KR19990002754A - Evaporator defrosting method of heat pump - Google Patents

Abstract

The present invention relates to a method of defrosting an evaporator of a heat pump. In the related art, the frost formed on the outer surface of the evaporator is removed by a high temperature refrigerant flowing back from the compressor while the outdoor fan is stopped. By inflowing a high temperature refrigerant into the evaporation heat exchanger and melting the frost at the temperature of the refrigerant, forming a forced convection with an outdoor fan to remove water droplets on the outer surface of the evaporation heat exchanger. It is effective to make indoor heating environment comfortable by minimizing the time that the indoor fan stops during defrosting.

Description

Evaporator defrosting method of heat pump

The present invention relates to a method for removing frost generated on an outer surface of an evaporative heat exchanger during a heating cycle of a heat pump, and in particular, by refluxing a high temperature refrigerant from a compressor to thaw frost frozen on an outer surface of an evaporative heat exchanger. Thereafter, the outdoor fan is operated to remove water, and the present invention relates to an evaporator defrosting method of a heat pump, which can drastically reduce defrosting operation time.

A general refrigeration cycle is applied to a refrigerator or an air conditioner to absorb heat from the outside or release heat to the outside to keep food fresh and to keep the indoor environment pleasant by cooling / heating the room.

Such a refrigeration cycle includes a compressor for converting a gaseous refrigerant of low temperature and low pressure into a gaseous refrigerant of high temperature and high pressure, and a condenser for changing a gaseous refrigerant of high temperature and high pressure changed into a liquid refrigerant of high temperature and high pressure in the compressor (hereinafter, Mixed with a heat exchanger for condensation), a capillary tube for converting the high temperature and high pressure liquid refrigerant changed in the condenser into a low temperature and low pressure liquid refrigerant, and the external heat while changing the low temperature low pressure liquid refrigerant in the capillary into a gas state. It is composed of an evaporator (hereinafter, mixed with the heat exchanger for evaporation), wherein each of the components are connected to the refrigerant pipe.

The refrigeration cycle of the heat pump that can serve as cooling / heating by applying the refrigeration cycle as shown in FIG.

That is, the refrigeration cycle for the heat pump is coupled to one side of the four-way valve (2) to the outlet of the compressor (1), the heat exchanger for condensation (3) is connected to the other side of the four-way valve (2), The condensation heat exchanger 3 is followed by an expansion mechanism, commonly referred to as a capillary tube 4, followed by the capillary tube 4, and an evaporation heat exchanger 5 is connected to the evaporation heat exchanger 5. It is then coupled to another side of the four-way valve (2), the other side of the four-way valve (2) is connected to the accumulator (1a), the accumulator (1a) is connected to the inlet of the compressor (1) It is done.

In the figure, reference numeral 3a denotes an indoor fan (sirocco fan), and 5a denotes an outdoor fan (axial flow fan).

In the heat pump refrigeration cycle configured as described above, while changing the direction of the four-way valve (2) to change the role of the condensation heat exchanger (3) and evaporation heat exchanger (5) to be used for cooling or heating do.

That is, when the refrigeration cycle for the heat pump is cooling, the indoor heat exchanger acts as an evaporator, while when heating, the indoor heat exchanger acts as a condenser. Of course, the outdoor heat exchanger at this time acts as a condenser when cooling, while acting as an evaporator when heating.

Here, the sequence of the refrigerant flow for the case where the refrigeration cycle for the heat pump is used for heating is as follows.

First, according to the operation of the compressor, the refrigerant is supplied to the compressor (1)-four-way valve (2)-condenser (3)-capillary tube (4)-evaporator (5)-four-way valve (2)-accumulator (1a)-compressor ( It proceeded through the sequence of 1) was to discharge the hot air heat exchanged in the condenser (3) by the indoor side sirocco fan (3a) to maintain the heating state.

When the evaporation temperature of the evaporation heat exchanger 5 installed outdoors in the normal heating cycle (external temperature condition is about 7 ℃) is about 0 ℃ to 1 ℃ but the external temperature is lowered the temperature difference between the refrigerant and the air The heat exchange efficiency is reduced and the heat exchange efficiency is reduced. In particular, while the heat exchange is performed in the evaporation heat exchanger (5) installed outdoors while the heat exchange is performed in the heat exchanger (3) installed in the room during the heating process, the evaporation heat exchanger ( Frost on the outer surface of 5) has been a cause of further deterioration of the performance of the heat pump.

Therefore, in the related art, the four-way valve 2 is periodically changed to send a high temperature refrigerant discharged from the compressor 1 to the evaporation heat exchanger 5, and then to the evaporation heat exchanger 5 at the temperature of the refrigerant. The frost formed on the surface was removed.

Looking at this in more detail as follows.

That is, when the time for which the heating cycle is normally operated has elapsed normally 60 minutes, the four-way valve (2) is changed so that the high temperature refrigerant discharged from the compressor (1) is evaporated on the outdoor side for 15 minutes ( 5) and the outdoor fan 5a stops to maintain the refrigerant in the evaporation heat exchanger 5 at about 50 ° C, and melts by the conduction heat to the outer surface of the evaporation heat exchanger 5. It was all evaporating the water that builds up. Of course, during the defrosting process as described above, the indoor fan 3a is stopped to prevent the supply of warm air into the room.

For reference, frost is best generated when the outdoor temperature is low and the humidity is high. If the humidity is about 0 ° C to 7 ° C and the humidity is 65% or more, the possibility of frost occurrence is significantly increased. This is because the relative humidity is the highest between about 0 ° C and 7 ° C, and if the temperature is below 0 ° C, the relative humidity is low and no frost occurs.

However, in the defrosting method of the heat pump as described above, there is a problem that the time for removing the frost formed on the outer surface of the evaporation heat exchanger 5 is too long, thereby preventing the supply of warm air to the room for a considerable time.

That is, when a small amount of water remains on the outer surface of the evaporation heat exchanger (5), the next time during heating, the water is implanted on the outer surface of the evaporation heat exchanger (5) earlier than before, and eventually the operating time of the heating cycle. Since much less, the defrosting is carried out for about 15 minutes so as to evaporate all the outer surface of the evaporation heat exchanger (5), especially trap-shaped water droplets formed between each cooling fin (not shown). When the defrosting, the outdoor fan 5a and the indoor fan 3a are not only stopped, but even when the refrigeration cycle finishes the defrosting and starts heating again, until the condensation heat exchanger 3 rises to a temperature suitable for heating. The indoor fan 3a is further stopped. At this time, the time required is usually about 5 minutes, so the indoor fan was stopped for about 20 minutes by adding 15 minutes of defrost time and 5 minutes of preheating time.

Therefore, the present invention improves the operation method of the heat pump with a refrigeration cycle as described above to minimize the time that the indoor fan is stopped when defrosting the heat exchanger for evaporation, heat pump that can comfort the indoor heating environment Its purpose is to provide an evaporator defrosting method.

1 is a schematic view showing a refrigerating cycle of a conventional heat pump.

Figure 2 is a flow chart showing a method of defrosting the evaporator of the heat pump according to the present invention.

Figure 3 is a graph showing the effect of the defrosting of the heat pump of the present invention compared with the conventional.

Explanation of symbols on the main parts of the drawings

1: compressor 2: four-way valve

3: heat exchanger for condensation 3a: indoor fan

4: capillary tube 5: heat exchanger for evaporation

5a: outdoor fan

In order to achieve the object of the present invention, one side of the four-way valve is in communication with the compressor, the other side of the four-way valve is in communication with the condenser, the capillary is in communication with the condenser, the capillary is followed by the evaporator In the refrigeration cycle of the heating and cooling heat pump is connected to, the evaporator followed by another side of the four-way valve, and another side of the four-way valve, the compressor through the accumulator again, the refrigeration cycle, Comparing the refrigerant temperature of the evaporating heat exchanger with the normal defrosting starting temperature while the cycle is in progress, and continuing the heating operation if the refrigerant temperature of the evaporating heat exchanger is not lower than the defrosting starting temperature. On the other hand, when the refrigerant temperature of the heat exchanger for the evaporator is lower than the set temperature, the heating operation is stopped and instead the defrosting operation is started. The outdoor fan and the indoor fan are turned off, the outdoor fan and the indoor fan are stopped, and at the same time, the high temperature refrigerant discharged from the compressor is introduced into the evaporation heat exchanger for a predetermined time, and the external surface of the heat exchanger Defrosting the frozen frost, and removing the water droplets formed on the heat exchanger while the outdoor fan is restarted for a predetermined time to release a relatively hot wind to the evaporation heat exchanger. A method is provided.

Hereinafter, the evaporator defrosting method of the heat pump according to the present invention will be described in detail based on the embodiment shown in the accompanying drawings.

In the defrosting method of the present invention, a high-temperature refrigerant is introduced into the evaporating heat exchanger for a predetermined time to melt the frost at the temperature of the refrigerant, and then a forced convection is formed by an outdoor fan to remove water droplets formed on the outer surface of the evaporating heat exchanger. 2 is a flow chart shown to explain the evaporator defrosting method of the heat pump according to the present invention.

As shown in the drawing, during the heating operation of the refrigeration cycle of the heat pump, the refrigerant temperature of the outdoor heat exchanger 5, that is, the evaporation heat exchanger, is -20 ° C., which is a normal defrosting start temperature. The temperature is lower than a predetermined temperature), and if the refrigerant temperature of the evaporator heat exchanger 5 is not lower than the set temperature, the heating operation is continuously performed, on the contrary, the refrigerant temperature of the heat exchanger 5 for evaporator Is lower than the set temperature, the heating operation is stopped and the defrosting operation is started instead. At this time, the outdoor fan (5a) and the indoor fan (3a) is turned off (OFF) at the same time the high-temperature refrigerant discharged from the compressor (1) to the four-way valve (2) flows in the opposite direction of the normal heating cycle evaporation heat exchange Frost which flows into the machine 5 and freezes on the outer surface of the heat exchanger 5 starts to melt.

Next, when the time elapses after 2 minutes (which is supplemented by the graph shown in FIG. 3 as an experimental value) since the defrosting operation is started, the outdoor fan 5a is restarted for about 3 minutes and relatively hot wind is generated. To the outdoor heat exchanger (5) to remove the water droplets formed on the outer surface of the heat exchanger (5) by the wind. As it is known, in general, when the water is removed, forced convection by wind has a faster material transfer rate than natural convection by heat of about 50 ° C.

Next, after the external surface of the evaporating heat exchanger 5 is removed as well as trap type water droplets formed between each cooling fan (not shown) by restarting the outdoor fan 5a (this time is about 3 Minutes). The indoor heat exchanger (3), that is, the heat exchanger for condensation rises to an appropriate temperature again, and the indoor fan (3a) is restarted to supply warm air to the room. At this time, the time required for the condensation heat exchanger 3 to rise to an appropriate temperature is about 5 minutes as described in the related art.

As a result, a conventional defrosting effect of removing frost formed in the evaporative heat exchanger while the outdoor fan is stopped for 15 minutes as shown by the solid line in FIG. 3, or about 2 minutes as shown by the dotted line in FIG. 3. It can be seen that the defrosting effect of the present invention, which stops and simultaneously removes water droplets by operating the outdoor fan for about 3 minutes after thawing frost by refluxing a high temperature refrigerant, can be seen.

As described above, in the evaporator defrosting method of a heat pump according to the present invention, a high-temperature refrigerant is introduced into the evaporation heat exchanger for a predetermined time, the frost is melted at the temperature of the refrigerant, and then forced convection is performed by an outdoor fan. By removing the water droplets formed on the outer surface of the evaporation heat exchanger, it is possible to minimize the time that the indoor fan is stopped when defrosting the evaporation heat exchanger to make the heating environment of the room comfortable.

Claims (2)

One side of the four-way valve communicates with the compressor, the other side of the four-way valve communicates with the condenser, the capillary tube communicates with the condenser, the evaporator communicates with the capillary tube, and the four direction following the evaporator. In the refrigeration cycle of the heating and cooling heat pump in which another side of the valve is connected, and the compressor is again communicated through the accumulator following another side of the four-way valve, heat exchange for evaporation while the refrigeration cycle is heating operation Comparing the refrigerant temperature of the air heater with the normal defrosting start temperature, and if the refrigerant temperature of the evaporator heat exchanger is not lower than the defrost start temperature, heating operation is continued while the refrigerant temperature of the heat exchanger for evaporator is If the temperature is lower than the set temperature, the heating operation is stopped and the defrosting operation is started. Instead, the outdoor fan and the indoor fan are turned off. And at the same time as the outdoor fan and the indoor fan are stopped and hot refrigerant discharged from the compressor is introduced into the evaporation heat exchanger for a predetermined time to thaw frost frozen on the outer surface of the heat exchanger. Evaporator defrosting method of the heat pump, characterized in that performed for a predetermined time to remove the water droplets formed on the heat exchanger while blowing a relatively hot wind to the heat exchanger for evaporation. The method of claim 1, wherein the time for stopping the outdoor fan is set to 2 minutes, and the time for blowing air to the heat exchanger for evaporation to the outdoor fan is set to 3 minutes.