally stored.

The storage unit is installed in the freezer compartment, and the battery is charged during non-electrostatic operation (normal operation), and the relay switch is connected to the refrigerator power input terminal. The fan is configured to be connected to operate the fan of the freezer compartment for a predetermined time by the power of the battery to supply the cold air of the cold storage means to the freezer compartment and the refrigerating compartment.

Even during a power outage, the cold air may be supplied to the refrigerating compartment and the freezing compartment for a predetermined time, thereby preventing food from being damaged during the power failure.

[Configuration]

Example 1.

The configuration of the first embodiment is as follows.

The charging circuit 5 and the storage battery 4 are configured, and the storage unit 11 is provided in the freezer compartment, and a relay 1 for interlocking the relay switch 2 is installed at the power input terminal of the freezer. In case of power failure, the circuit is moved to the power source energy side of the storage battery 4 in which the freezer compartment fan 3 is charged by the charging circuit 5 by the relay switch 2 that is switched in conjunction with the operation of the relay 1 according to the power failure. If the freezer compartment fan 3 is for AC, it is connected to the DC / AC converter to convert the output terminal voltage of the battery 4 to AC, the power of the battery 4 in case of power failure The freezer compartment fan 3 is operated while being controlled by the refrigerating compartment temperature switch 20 so that the cold air of the heat storage means 11 is continuously supplied to the freezer compartment and the refrigerating compartment for a predetermined time, even after a power failure, to perform a cooling action. .

In the above configuration,

The storage energy of the battery 4 (or the DC / AC converter output terminal power) may also be controlled by another relay switch 2 'connected in series with the refrigerating compartment temperature switch 20 as shown in FIG. 3. . In this case, when the user opens the refrigerating compartment door for a long time during the normal operation without power failure or when suddenly a large amount of new food is added to the refrigerating compartment and the temperature of the refrigerating compartment temporarily increases, the refrigerating compartment temperature switch 20 On (ON) has the advantage that the power source of the battery 4 is connected to the DC / AC converter 6 to prevent unnecessary power consumption.

The relay switch 2 and another relay switch 2 ′ are configured together with the relay 1 to operate in conjunction with the operation of the relay 1. The characteristic of this circuit configuration is that the power supply of the battery 4 cannot be connected to the DC / AC converter 6 even when the temperature of the refrigerating chamber is increased by a sudden situation during normal operation. This is because the power supply of the storage battery 4 is always cut off by the relay switch 2 'during normal operation in an uninterrupted state as shown in FIG.

The refrigerator compartment temperature switch 20 is preferably set to a temperature slightly higher than the refrigerator compartment temperature in normal operation (eg, about 8 degrees to 10 degrees). This is because the power failure is an emergency situation, so that the refrigerating chamber 13 is kept at the refrigerating temperature for as long as possible only by the cold air of the heat storage means 11. However, if the capacity of the heat storage means 11 is sufficiently large, the set temperature of the refrigerating compartment temperature switch 20 may be set to the temperature of the refrigerating compartment 13 as usual.

The cold storage means 11 used in the configuration of the present invention is preferably composed of a coolant made of a material causing a phase conversion from liquid to solid at the temperature of the freezing chamber 12. This is because a large amount of heat is released during phase change and a large amount of heat can be absorbed while phase change while melting during power outage, so that a small amount of coolant can be stored even with a small volume of coolant.

Example 2.

The structure of this Example 2 is as follows.

The second embodiment is configured as shown in FIG. That is, the method of circulating cold air from the freezing chamber 12 to the refrigerating chamber 13 at the time of power failure has an air circulation structure of the intercooled refrigerator, and for this purpose, the freezer compartment is provided with a freezing chamber fan 3 which is not necessary in the normal direct cooling freezer. In the normal operation supplied normally, it is cooled by a conventional direct cooling evaporator installed in the freezer compartment and the refrigerating compartment, and in the case of power failure, the cold air of the accumulator means is exchanged with the freezer compartment fan 3 to circulate in an intercooled manner.

Of course, the heat storage means of the present invention described above can be installed at any position in the freezer compartment.

In the above-described configuration of the first and second embodiments of the present invention, a large amount of frozen foods that are already frozen in the freezing chamber by normal operation without separately installing the cold storage means 11 installed in the freezing chamber are provided. It can also be used instead as a means for the storage. The configuration for this case is FIG.

[Action]

[Operation of Example 1]

1 and 2 or 3, during normal operation in which power is normally supplied, the compressor 9 is operated by a conventional freezer refrigerator circuit to compress and liquefy refrigerant to be liquefied in the evaporator 10. The refrigerant is evaporated while the refrigerant is evaporated by heat exchange of the cold air of the evaporator 10 to the freezer compartment and the refrigerating compartment. And the cooling of the freezer compartment and the refrigerating compartment while repeating the compression and evaporation of the refrigerant while removing the defrost formed in the evaporator 10 by the defrost action composed of the defrost timer 16, the defrost heater 17, the bimetal 18 every predetermined time. Continue to work. The temperature of the freezer compartment controls the freezer compartment fan 3 and the compressor 9 on and off by the freezer compartment temperature switch 8, and the damper 7 controls the flow of cold air introduced through the doctor 19 in the refrigerating compartment 13. Maintain the fridge temperature at the set temperature while controlling. As such, the refrigerator refrigerator in normal operation has a problem in that the food is damaged because there is no countermeasure in the conventional refrigerator refrigerator at the time of sudden power failure, but in the present invention, the refrigerator can be supplied to the refrigerator compartment and the freezer for a predetermined time even during a power failure. It is possible to prevent food from spoiling. When described in detail with the accompanying drawings the operation of the present invention as follows.

The battery 4 is charged by the charging circuit 5 during the normal operation of the refrigerator freezer of the present invention in an uninterrupted state. In addition, the relay 1 of FIG. 2 is supplied with power to suck the working iron pieces (not shown) inside the relay 1, and thus the relay switch 2 interlocked with the relay 1 is shown in FIG. Is connected to the a contact of. Accordingly, the freezer refrigerator of the present invention operates normally while the compressor 9 and the freezer compartment fan 3 are controlled on and off by the freezer compartment temperature switch 8 like the conventional freezer. During this normal operation, the storage battery 4 connected to the charging circuit 5 is sufficiently charged, and the storage cooling means 11 provided in the freezing chamber 12 sufficiently stores cold air while causing phase change. Storing cold air while phase shifting from liquid to solid state means that the refrigerating means 11 releases a lot of heat to the outside as the phase changes from liquid to solid, and thus reverses phase change (solid to liquid during power outages). This means that it absorbs a lot of heat from the surroundings and consequently cools the surroundings of the heat storage means 11.

When a sudden power failure occurs during such normal operation, power is not supplied to the relay 1, and thus, an operating iron piece (not shown) inside the relay 1 is released in a suction state, thereby In the relay switch 2 of FIG. 2, the contact point is switched to the b side, and the freezer compartment fan 3 is connected to the output side of the DC / AC converter 6 in which the battery power is converted. As a result, the compressor 9 is in a stopped state, but the freezer compartment fan 3 continues to operate due to the power of the uncharged battery 4. The freezer compartment fan 3 is controlled on and off by the refrigerating compartment temperature switch 20 of FIGS. 2 and 3. Accordingly, the freezer compartment fan 3 is operated by the force of the battery 4 while the power failure is generated, and the cold air stored in the cold storage means 11 in the freezer compartment 12 is sent to the freezer compartment 12 and the refrigerating compartment 13 side. It becomes. Accordingly, the refrigerating chamber temperature maintains the refrigerating temperature for a predetermined time even during a power failure until the cold air of the heat storage means is exhausted. Likewise, the temperature of the freezer compartment 12 is further maintained for a predetermined time after the power failure by the cold air of the cold storage means. The refrigerator compartment temperature switch 20 is an additional configuration for the present invention is preferably set to a slightly higher temperature than the normal refrigerator compartment holding temperature. Because it is an emergency situation of power failure, it is to use the cold air of the limited heat storage means 11 as long as possible for as long as possible.

As described above, in case of power failure, when the power is supplied again after a certain amount of time passes after the electric power of the battery and the cold of the cold storage means 1 according to the configuration of the present invention, the relay 1 returns to the internal iron piece ( (Not shown), whereby the relay switch 2 is returned to the contact point a of FIG. 2 to have a circuit configuration of a conventional freezer refrigerator, whereby the compressor 9 and the freezer fan 3 are freezer compartments. It is controlled on and off by the temperature switch 8 to return to the normal operating state.

If the circuit is configured as shown in FIG. 3, the relay switch 2 becomes the a contact point during normal operation, so that the freezer fan 3 and the compressor are supplied with power, but another relay switch 2 ' ) Is OFF, so that the battery power is not supplied to the DC / AC converter 6 in the normal operation, no matter how high the temperature of the refrigerating chamber is. The role of the DC / AC converter is that the freezer fan 3 mainly uses the AC fan, so that the DC of the battery 4 is driven in order to drive the AC freezer fan 3 with the DC power of the battery during a power failure. It converts power to AC power. Therefore, if the freezer compartment fan 3 is configured as a fan for DC from the beginning, the DC / AC converter 6 may be omitted in this case, since DC does not need to be converted to AC for driving during power failure. Is common sense.

[Operation of Example 2]

During normal operation, the battery is charged and the cold air is stored by the cold storage means in the freezer compartment. When an unexpected power failure occurs, the cold air stored in the cold storage means 11 in the freezer compartment is operated by operating the freezer compartment fan 3 with the power of the battery. The method of supplying the freezer compartment and the refrigerating compartment is the same as in Example 1 described above. However, in the second embodiment, in the normal operation in the uninterrupted state, the freezing chamber and the refrigerating chamber are respectively cooled by heat exchange by natural convection in a direct-cooling evaporator that does not require the operation of the freezer compartment fan 3. It's just different. That is, this embodiment is a case where the present invention is installed in a direct-cooling freezer refrigerator, in which case it has a cold air circulation structure in the inter-cooling as shown in FIG. The circuit operation for the second embodiment is the same as that of the first embodiment described above.

In the above-mentioned Example 1 and Example 2, the structure which installs the other accumulator | cooling means 11 in the freezer compartment was proposed so far. However, as shown in FIG. 5, the cold air of the frozen foods 21 in the freezer compartment may be used as the cold storage means instead of installing a separate cold storage means 11 in the freezer compartment. In this case, there is an advantage that the structure is simplified by not installing a separate heat storage means (11). In this case, by using the cold air of the frozen food 21 in the freezer compartment of FIG.

1 is a side cross-sectional view when the present invention is applied to a freezer refrigerator of an indirect cooling system.

2 is an example circuit diagram of the present invention.

3 is another example circuit diagram of the present invention.

4 is an air circulation structure of the intercooled refrigerator, which is installed in a fan in a freezer compartment, is cooled by a direct-cooling evaporator during normal operation, and circulates the cold air of the cold storage means in an intercooled manner during power failure. One example.

Figure 5 is an example of a side cross-sectional view of the present invention in the case of using the frozen food already frozen in the freezer compartment as a coolant as a cold storage means instead of a separate cold storage means.

※ Explanation of the main symbols in the drawings

1. Relay 2, 2 'relay switch

3. Freezer Fan 4. Storage Battery

5. Charging Circuit 6. DC / AC Converter

7. Damper 8. Freezer Temperature Switch

9. Compressor 10. Evaporator

11.Refrigeration means 12, freezer

13. Cold room 14. Freezer door

15. Refrigerator door 16. Defrost timer

17. Defrost heater 18. Bimetal

19. Doctor 20. Fridge Temperature Switch

21. Frozen Foods

Claims (2)

In the normal freezer refrigerator comprising a configuration having a cold storage means in the freezer compartment, The configuration of the cold storage means installed in the freezing chamber; The configuration of a relay connected to the power input of the refrigerator; A configuration of a relay switch interlocked with the relay whose contact is switched in response to the release of the relay during a power failure; The fan of the freezer compartment is connected to the power source energy of the battery which is charged at the time of no power failure by the charging circuit according to the switching of the relay switch, and the freezer compartment fan is connected to the refrigerator compartment temperature switch installed in the refrigerating compartment. A configuration in which power energy is controlled; Refrigeration refrigerator freezer, characterized in that configured to include a. The method according to claim 1, The refrigerator according to the electrostatic freezer, characterized in that instead of cold storage of the food is frozen in the freezer compartment.

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