JP5393283B2 - refrigerator - Google Patents

Description

  The present invention relates to a refrigerator, particularly a refrigerator that automatically performs a defrosting operation for removing frost attached to a cooler.

  In a refrigerator with a forced air circulation system that cools a refrigerator compartment (corresponding to the refrigerator temperature zone chamber in the present invention) and a freezer chamber (corresponding to the refrigerator temperature zone chamber in the present invention) with a common cooler, As the techniques, the techniques of Patent Document 1 to Patent Document 4 shown below are known.

  Patent Document 1 describes a technique for performing defrosting as a defrosting heater energization state in a compressor stopped state, all damper closed states, and an internal fan stopped state.

  Patent Document 2 discloses that when a compressor operation time integration reaches a predetermined value during a normal cooling operation or when a user turns on a manual humidification switch, the refrigerator compartment damper is opened, A technique is described in which the chamber damper is closed, the internal fan is operated to perform a humidifying operation, and the defrosting operation is terminated after a predetermined time has elapsed or when the cooler has risen to a predetermined upper limit temperature.

  Patent Document 2 also discloses that when the integrated value of the operating time of the compressor reaches a predetermined value, the defrost heater is energized, and at the same time, the refrigerator compartment damper is opened and the freezer compartment damper is closed. Describes a technique for performing a humidification operation (also a defrosting operation) by operating the.

  Further, in Patent Document 3, when the accumulated operation time of the compressor becomes a predetermined time or more, the operation of the compressor is stopped, the defrost heater is energized, the freezer damper is closed, and the refrigerator compartment When the damper is in the open state, the humidifier operation (also defrosting operation) in the refrigerator compartment is performed by operating the internal fan, and when the temperature of the refrigerator compartment exceeds the predetermined temperature, the energization to the defrost heater is stopped and A technique for performing a cooling operation in the refrigerator compartment (refrigerating compartment temperature return operation) by resuming the operation of the compressor is described.

  Furthermore, in Patent Document 4, the compressor is stopped before the defrost heater is energized during the defrosting operation, the refrigerator compartment damper is opened, and the cooler in the refrigerator compartment having a relatively high temperature is operated. As a result, the temperature of the cooler is raised so as to be called back into the cold air discharge duct, and when the temperature of the cooler becomes higher than a predetermined temperature, the internal fan is stopped and the refrigerator compartment damper is closed to defrost. A technique for energizing and defrosting a heater is described.

JP 2002-31466 A JP 2001-280784 A Japanese Patent No. 3912233 JP 2003-83667 A

  However, the conventional technology does not have sufficiently high energy saving performance, and is reliable in that reliable defrosting is performed, and that the temperature of the refrigerator compartment and the temperature of the freezer compartment during the defrosting is kept below their respective predetermined temperatures. It was low. The reason will be described below.

  First, problems of the conventional technology relating to energy saving performance will be described. In a refrigerator provided with a cooler that cools the refrigerator compartment and the freezer compartment in common, the first method for defrosting the cooler is the compressor stop state, all dampers described in Patent Document 1. In the closed state and the state where the internal fan is stopped, the defrost heater is energized to heat and defrost the frost. The energy saving performance of this method can be explained by considering [1] heat transfer efficiency between the defrosting heater and the frost and [2] handling of frost cold. First, [1] Regarding the heat transfer efficiency between the defrost heater and the frost, in the method of heating frost with the defrost heater described in Patent Document 1, heat transfer from the defrost heater to the frost is basically performed. Is due to natural convection (there is also radiation, but natural convection is generally dominant), so the heat transfer efficiency between the defrost heater and frost is low. Therefore, in order to give the necessary amount of heat to the frost, more inputs are required to the defrost heater, and the energy saving performance is low. Next, [2] handling of frost cold will be described. Since the refrigerating room is a room that is normally maintained at about 3 to 5 ° C., frost that undergoes a phase change (melting) at 0 ° C. can be considered as a cooling heat source that can cool the refrigerating room when viewed from the refrigerating room. Considering this, the method (first method) in which frost is heated and defrosted by the defrost heater described in Patent Document 1 is discarded without reusing the cold heat of available frost for cooling the refrigerator compartment. As a result, the energy saving performance cannot be sufficiently increased.

  In a refrigerator provided with a cooler that cools the refrigerator compartment and the freezer compartment in common, the second method for defrosting the cooler is described in Patent Document 2, and the refrigerator compartment is in a refrigerator stopped state. In this method, the damper is opened, the freezer damper is closed, and the defrost heater is not energized, and the refrigerator is operated to humidify the refrigerator. This second method is intended for humidification, but frost can be dissolved by this method as well, so here it will be described as the second method. In this case, the input to the defrost heater is zero, the energy input from the outside is only the power of the internal fan (generally sufficiently smaller than the input of the defrost heater), and the air cooled by the frost is stored in the refrigerator compartment. To be supplied.

  That is, the energy saving performance is very high because the refrigeration room is cooled using the cold heat of frost. However, it is difficult to perform complete defrosting by this second method. This is because when the compressor is stopped and the refrigerator compartment damper is opened, the freezer compartment damper is closed, and the internal fan is operated, it takes time to defrost. This is because if the frost is attempted, the temperature of the freezer compartment that closes the damper and stops air blowing rises. Therefore, the second method for defrosting the cooler described in Patent Document 2 is unsuitable as a defrosting method for a refrigerator provided with a cooler that cools the refrigerator compartment and the freezer compartment in common.

  In a refrigerator provided with a cooler that cools the refrigerator compartment and the freezer compartment in common, the third method for defrosting the cooler is described in Patent Document 2 or Patent Document 3, and the compressor stop In this state, the refrigerator compartment damper is opened, the freezer compartment damper is closed, the defrost heater is energized, and the internal fan is operated. Although this third method is intended for humidification, frost can be dissolved by this method as well, so here it will be described as the third method. The energy saving performance of this method will be described with reference to FIG.

  FIG. 11 shows a state in which the defrost heater is energized while the cool air circulation to the freezer compartment is interrupted when the compressor is stopped, and at the same time, the internal fan provided in the refrigerator is described in Patent Document 2 or Patent Document 3. It is a time chart showing the change of the temperature in a refrigerator compartment, the refrigerator compartment discharge air temperature, and a cooler temperature at the time of performing a humidification operation by sending air to a refrigerator compartment. The air returning from the refrigerator compartment is heated by the defrost heater and the temperature rises. Here, in order to increase the effect of humidification, the return air from the refrigerator compartment is sufficiently raised in temperature by a defrost heater to reduce the relative humidity (in a state where the amount of saturated water vapor is increased), What is necessary is just to make it flow into a cooler. As a result, more water (or frost) on the surface of the cooler evaporates (or sublimates), so that air containing a large amount of moisture can be supplied to the refrigerator compartment.

  On the other hand, by sufficiently raising the temperature with the defrost heater, the temperature of the air supplied to the refrigerating chamber also rises at the same time. The refrigerator compartment temperature will rise. Therefore, in the technique described in Patent Document 2, since the temperature of the refrigerator compartment is excessively increased, the technique described in Patent Document 3 is used to perform a cooling operation in the refrigerator compartment (the refrigerator compartment) so that such a situation does not occur. Temperature recovery operation).

  Note that due to the frost phase change (melting), the cooler temperature is maintained at approximately 0 ° C. from the start of frost melting to the completion of frost melting.

  In this way, with the main purpose of humidification, when the compressor is stopped, the defrost heater is energized while the cold air circulation to the freezer compartment is shut off, and at the same time, the refrigerator compartment is provided with air in the refrigerator compartment. In the prior art of Patent Document 2 or Patent Document 3 to be performed, the temperature of the refrigerator compartment rises, that is, the refrigerator compartment cannot be cooled. From this, the third method for defrosting the cooler frost has a high heat transfer efficiency between the defrost heater and the frost because the forced convection is formed by the internal fan, but the cooler frost As described in the explanation of the first method for solving the problem, the energy saving performance is lowered by that amount because the available frost is not reused for cooling the refrigerator compartment. That is, in the prior arts of Patent Document 2 or Patent Document 3, since the purpose is humidification, no consideration is given to increase energy savings such as “reuse of frost cold”.

  For the above reasons, when performing defrosting (complete defrosting) using the conventional technology for defrosting, the energy saving effect has been reduced.

  Next, a description will be given of problems of the related art relating to reliability in that the above-described reliable defrosting is performed or the temperature of the refrigerator compartment and the temperature of the freezer compartment during the defrosting are kept below the predetermined temperatures.

  In the technique described in Patent Document 2 or the technique described in Patent Document 3, the flow field indicating the state of the cool air flow in the cooler chamber formed by the return cold air from the refrigerator compartment, and the return cold air from the freezer compartment Because the flow field indicating the state of the cold air flow in the cooler room to be formed is different, consideration is given to the fact that there is a place where frost is difficult to thaw when air is blown into the refrigerator room by the internal fan and defrosted Has not been made. As a result, there is a problem that the user will not be able to keep the food in the predetermined temperature range or the energy saving performance will be deteriorated without leaving the refrigerator door open for a long time, for example, without leaving the refrigerator door open for a long time. Has occurred.

  Moreover, in the technique described in Patent Document 4, the cooler in the refrigerating room having a relatively high temperature is caused to flow back into the cool air discharge duct by operating the internal blower, thereby raising the cooler temperature. In order to cause the cold air in the refrigeration room having a high temperature to flow back into the refrigeration room air duct rather than into the refrigeration room return duct, it is necessary to form an air flow opposite to that during normal cooling operation. It is necessary to reversely rotate the inner blower or to separately provide a second internal blower for forming a reverse flow.

  Usually, since the wing shape is designed so that the blower efficiency is maximized during forward rotation, the blower efficiency is greatly reduced during reverse rotation. Therefore, in order to obtain a predetermined air volume, for example, it is necessary to increase the rotational speed during reverse rotation, which causes a problem that required power of the internal fan increases and a problem that noise increases.

  Moreover, when the 2nd fan in a store | warehouse | chamber was provided separately in order to form a reverse flow, the reduction | decrease in the refrigerator volume and the increase in cost were caused.

  Furthermore, the technique described in Patent Document 4 is for defrosting when the cooler temperature is higher than a predetermined temperature by stopping the internal fan and closing the refrigerator compartment damper to energize the defrost heater. However, due to insufficient consideration of the temperature change of the cooler during defrosting, the energy saving performance is low, and even if the user does not have a special drop, the food in the refrigerator cannot be maintained within the specified temperature range. There was a possibility that.

  The reason why the problem occurs will be described below. The cooler temperature at the time of defrosting almost represents the temperature of the frost, and the temperature change of the frost is the part of the sensible heat change from the minus temperature to 0 ° C, when the frost melts (during phase change) It is composed of a constant latent heat change portion that is seen at 0 ° C., and a sensible heat change portion where the temperature becomes higher than 0 ° C. after the frost has been thawed. The specific heat of frost (ice) is about 2 kJ / (kg · K), the latent heat of fusion of frost (ice) is about 335 kJ / kg, and the specific heat of water is about 4.2 kJ / (kg · K). When defrosting the cooler, a great amount of heat is required at the time of latent heat change (phase change).

  From this, at the time of defrosting, especially when there is a relatively large amount of frost, the constant time of 0 ° C. becomes longer. In other words, it can be said that frost is a cold source that can absorb a great deal of heat during a phase change of 0 ° C. In addition, considering energy saving performance, the defrosting method in which the defrost heater is in a non-energized state and blows air to the refrigerating room by the internal fan uses the cold heat of the frost to cool the refrigerating room. Energy saving performance is high because the effect of defrosting with the heat load of the refrigerator compartment and the heat transfer efficiency between the cooler and the blower are increased by causing forced convection by the blower.

  On the other hand, the defrosting method that energizes the defrosting heater while the internal fan is stopped does not use the cold heat of the frost for cooling, and the cooler and the surrounding air are natural convection, compared with forced convection. Because of its low heat transfer efficiency, energy saving performance is low.

  In consideration of the above, in the technique described in Patent Document 4, when the set value of the cooler temperature for stopping the internal fan is set to 0 ° C. or less, the sensible heat change of the frost has Only the cold heat of the part can be used for cooling the refrigerator compartment. Therefore, the part of the latent heat change from which more available cold heat can be taken out for cooling the refrigerator compartment is discarded by the defrosting by the defrosting heater performed with the internal fan stopped. As a result, the energy saving effect was reduced.

  On the other hand, when the set value of the cooler temperature for stopping the internal blower is set to a temperature higher than 0 ° C., when the amount of frost is relatively large, as described above, the time constant for 0 ° C. (part of the latent heat change) ) For a long time, the temperature rise in the freezer compartment in a state where the cold air circulation is interrupted becomes significant, and there is a possibility that the frozen food can be dissolved even if the user does not have a special drop.

  The present invention has been made in view of the above-mentioned problems of the prior art, and provides a highly reliable refrigerator that has high energy saving performance and is unlikely to maintain food in the refrigerator in a predetermined temperature range. The purpose is to do.

In order to achieve the above object, the invention according to claim 1 of the present invention has at least a refrigeration temperature zone chamber, a refrigeration temperature zone chamber, a compressor, and the refrigeration temperature zone chamber and the refrigeration temperature zone chamber in common. A cooler that cools the cooler, a blower that circulates the cool air cooled by the cooler to the refrigeration temperature zone chamber and the refrigeration temperature zone chamber, and a refrigeration that controls ventilation from the cooler to the refrigeration temperature zone chamber In a refrigerator comprising a room damper, a refrigeration room damper that controls ventilation from the cooler to the refrigeration temperature zone, and a defrost heater that defrosts the frost attached to the cooler, when the compressor is stopped, A first defrosting means for defrosting by closing the freezer damper, opening the refrigerator compartment damper, de-energizing the defrost heater, operating the blower, and stopping the compressor Sometimes the freezer damper is closed and the front The refrigerator compartment damper is opened, the defrost heater is energized, the defroster is activated by operating the blower, and the freezer damper is closed when the compressor is stopped. A third defrosting means for closing the refrigerator compartment damper, energizing the defrost heater, and defrosting the blower in a stopped state, the first defrosting means, the second defrosting means, It has a plurality of defrosting modes for performing a defrosting operation by combining one or more of the defrosting means and the third defrosting means, and selects one defrosting mode from the plurality of defrosting modes. the defrosting operation is performed, then the defrost heater is energized state, have rows defrosting performing defrosting the air blower as the stop state, the selected defrosting mode, divided by the temperature of the cooler Defrost completion is determined, and defrost completion is determined to determine the defrost completion. The constant temperature differs depending on the selected defrost mode, and the defrost completion determination temperature in the defrost mode in which the defrost operation by the third defrost means is performed is performed by the third defrost means. It is set higher than the defrosting completion determination temperature of the defrosting mode which is not performed .

  According to the first aspect of the present invention, in the defrosting operation by the first defrosting means, the refrigeration temperature zone chamber is attached to the cooler while the frost adhering to the cooler is dissolved by the return air from the refrigeration temperature zone chamber. It will be cooled by the latent heat of the frost that has been produced, and the energy saving effect is great.

  Further, in the defrosting operation by the second defrosting means, the frost adhering to the cooler is further heated by the defrosting heater after the return air from the refrigeration temperature zone chamber is defrosted, and the refrigeration temperature zone chamber is used. It is possible to cool the refrigerated temperature zone as an air temperature of an appropriate temperature, the heat transfer efficiency with the frost in the defrosting operation is good, and a shorter time than in the case of the defrosting operation by the first defrosting means. Defrosting is possible. Energy saving effect is better than defrosting using only a defrosting heater.

  As a result, by combining the defrosting operations by the first to third defrosting means, the defroster is defrosted by natural convection with the cooler only by the defrosting heater in the defrosting operation by the third defrosting means. It is possible to perform a defrosting operation with a higher energy saving effect than to do.

Moreover, after performing the defrost operation of the said defrost mode, a cooler can be defrosted reliably by making the said defrost heater into an energized state and performing a defrost with the said air blower stopped. Moreover, the defrost completion determination temperature of each defrost mode can be set differently, and the completion | finish state of the defrost of the cooler according to the objective of each defrost mode can be set flexibly. In addition, the defrosting completion determination temperature in the defrosting mode in which the defrosting operation by the third defrosting unit is performed is set higher than the defrosting completion determination temperature in the defrosting mode in which the third defrosting unit is not performed. The In the defrosting operation by the third defrosting means, the cooler is defrosted by heat exchange by natural convection with a defrosting heater. In the defrosting operation by the second defrosting means, the refrigeration temperature zone chamber is used. Since air is not circulated, it is possible to set the defrosting completion determination temperature at a higher cooler temperature, and complete defrosting can be performed.

The invention according to claim 2 of the present invention includes at least a refrigeration temperature zone chamber, a refrigeration temperature zone chamber, a compressor, a cooler that cools the refrigeration temperature zone chamber and the refrigeration temperature zone chamber in common, and A fan that circulates cold air cooled by a cooler to the freezing temperature zone chamber and the refrigeration temperature zone chamber, a freezer damper that controls air flow from the cooler to the freezing temperature zone chamber, and the cooler In a refrigerator having a refrigerator compartment damper that controls air flow to the refrigerator temperature zone chamber and a defrost heater that defrosts frost attached to the cooler, when the compressor is stopped, the freezer compartment damper is closed, The refrigerator compartment damper is opened, the defrost heater is energized, the defroster is activated by operating the blower, and the freezer compartment damper is closed when the compressor is stopped. And the refrigerator compartment damper is closed, A third defrosting unit that deenergizes the defrosting heater and defrosts the blower in a stopped state, and includes the first defrosting unit, the second defrosting unit, and the third defrosting unit. A plurality of defrosting modes for performing a defrosting operation by combining one or more of the means, and after the defrosting operation by the second defrosting unit, the defrosting operation by the third defrosting unit In the second defrosting mode, the defrosting operation by the second defrosting means is a predetermined first defrosting mode in which the temperature of the cooler is 0 ° C. or higher. higher than condenser temperature, and ends when the temperature of the condenser is higher than the temperature of the refrigerating temperature zone compartment, the defrosting operation by the third defrosting means is carried, characterized in Rukoto.

According to the second aspect of the present invention, the defrosting operation by the second defrosting means is terminated when the temperature of the cooler becomes higher than the predetermined first cooler temperature of 0 ° C. or higher. The air circulated from the blower during the defrosting operation by the defrosting means 2 to the refrigeration temperature zone chamber prevents the temperature of the refrigeration temperature zone chamber from exceeding the predetermined temperature range required for the refrigeration temperature zone chamber. it can. Further, since the defrosting operation by the second defrosting means is terminated when the temperature of the cooler becomes higher than the temperature of the refrigeration temperature zone, the refrigeration temperature is supplied from the blower during the defrosting operation by the second defrosting means. The temperature of the refrigerated temperature zone chamber can be prevented from exceeding the predetermined temperature range required for the refrigerated temperature zone chamber by the air circulated in the belt chamber.

  The invention described in claim 3 of the present invention is characterized in that, in the configuration of the invention described in claim 1 or 2, the energization amount of the defrost heater in the second defrosting means is adjusted.

  According to the invention described in claim 3, in the defrosting operation, with the compressor stopped, the freezer compartment damper is closed, the refrigerator compartment damper is opened, the defrost heater is energized, and the blower is Since the defrost heater is energized to adjust the energization amount of the defrost heater so that the temperature of the refrigeration temperature zone is maintained or lowered while operating, the refrigeration temperature zone chamber is adjusted by the latent heat of frost attached to the cooler, etc. It will cool, and the energy saving effect is great. Further, there is no problem that the temperature of the refrigerated temperature zone cannot be maintained at a predetermined value.

  The invention described in claim 4 of the present invention is characterized in that, in the configuration of the invention described in claim 1 or 2, the rotational speed of the blower in the second defrosting means is adjusted.

  According to the invention of claim 4, in the defrosting operation, with the compressor stopped, the freezer compartment damper is closed, the refrigerator compartment damper is opened, the defrost heater is energized, and the blower is While operating and defrosting, the rotation speed of the blower is adjusted so that the temperature of the refrigerated temperature zone is maintained or lowered, so the refrigerated temperature zone is cooled by the latent heat of frost attached to the cooler, etc. That is, the energy saving effect is great. Further, there is no problem that the temperature of the refrigerated temperature zone cannot be maintained at a predetermined value.

According to a fifth aspect of the present invention, in the configuration of the first or second aspect of the present invention, the defrosting operation by the third defrosting means is the second cooling in which the temperature of the cooler is predetermined. It ends when the temperature rises to the vessel temperature.

According to invention of Claim 5 , the temperature condition of the cooler which complete | finishes the defrost operation by a 3rd defrosting means can be set with 2nd cooler temperature different from 1st cooler temperature. In addition, the second cooler temperature can be set to a temperature higher than a predetermined temperature range required for the refrigeration temperature zone chamber, and the cooler can be set to a temperature capable of completely defrosting. As a result, highly reliable defrosting is possible.

The invention according to claim 6 of the present invention is the configuration of the invention according to any one of claims 1 to 5 , wherein the refrigeration temperature is performed during the defrosting operation in the selected defrosting mode. The third defrosting means is performed when the temperature of the belt chamber rises above a predetermined freezing temperature belt chamber upper limit temperature.

According to the sixth aspect of the present invention, the third defrosting means is implemented when the temperature of the freezing temperature zone chamber rises above the predetermined maximum freezing temperature zone temperature during the defrosting operation. In addition, it is possible to prevent the problem that the stored items in the refrigeration temperature zone can be unraveled and to reliably defrost the cooler.

According to a seventh aspect of the present invention, in the configuration of the sixth aspect of the present invention, the upper limit temperature of the freezing temperature zone varies depending on the selected defrosting mode.

According to the seventh aspect of the present invention, since the refrigeration temperature zone upper limit temperature can be set differently depending on the selected defrost mode, the refrigeration temperature zone upper limit temperature is set, for example, in a mild defrosting operation with high operation frequency. The defrosting operation freezing temperature zone upper limit temperature for performing reliable defrosting with low operation frequency is set high, and the frequency of large temperature changes in the freezing temperature zone chamber due to the defrosting operation can be reduced.

The invention according to claim 8 of the present invention is the refrigerator according to claim 7 , wherein the freezing temperature zone upper limit temperature in the defrosting mode in which the defrosting operation by the third defrosting means is performed is It is set higher than the freezing temperature zone room upper limit temperature in the defrosting mode in which the defrosting operation by the third defrosting means is not performed.

According to the eighth aspect of the present invention, the defrosting operation refrigeration temperature zone upper limit temperature for performing the defrosting with low refrigeration temperature zone and the reliable defrosting operation frequency is set low in the light defrosting operation with high operation frequency. It is possible to reduce the frequency of the large temperature change in the freezing temperature zone due to the defrosting operation by setting it high.

The invention according to claim 9 of the present invention is the refrigeration temperature zone in the defrosting mode in which only the defrosting operation by the first defrosting means is performed in the configuration of the invention according to claim 7 or claim 8. The room upper limit temperature is set lower than the freezing temperature zone room upper limit temperature in the defrost mode including the defrosting operation by the second defrosting unit or the defrosting operation by the third defrosting unit. And

According to the ninth aspect of the present invention, the defrosting operation freezing temperature zone upper limit temperature for performing the reliable defrosting with low refrigeration temperature zone room temperature and lowering the refrigeration temperature zone room upper temperature limit in the mild defrosting operation with high operation frequency is set. It is possible to reduce the frequency of the large temperature change in the freezing temperature zone due to the defrosting operation by setting it high.

  According to the present invention, it is possible to provide a highly reliable refrigerator that has high energy saving performance and is unlikely to cause a possibility that the food in the refrigerator cannot be maintained in a predetermined temperature range.

It is a front external view of the refrigerator which concerns on embodiment of this invention. It is a longitudinal cross-sectional view showing the structure in the store | warehouse | chamber of a refrigerator. It is a front view showing the structure in the store | warehouse | chamber of a refrigerator. It is a partial side view of a cooler peripheral part. It is a partial front view of a cooler peripheral part. It is a figure explaining a defrost mode. It is a flowchart which shows the flow of control of a defrost operation. It is a flowchart which shows the flow of control of a defrost operation. It is a flowchart which shows the flow of control of a defrost operation. It is a time chart at the time of defrosting in the defrosting mode 4. FIG. It is a time chart at the time of the humidification driving | operation in a prior art.

  An embodiment of a refrigerator according to the present invention will be described with reference to FIGS.

  FIG. 1 is a front external view of a refrigerator according to the present embodiment, and FIG. 2 is an XX longitudinal sectional view in FIG. 1 showing a configuration inside the refrigerator. FIG. 3 is a front view illustrating a configuration inside the refrigerator, and is a diagram illustrating the arrangement of the cold air duct and the outlet.

  As shown in FIG. 1, the refrigerator 1 of this embodiment is comprised from the upper part from the refrigerator compartment 2, the ice-making room 3, the upper stage freezer room 4, the lower stage freezer room 5, and the vegetable compartment 6. FIG.

  Here, the refrigerator compartment 2 and the vegetable compartment 6 in the present embodiment correspond to the refrigerator temperature zone chamber described in the claims, and the ice making chamber 3, the upper freezer chamber 4, and the lower refrigerator chamber 5 are the freezing temperatures described in the claims. Corresponds to the obi room.

  The refrigerating room 2 includes front and rear refrigerating room doors 2a and 2b which are divided into left and right sides. The ice making room 3, the upper freezing room 4, the lower freezing room 5, and the vegetable room 6 are each a drawer-type ice making room door. 3a, an upper freezer compartment door 4a, a lower freezer compartment door 5a, and a vegetable compartment door 6a. Hereinafter, the refrigerator compartment doors 2a and 2b, the ice making compartment door 3a, the upper freezer compartment door 4a, the lower freezer compartment door 5a, and the vegetable compartment door 6a are simply referred to as doors 2a, 2b, 3a, 4a, 5a, and 6a.

  The refrigerator 1 includes a door sensor (not shown) that detects the open / closed state of each door of the doors 2a, 2b, 3a, 4a, 5a, and 6a, and a state determined to be the door open state for a predetermined time, for example, 1 minute. When the operation is continued, an alarm (not shown) for notifying the user, a temperature setting unit (not shown) for setting the temperature of the refrigerator compartment 2 and the temperature of the upper freezer compartment 4 and the lower freezer compartment 5 are provided.

  As shown in FIG. 2, the outside of the refrigerator 1 and the inside of the refrigerator are separated by a heat insulating box 10 formed by filling a foam heat insulating material (foamed polyurethane). The heat insulating box 10 of the refrigerator 1 has a plurality of vacuum heat insulating materials 25 mounted thereon.

  The inside of the refrigerator is separated from the refrigerator compartment 2 by the heat insulating partition wall 28, the upper freezing chamber 4 and the ice making chamber 3 (see FIG. 1, the ice making chamber 3 is not shown in FIG. 2). The lower freezer compartment 5 and the vegetable compartment 6 are separated.

  A plurality of door pockets 32 are provided on the inner side of the doors 2a and 2b (see FIG. 1, the refrigerator compartment door 2b is not shown in FIG. 2). The refrigerator compartment 2 is partitioned into a plurality of storage spaces in the vertical direction by a plurality of shelves 36.

  As shown in FIG. 2, the upper freezer compartment 4, the lower freezer compartment 5, and the vegetable compartment 6 are integrated with doors 3a, 4a, 5a, 6a provided in front of the respective compartments, and storage containers 3b, 4b, 5b. , 6b are provided, and the storage containers 4b, 5b, 6b can be pulled out by placing a hand on a handle portion (not shown) of the doors 4a, 5a, 6a and pulling it out to the front side. Similarly, the ice making chamber 3 shown in FIG. 1 is provided with an unillustrated storage container (indicated by (3b) in FIG. 2) integrally with the door 3a. The container 3b can be pulled out by pulling it out.

  As shown in FIG. 2 (see FIG. 3 as appropriate), the cooler 7 is provided in a cooler storage chamber 8 provided substantially at the back of the lower freezing chamber 5, and is a warehouse provided above the cooler 7. Air cooled by heat exchange with the cooler 7 by the internal blower (blower) 9 (cold air, hereinafter, low-temperature air cooled by the cooler 7 is referred to as cold air) is a refrigerator compartment air duct 11, symbol omitted Refrigeration room 2, vegetable room 6, upper freezer room 4, lower freezer room through vegetable room air duct (see FIG. 3), upper freezer room air duct 12, lower freezer room air duct 13 and ice making room air duct (not shown) 5. It is sent to each chamber of the ice making chamber 3. Air blowing to each room is controlled by opening and closing the refrigerator compartment damper 20 and the freezer compartment damper 50.

  Incidentally, the air ducts to the refrigerator compartment 2, the ice making room 3, the upper freezer room 4, the lower freezer room 5, and the vegetable room 6 are provided on the back side of each room of the refrigerator 1 as indicated by broken lines in FIG. Yes.

  Specifically, when the refrigerator compartment damper 20 is in the open state and the freezer compartment damper 50 is in the closed state, the cold air is sent to the refrigerator compartment 2 from the air outlets 2c provided in multiple stages via the refrigerator compartment air duct 11. It passes through the vegetable room ventilation duct (refer FIG. 3) branched from the room ventilation duct 11, and is sent to the vegetable room 6 from the blower outlet 6c.

  Note that the cold air that has cooled the refrigerator compartment 2 is viewed from the front of the cooler storage compartment 8 (see FIG. 5) from the return port 2d provided on the lower surface of the refrigerator compartment 2 through the refrigerator compartment return duct 16, for example. For example, return to the lower right side. The return air from the vegetable compartment 6 returns to the lower part of the cooler storage compartment 8 through the return opening 6d.

  Although the freezer damper 50 is omitted in FIG. 3, when the freezer damper 50 is in an open state, the cold air heat-exchanged by the cooler 7 is not shown in the drawing by an internal fan 9 and an ice making chamber air duct or upper freezer Air is blown from the blowout ports 3 c and 4 c to the ice making chamber 3 and the upper freezer compartment 4 through the blower duct 12, and blown from the blowout port 5 c to the upper freezer compartment 4 through the lower freezer compartment blower duct 13.

  The cold air that has cooled the upper freezing chamber 4, the lower freezing chamber 5, and the ice making chamber 3 returns to the cooler storage chamber 8 through the freezing chamber return port 17 provided in the lower part of the lower freezing chamber 5.

  A defrost heater 22 is installed below the cooler 7, and an upper cover 53 is provided above the defrost heater 22 to prevent defrost water from dripping onto the defrost heater 22. It has been.

  In addition, the defrost heater 22 can change an output by the duty control by the control board 31 mentioned later.

  The defrost water produced by the frost adhering to the wall of the cooler 7 and the surrounding cooler storage chamber 8 is melted by the defrost, and then flows into the trough 23 provided at the lower part of the cooler storage chamber 8. It reaches the evaporating dish 21 disposed in the machine room 19 to be described later via the drain pipe 27 and is evaporated by the heat of the condenser to be described later.

  Further, a cooler temperature sensor 35 is provided in the upper right portion when viewed from the front of the cooler 7, a refrigerator temperature sensor 33 is provided in the refrigerator compartment 2, and a freezer compartment temperature sensor 34 is provided in the lower freezer compartment 5, respectively. The temperature of the cooler 7 (hereinafter referred to as “cooler temperature”), the temperature of the refrigerator compartment 2 (hereinafter referred to as “refrigerator compartment temperature”), and the temperature of the lower freezer compartment 5 (hereinafter referred to as “freezer compartment temperature”) can be detected. It has become.

  Here, the temperature of the refrigerator compartment in the present embodiment corresponds to the temperature of the refrigerator temperature zone described in the claims, and the temperature of the freezer compartment corresponds to the temperature of the refrigerator temperature zone described in the claims.

  Further, the refrigerator 1 includes an outside air temperature sensor and an outside air humidity sensor (not shown) that detect a temperature and humidity environment (outside air temperature, outside air humidity) outside the refrigerator.

  Note that the vegetable room temperature sensor 33A may be arranged in the vegetable room 6 as well.

  A machine room 19 is provided on the lower back side of the heat insulating box 10. The machine room 19 contains a compressor 24 and a condenser (not shown). Is removed.

  Incidentally, in this embodiment, isobutane is used as a refrigerant, and the amount of refrigerant enclosed is as small as about 80 g.

  A control board 31 on which a CPU, a memory such as a ROM and a RAM, an interface circuit, and the like are mounted is disposed on the upper surface side of the refrigerator 1. The control board 31 includes the above-described outside temperature sensor, outside air humidity sensor, and cooler. The temperature sensor 35, the refrigerator temperature sensor 33, the freezer temperature sensor 34, the door sensor for detecting the open / closed state of each door of the doors 2a, 2b, 3a, 4a, 5a, 6a, respectively, are provided on the inner wall of the refrigerator compartment 2. Connected to a temperature setter (not shown), a temperature setter (not shown) provided on the inner wall of the lower freezer compartment 5, etc., and control of turning on / off the compressor 24 by a program pre-installed in the ROM, refrigerator compartment damper 20 and the control of each actuator (not shown) that individually drives the freezer damper 50, ON / OFF control and rotational speed control of the internal fan 9, and the external fan ON / OFF control or rotating speed control control or the like, and controls, such as alarm ON / OFF to notify the above-mentioned door open.

  Next, the flow of air flowing into the refrigerator cooler of the present embodiment will be described with reference to FIGS. 2 and 3 as appropriate with reference to FIGS. 4 and 5.

  4 is a partial side view of the peripheral portion of the cooler, and FIG. 5 is a partial front view of the peripheral portion of the cooler.

  In the state where the refrigerator compartment damper 20 is closed and the freezer compartment damper 50 is open, and only the freezing temperature zone (the ice making room 3, the upper freezing room 4 and the lower freezing room 5) is being cooled, ice making is performed. The cold air blown into the chamber 3 through the ice making chamber air duct and the cold air blown into the upper freezer chamber 4 through the upper freezer chamber air duct 12 (see FIG. 2) descends to the lower freezer chamber 5 to be cooled at the lower stage. Along with the cold air blown into the chamber 5 through the lower freezer compartment air duct 13 (see FIG. 2), the freezer return air indicated by the arrow C in FIG. The refrigerant flows into the cooler housing chamber 8 from the lower front of the cooler housing chamber 8 via the freezer return port 17 and exchanges heat with the cooler 7 configured by attaching a number of fins to the cooler pipe 7a.

  Incidentally, the width dimension of the freezer return port 17 is substantially equal to the width dimension (cooler width dimension L) of the cooler 7 shown in FIG.

  On the other hand, in the state where the refrigerator compartment damper 20 is in the open state and the freezer compartment damper 50 is in the closed state, and only the refrigerator temperature zone chamber (the refrigerator compartment 2 and the vegetable compartment 6) is being cooled, The return cold air flows into the cooler storage chamber 8 from the lower side of the cooler storage chamber 8 through the refrigerator return duct 16 like the cooler return air indicated by the arrow D in FIG. Heat exchange with 7

  The cold air that has cooled the vegetable compartment 6 flows into the lower part of the cooler storage chamber 8 through the vegetable compartment return port 6d (see FIG. 2), which is not shown in FIGS. 4 and 5, but the air volume is frozen. The flow field (hereinafter referred to as the flow of the cold air in the cooler storage chamber 8) indicates the state of the cool air flow in the cooler storage chamber 8 which is smaller than the air flow circulating in the temperature zone chamber and the air flow circulating in the refrigerator compartment 2. Since the flow field indicating the state is simply referred to as “flow field”), the description thereof is omitted here.

  When both the refrigerator compartment damper 20 and the freezer compartment damper 50 are open and the refrigerator temperature zone chamber and the refrigerator temperature zone chamber are cooled at the same time, the flow of the return cold air from the refrigerator temperature zone chamber and the refrigerator temperature zone chamber Since the flow of the return cold air from each other influences each other, the flow of the cold air in the cooler storage chamber 8 becomes a complicated flow field. However, the flow C of the return cold air from the freezing temperature zone chamber shown in FIG. 5 is a flow field in which the flow D of the return cold air from the refrigerator compartment 2 shown in FIG.

  Not only in the configuration of the refrigerator 1 of the present embodiment, but also in the cold air forced circulation type refrigerator that cools the refrigeration temperature zone chamber and the refrigeration temperature zone chamber by the common cooler 7, the cooler storage chamber 8 for each return cold air. The cooler storage chamber in which the return cold air from the freezing temperature zone chamber and the return cold air from the refrigerating temperature zone chamber are formed because the inflow location, the inflow direction (angle) to the cooler storage chamber 8, the air volume, etc. are different. The flow field in Fig. 8 is between the case where only the refrigeration temperature zone chamber is cooled, the case where only the refrigeration temperature zone chamber is cooled, and the case where the refrigeration temperature zone chamber and the refrigeration temperature zone chamber are cooled simultaneously. Generally, it will be different.

  On the other hand, when considering the temperature and humidity environment in the refrigerator 1, the absolute temperature is generally higher in a refrigerated temperature zone room having a higher temperature than in a refrigeration temperature zone room having a lower temperature. Moisture that is the source of frost on the water 7 is mainly carried from the refrigerated temperature zone. From this, in the refrigerator 1 of this embodiment, frosting tends to occur around the region B shown in FIG. In the case of this frosting state, when the compressor 24 (see FIG. 2) is stopped, the cold air circulation to the freezing temperature zone chamber is shut off and air is sent to the refrigerated temperature zone chamber by the internal fan 9 to perform defrosting. (For example, the technique described in Patent Document 2), the location where frost formation is likely to occur coincides with the location where the flow formed during defrosting flows easily, so that the frost is easy to melt and the efficiency of defrosting is increased.

  However, even if the user does not use the unique refrigerator 1, there may be a condition that deviates from the temperature and humidity environment of the normal refrigerator described above.

  For example, when trying to freeze and store a large amount of normal temperature fish or meat in the freezing temperature zone, or a minute gap is generated between the door 3a, 4a, 5a of the freezing temperature zone and the heat insulating box 10 Nevertheless, this occurs when the door sensor cannot detect the open state of the doors 3a, 4a, 5a, the alarm is not notified, and the user does not notice the situation. As an example of the latter, the doors 3a, 4a, 5a are in a state where fine food residue is sandwiched between the doors 3a, 4a, 5a of the freezing temperature chamber and the front surface of the edge of the opening of the heat insulation box 10. It is possible that is closed. In this case, since the doors 3a, 4a and 5a are basically closed, the alarm function does not operate and the user cannot know that there is a gap in the door, so the next doors 3a, 4a and 5a The operation of the refrigerator 1 is continued in a state in which a gap is generated until the opening and closing of is performed.

  In the state as described above, a large amount of moisture that causes frost formation on the cooler 7 is also transported from the freezing temperature zone chamber to the cooler storage chamber 8. Therefore, frost formation occurs in a large amount in almost the entire width of the lower part of the cooler 7 due to the influence of the inflow from the freezer return port 17 having a dimension substantially equal to the cooler width dimension L.

  On the other hand, when the compressor 24 is stopped, the cold air circulation to the refrigeration temperature zone chamber is interrupted, and air is blown to the refrigeration temperature zone chamber by the internal fan 9 to perform defrosting effectively. As described above, the region to be returned is the region B shown in FIG. 5 in which the return cold air from the refrigeration temperature zone is easy to flow. Therefore, the region shown in FIG. 5 is hardly affected by the flow of the return cold air from the refrigeration temperature zone. The frost near A is difficult to thaw.

  Therefore, since the frost in the vicinity of the area A is not easily melted, the defrosting time is extended, and during the defrosting, the temperature of the freezing temperature zone that continues to receive heat intrusion from the outside of the chamber rises significantly, There was a possibility that the frozen food could be thawed.

  Furthermore, even though frost remains in the vicinity of the region A, depending on the installation location of the cooler temperature sensor provided in the cooler 7, it is erroneously determined that the defrosting is finished due to the rise in the detected temperature, The normal operation is resumed with frost remaining in the cooler 7, the efficiency of heat exchange in the cooler 7 is lowered, and the energy saving performance is deteriorated. Eventually, there was a possibility that the cooling capacity was insufficient, and the temperature inside the refrigerator 1 could not be maintained at a predetermined value.

  Next, the cause of erroneously determining the end of defrosting in the prior art will be described below. The flow of air circulating through the refrigerated temperature zone is such that, as the frost in the vicinity of the region B in FIG. Will do. Therefore, the amount of air flowing through the region with little frost increases with the passage of time, and the amount of heat exchange with the frost decreases, so the circulating air temperature may rise even if frost remains in the vicinity of region A. is there. Even if the cooler temperature sensor 35 is installed on the upper part of the cooler 7 in which the frost of the cooler 7 generally tends to remain at the time of defrosting, for example, due to the increase in the air temperature, the cooler temperature at that position is increased. Based on this, the control board 31 (see FIG. 3) may determine that the defrosting has been completed.

  Such inconvenience is described in Patent Document 2 and Patent Document 3, for example, when the compressor 24 is stopped, the freezer damper 50 is closed, and the cold air circulation to the freezer temperature zone is shut off. This may occur even when the heater 22 is energized and air is blown into the refrigerated temperature zone by the internal fan 9. This is because even if the defrosting heater 22 is energized, since the air is blown, the defrosting effect due to the radiation from the defrosting heater 22 is reduced, and the frost near the area A in FIG. is there.

The reason why the defrosting effect due to radiation from the defrosting heater 22 is reduced is as follows. It is known that the amount of heat transfer Q _rad by radiation is proportional to the fourth power difference (T ₁ ⁴ −T ₂ ⁴ ) between the high temperature surface T ₁ and the low temperature surface temperature T ₂ , as shown in the following equation (1).

Q _rad ∝ (T ₁ ⁴ -T ₂ ⁴ ) (1)
On the other hand, the temperature T _surf the calorific value Q is constant of the object surface, as shown in the following equation (2), the heat transfer coefficient h of the temperature T _air and the heat transfer area S _A is the surface of the object if the same air The larger the value, the lower.

T _surf = T _air + (Q / (h · S _A )) (2)
In general, the heat transfer coefficient h increases as the wind speed of the wind flowing through the object surface increases. Therefore, the heat transfer rate h is higher in the blown state than in the state where no blown air is supplied. From the above, even if the amount of heat generated by the defrost heater 22 is the same, when the air is blown, the temperature of the surface of the defrost heater 22 is lower than that when no air is blown from Equation (2). If the surface temperature of the defrosting heater 22 is reduced, the defrosting effect due to radiation is reduced because the amount of heat transfer due to radiation decreases when the low-temperature surface temperature (here, the frost surface temperature) is the same.

  In the refrigerator of this embodiment, since the upper cover 53 exists between the defrosting heater 22 and the cooler 7, the defrosting effect due to radiation is further reduced.

  For the above reasons, for example, when the compressor 24 is stopped as described in Patent Document 2 and Patent Document 3, the defrost heater 22 is energized while the cold air circulation to the refrigeration temperature zone chamber is shut off, When the method of blowing air to the refrigerated temperature zone by the blower 9 is adopted, the area A in FIG. 5 is not sufficiently defrosted by radiation, and as described in [Problems to be Solved by the Invention] The air flow circulating through the refrigerated temperature zone may not be sufficiently defrosted and the energy saving performance deteriorates. Eventually, there was a possibility that the cooling capacity was insufficient and the internal temperature could not be maintained at a predetermined value.

  Next, the defrosting method of the refrigerator 1 of this embodiment is demonstrated, referring FIGS. 6-10.

  FIG. 6 is a diagram for explaining the defrosting mode, and FIGS. 7 to 10 are flowcharts showing the flow of the defrosting control. FIG. 10 shows a defrosting heater, an internal fan, a cold room damper during defrosting, It is a time chart which shows the operating state of a freezer compartment damper and a compressor, and a figure explaining change of refrigerator temperature, freezer compartment temperature, and cooler temperature.

  In the following description, the state where the compressor 24 is operating is “compressor ON”, the state where the compressor 24 is stopped is “compressor OFF”, and the state where the internal fan 9 is operating. The state in which the internal fan 9 is stopped, the state in which the internal fan 9 is stopped is “internal fan OFF”, the state in which the defrost heater 22 is energized is “defrost heater ON”, and the defrost heater 22 is energized. The state where the defrost heater is not turned on, the refrigerator compartment damper 20 is in the open state, and the state where the air can be sent to the refrigerator compartment is "refrigerator compartment damper open", the refrigerator compartment damper 20 is in the closed state, and the refrigerator temperature The state where the ventilation to the belt room is blocked is “refrigeration room damper closed”, the freezing room damper 50 is open, and the state where the air blowing to the freezing temperature zone is possible is “freezing room damper open”, the freezing room damper 50 Is closed and the state where the air flow to the freezer compartment is shut off Referred to as.

  In addition, a plurality of cooling operation modes are prepared as normal cooling operation modes of the refrigerator 1, and the states of “compressor ON, internal fan ON, refrigerator compartment damper open, freezer compartment damper closed, defrost heater OFF” The state of “refrigeration room cooling operation” mode, “compressor ON, internal fan ON, cold room damper closed, freezer damper open, defrost heater OFF” is “freezer cooling operation” mode, “compressor ON, warehouse” The state in which the inner fan is ON, the refrigerator compartment damper is open, the freezer compartment damper is open, and the defrost heater is OFF is referred to as a “refrigeration compartment / freezer compartment simultaneous cooling operation” mode.

  Here, the normal cooling operation refers to control (ON / OFF control) of the compressor 24, the internal fan 9, and the external fan based on the temperatures detected by the refrigerator temperature sensor, the freezer temperature sensor, and the outside air temperature sensor. And the rotation speed control) and the open / close state control of the refrigerator compartment damper 20 and the freezer compartment damper 50, each room has a predetermined temperature (for example, the refrigerator compartment is about 3 ° C, the vegetable compartment is about 5 ° C, and the freezer compartment is -18). The operation is maintained at about ℃.

  In the following description of the defrosting method, the vegetable compartment 6 is treated as a part of the refrigerated compartment 2, and the explanation regarding the vegetable compartment 6 is omitted.

  As shown in FIG. 6, the refrigerator 1 of the present embodiment includes three modes of defrost modes 4 to 6 as modes in the defrost operation. Among these defrosting modes, as shown below the table in FIG. 6, “defrost heater of“ compressor OFF, internal fan OFF, refrigerator colder damper close, freezer damper close, defrost heater ON ” The defrosting mode 6 for performing “defrosting by” corresponds to “third defrosting means” recited in the claims.

  The defrosting mode 4 is followed by the defrosting mode 3 (second defrosting means) and the defrosting mode 6 (third defrosting mode) after the defrosting operation in the defrosting mode 1 (first defrosting means). The defrosting mode 5 is a mode in which the defrosting operation is performed by the defrosting mode), and the defrosting mode 5 is performed after the defrosting operation by the defrosting mode 3 (second defrosting unit), followed by the defrosting mode 6 (third defrosting unit). ) To perform the defrosting operation.

  Thus, the mode of the defrosting operation in the refrigerator 1 of the present embodiment is set to the defrosting mode by combining all or a part of the first to third defrosting means.

  The defrost mode 4 in this embodiment corresponds to the first defrost mode in the claims, and the defrost modes 4 and 5 correspond to the second defrost mode in the claims.

  As shown in the “conditions before defrosting” column in the table of FIG. 6, the cooling operation mode of the refrigerator 1 before the start of the defrosting operation applied to the defrosting modes 4 to 6, the freezer room temperature, and the refrigerator room temperature. The conditions for temperature are different. Moreover, the combination of the defrosting means 1-3 is described in the "Defrost" column of the table | surface of FIG. 6 so that each defrost mode can be understood easily. Furthermore, as shown in the “defrosting completion determination condition” column in the table of FIG. 6, the defrosting modes 1 to 6 are for any freezing room temperature, refrigerating room temperature, or cooler temperature defrosting completion determination temperature condition. Indicates whether each defrosting mode is completed. For example, even when the determination is made based on the freezer temperature, the temperature values applied in each mode are different.

  Here, the condition of the cooler temperature shown in the “defrosting completion determination condition” column of the table of FIG. 6 corresponds to the defrosting completion determination temperature described in the claims.

  Details of the pre-defrost condition and the defrost completion determination condition will be described in the description of the flowchart described later.

<Control flow for defrosting operation>
Next, the control flow of the defrosting operation will be described with reference to FIGS. This control is performed by the CPU of the control board 31 (see FIG. 2) executing a program stored in the ROM.

  As shown in FIG. 7, the refrigerator is started to operate when the power is turned on (start), and FLAGi = 0 is set as an initial condition (step S100).

  Here, FLAGi is a flag indicating that the defrosting mode 4 has been selected as will be described later, and the freezing room temperature has risen too much during the defrosting operation in the defrosting mode 4, and the defrosting operation is interrupted. It is also a flag indicating that the freezing room cooling operation or the like is temporarily performed and the mode is shifted to another defrosting mode.

  Then, a normal cooling operation is performed (step S101). In step S102, it is checked whether the normal cooling operation mode is “freezer compartment cooling operation” and the freezer compartment temperature is lower than −21 ° C. In the “freezer compartment cooling operation” mode and the freezer compartment temperature is lower than −21 ° C. (Yes), the process proceeds to step S103. Otherwise (No), the process returns to step S101 and the normal cooling operation is continued.

  Since the normal cooling operation has three types of cooling operation modes as described above, when the normal cooling operation is continued, in addition to continuing the “freezer compartment cooling operation” mode, the normal cooling operation is based on the refrigerator compartment temperature and the freezer compartment temperature. In some cases, the mode is switched to two types of cooling operation modes other than the “freezer compartment cooling operation” mode (“refrigeration compartment cooling operation” mode and “refrigeration compartment / freezer compartment simultaneous cooling operation” mode). For example, when a user puts food having a relatively high temperature into the refrigerator compartment 2, the “freezer compartment cooling operation” mode is switched to the “refrigerator compartment cooling operation” mode, and the refrigerator compartment 2 is quickly brought to a predetermined temperature. After cooling, the mode is again shifted to the “freezer cooling operation” mode.

  If the freezer temperature is lower than −21 ° C. in step S102, it is subsequently determined whether or not the conditions for defrosting are satisfied (step 103). In the present embodiment, whether or not the defrosting condition is satisfied depends on the accumulated operation time of the compressor 24 after the completion of the previous defrosting operation, the operating rotational speed of the compressor 24, and the temperature and humidity environment outside the chamber. It is determined based on (outside air temperature, outside air humidity (relative humidity)). This condition is stored in advance in the form of table data in the ROM using the outside air temperature, the outside air chamber, the accumulated operation time, and the operating rotational speed as parameters, and is determined by referring to this data table. For example, if the conditions are an outside air temperature of 30 ° C. and a relative humidity of 70%, the conditions for performing defrosting approximately once a day are satisfied.

  In step S103, when the condition for performing defrosting is satisfied (Yes), the process proceeds to step S201, and when the condition for performing defrosting is not satisfied (No), the process returns to step S101 and the normal cooling operation is continued.

<Defrost mode 4>
In step S103 of FIG. 7, when the condition for performing defrosting is satisfied (Yes), the process proceeds to step S201 of FIG. 8 according to the code (1) and stores FLAGi = 1.

  Next, the defrosting mode 4 is selected (step S202), and it is checked whether the “freezing room cooling operation”, which is a condition for starting the defrosting operation in the defrosting mode 4, and whether the temperature in the refrigerator compartment is higher than 5 ° C. (step S203). ). If the “freezer operation cooling operation” and the temperature of the refrigerator compartment is higher than 5 ° C. (Yes), the process proceeds to step S204. If not (No), step S203 is repeated.

  As shown in FIG. 6, the defrosting mode 4 is started when the temperature of the refrigerator compartment becomes higher than 5 ° C. during the “freezer cooling operation” mode. Since “operation” is performed, even if the defrosting mode 4 is selected in step S202, the normal cooling operation mode of the “freezer cooling operation” continues until the refrigerator compartment temperature becomes higher than 5 ° C.

  When the process proceeds from step S203 to step S204, the defrosting operation by the first defrosting means, which is the first stage defrosting operation in the defrosting mode 4 (“compressor OFF, internal fan ON, refrigerator compartment damper open, freezing Close the room damper and turn off the defrosting heater. In step S205, it is checked whether FLAGi = 2. If FLAGi = 2 (Yes), the process proceeds to step S208. If FLAGi ≠ 2 (No), the process proceeds to step S206. Here, since FLAGi = 1 is stored in step S201, FLAGi = 2 is not satisfied, and the process proceeds to step S206.

  In step S206, it is checked whether or not the freezer temperature is higher than −10 ° C. If the freezer temperature is higher than 10 ° C. (Yes), the process proceeds to step S301. If not (No), the process proceeds to step S207. In step S207, it is checked whether or not the temperature difference between the refrigerator temperature and the cooler temperature (refrigerator temperature-cooler temperature) is lower than 2 ° C. If the temperature difference is lower than 2 ° C (Yes), step S207 is performed. It progresses to S208, and when that is not right, it returns to step S206, and the check of step S206, S207 is repeated, continuing the defrost operation by a 1st defrost means.

  Here, -10 degreeC of the freezer compartment temperature in step S206 respond | corresponds to the freezer compartment temperature zone upper limit temperature as described in a claim.

  In step S208, the defrost heater 22 is turned on and its output is set to 80 W (defrost heater ON (80 W)). By turning on the defrost heater 22 in step S208, the state of the defrosting operation by the second defrosting means (defrosting by the internal fan + defrosting heater: “compressor OFF, internal fan ON, refrigerator compartment” Damper open, freezer compartment damper close, defrost heater ON ”).

  In step S209, it is checked whether the freezer temperature is higher than −10 ° C. When the freezer temperature is higher than −10 ° C. (Yes), the process proceeds to step S301 in FIG. 9 according to reference numeral (4), and when the freezer temperature is −10 ° C. or lower (No), the process proceeds to step S210.

  In step S210, it is checked whether or not the refrigerator compartment temperature is lower than the cooler temperature. If the refrigerator compartment temperature is lower than the cooler temperature (Yes), the process proceeds to step S211 and the refrigerator compartment temperature is equal to or higher than the condenser temperature. In the case (No), the process returns to step S209 again, the defrosting operation by the second defrosting means is continued, and the checks in steps S209 and S210 are repeated.

  Here, −10 ° C. of the freezer temperature in step S209 corresponds to the freezer compartment temperature zone upper limit temperature described in the claims, and the refrigerator temperature in step S210 is lower than the cooler temperature (refrigerator temperature <cooler temperature). ) Corresponds to “predetermined first cooler temperature at which the cooler temperature is 0 ° C. or higher” recited in the claims.

  If the refrigerating room temperature is lower than the cooler temperature (Yes) in step S210 and the process proceeds to step S211, the internal fan is turned off, the refrigerating room damper is closed, and the defrost heater output is changed from 80W to 160W. Thereby, it will be in the state of the defrost driving | operation by a 3rd defrosting means. Moving to FIG. 9, in step S212, it is checked whether or not the freezer temperature is higher than −10 ° C. If the freezer temperature is higher than −10 ° C. (Yes), the process proceeds to step S301. If the freezer temperature is −10 ° C. or lower (No), the process proceeds to step S213, and whether the cooler temperature is higher than 8 ° C. Check whether or not. When the cooler temperature is higher than 8 ° C. (Yes), the process proceeds to step S214. When the cooler temperature is 8 ° C. or lower (No), the process returns to step S212, and the defrosting operation by the third defrosting means is performed. And the checks in steps S212 and S213 are repeated.

  Here, −10 ° C. of the freezer temperature in step S212 corresponds to the upper limit temperature of the freezer temperature zone described in the claims, and the cooler temperature in step S213 is higher than 8 ° C. (cooler temperature> 8 ° C.). This corresponds to “when the temperature rises to the predetermined second cooler temperature” described in the claims.

  In step S213, if the process proceeds to Yes in step S214, the defrosting operation in the defrosting mode 4 ends, and the defrosting heater 22 is turned off (defrosting heater OFF). Thereby, it will be in the state of "compressor OFF, internal fan OFF, refrigerator compartment damper closed, freezer compartment damper closed, defrost heater OFF". In step S215, it is checked whether or not 5 minutes have elapsed after turning off the defrosting heater 22 (5 minutes after turning off the defrosting heater 22?). If not (No), step S215 is executed. If 5 minutes have elapsed (Yes), the compressor 24 is turned on (step S216, the compressor is turned on). Thereby, it will be in the state of "compressor ON, internal fan OFF, refrigerator compartment damper closed, freezer compartment damper closed, defrost heater OFF".

  In step S217, it is checked whether 2 minutes have passed since the compressor 24 was turned on. If not (No), step S217 is repeated, and if 2 minutes have passed (Yes), the process returns to step S101 (see FIG. 7) and returns to the normal cooling operation again (2 minutes after the compressor is turned on?).

(Operational effect of defrost mode 4)
The flow from step S201 to step S217 described above is an explanation when the defrosting condition is satisfied and the defrosting operation in the defrost mode 4 is performed.

  Below, the effect is demonstrated, referring the flowchart of FIG. 8, FIG. 9, and the time chart in the defrost operation by the defrost mode 4 of FIG. In FIG. 10, the section of “freezer cooling operation” after the defrosting mode 4 is selected, the section TA of the defrosting operation by the “first defrosting means”, and the “second defrosting means”. It is divided into a section TB for defrosting operation, a section TC for defrosting operation by the “third defrosting means”, a section TD, TE after the completion of the defrosting operation, and a section for “normal cooling operation”. Transition of room temperature, freezer room temperature and cooler temperature, ON state (ON 160W) / ON state (ON 80W) / OFF (OFF) state of the defrost heater 22, ON (ON) / OFF ( OFF) state, refrigerator compartment damper 20 open / closed state, internal fan 9 ON (ON) / OFF (OFF) state, freezer compartment damper 50 open / closed state, compressor 24 ON (ON) State / OFF (OFF) state is shown.

  As shown in FIG. 10, when the defrost mode 4 is selected, the freezer compartment cooling operation is performed until the refrigerator temperature exceeds 5 ° C. before entering the defrost operation in the defrost mode 4 (step S203). When the refrigerator temperature exceeds 5 ° C., the defrosting operation by the first defrosting means (“compressor OFF, internal fan ON, refrigerator refrigerator damper, freezer damper damper, defrost heater OFF”) is performed. (Steps S204 to S207).

  This is because, when frost is released by blowing air to the refrigerator compartment 2 by the internal fan 9, it is easier to exchange heat with the frost attached to the cooler 7 when the temperature of the refrigerator compartment 2 is as high as possible. In this case, the temperature of the refrigerator compartment 2 is raised in advance, and the energy saving effect is enhanced. In addition, since the freezer compartment cooling operation is performed while the refrigerator compartment 2 waits for the temperature to rise due to heat intrusion from the outside of the refrigerator, the freezer compartment that tends to rise in temperature due to heat intrusion from outside the compartment during defrosting is removed. It can be sufficiently cooled before frost, and has the effect of reducing the possibility of problems such as freezing of frozen food during defrosting.

  As the first stage in the defrosting mode 4, when the defrosting operation by the first defrosting means is performed, the refrigerator compartment temperature is cooled by the cold heat of the frost, as shown in the section TA in FIG. The cooler temperature (frost temperature) rises due to the heat load of the refrigerator compartment, and the difference from the cooler temperature gradually decreases. When the temperature difference between the refrigerator temperature and the cooler temperature becomes small, heat exchange becomes difficult. Therefore, when the defrosting operation by the first defrosting means is continued as it is, the defrosting time becomes long. On the other hand, as shown in FIG. 10, the temperature of the freezer compartment continues to rise during defrosting.

  Therefore, if the defrosting time is long, there is a possibility that the frozen food can be dissolved, which is not desirable. Therefore, when it is determined that the temperature difference between the refrigerator temperature and the cooler temperature is small ((refrigerator temperature− (When the cooler temperature) <2 ° C. is satisfied) (step S207), the defrost heater 22 is turned on so that the defrost time is not prolonged (step S208), thereby returning the return air from the refrigerator compartment 2 Heat and make it easier to defrost. This “compressor OFF, internal fan ON, refrigerator compartment damper open, freezer compartment damper closed, defrost heater ON” state is the defrosting operation by the second defrosting means in the section TB in FIG. This is a state in which “defrosting by the inner blower + defrosting heater” is performed (steps S208 to S210). The output of the defrost heater 22 in the second defrosting means is 80 W. If this output is in a state where frost remains in the cooler 7, the air after passing through the cooler 7 cools the refrigerator compartment 2. Is an output with a temperature of about 0 to 4 ° C.

  Further, the rotation speed of the internal fan 9 during the normal cooling operation is about 1600 rpm, and is about 1400 rpm during the defrosting operation by the second defrosting means in the section TB. In this way, the rotation speed of the internal fan 9 is changed from that in the normal cooling operation during the defrosting operation by the second defrosting means because the air temperature of about 0 to 4 ° C. that can cool the refrigerator compartment 2 is changed. It is for adjusting so that it may be obtained.

  Thus, since the defrost operation by the 2nd defrosting means of the refrigerator 1 of this embodiment is adjusted so that the air temperature of about 0-4 degreeC which can cool the refrigerator compartment 2 is obtained, patent For the purpose of humidification disclosed in Document 2 and Patent Document 3, “use of compressor OFF, internal fan ON, refrigerator compartment damper open, freezer compartment damper closed, defrost heater ON” The problem that the energy-saving performance is reduced because the possible frost heat cannot be reused for cooling the refrigerator compartment can be solved, and the energy-saving performance is improved.

  If the output of the defrost heater 22 in the defrosting operation of “defrosting by the internal fan + defrost heater” is excessive, the air temperature after passing through the cooler higher than the temperature to be kept in the refrigerator compartment 2 is obtained. This is not preferable because the refrigerator compartment 2 is heated. In addition, since the defrosting operation by the second defrosting means is intended to suppress an increase in freezer temperature by shortening the defrosting time, this purpose is achieved if the output of the defrosting heater 22 is too small. Not. Therefore, the output of the defrost heater 22 in the second defrosting means must be appropriate. As an effect of the second defrosting means, although the defrost heater 22 is turned on as well as suppressing the rise in the freezer temperature, the frost is defrosted while cooling the refrigerator room 2 (using the heat load of the refrigerator room 2). Therefore, the amount of energy input from the outside for defrosting can be reduced by the amount using the heat load of the refrigerator compartment 2, and an energy saving effect can be obtained. Furthermore, since the return air from the refrigerator (refrigeration room return air indicated by arrow D in FIG. 5) is forced to convection to the cooler 7 by blowing, heat transfer efficiency between the air and frost is good. There is also an energy saving effect due to the fact that frost can be easily melted.

  Thus, by combining the defrosting operation by the second defrosting means after the defrosting operation by the first defrosting means, an energy saving effect at the time of the defrosting operation is obtained while shortening the defrosting time. be able to.

  Subsequently, when the temperature of the refrigerating room becomes equal to or lower than the temperature of the cooler (step S210), the internal fan is turned off and the refrigerating room damper is closed, and the output of the defrost heater 22 is changed from 80 W to 160 W (step S211). Thus, in the section TC of FIG. 10, the defrosting operation by the third defrosting means, “defrosting by the defrosting heater” is performed (step S211 to step S213). When the refrigerator temperature falls below the cooler temperature, the cooling heat of the cooler 7 does not have the ability to cool the refrigerator 2 and if the air is further blown, the refrigerator 2 will be warmed. , “Defrosting by the defrosting heater” is performed to prevent the refrigerator compartment 2 from being warmed, and the cooler 7 is made free from unmelted frost.

  Since the defrost mode 4 is intended for defrosting to ensure reliability, it is necessary to prevent the frost from remaining unmelted. As described above, the first defrosting mode in the “internal fan ON” state is required. Only by the defrosting operation by the frosting means or the second defrosting means, a portion where the frost is difficult to be melted is generated, and the unmelted frost may be generated. Therefore, when performing reliable defrosting, as shown in section TC of FIG. 10 after defrosting in the “inside fan ON state” of the first defrosting means and the second defrosting means. In addition, “defrosting by a defrosting heater” is performed so that there is no remaining frost.

  In the present embodiment, the output of the defrost heater 22 is increased from 80 W to 160 W in the defrosting operation by the third defrosting means. Thereby, section TC of the defrosting operation by the 3rd defrosting means can be shortened, and the rise of the refrigerator compartment temperature and freezer compartment temperature in the meantime can be suppressed small.

  In addition, the defrosting operation by the third defrosting means has a lower heat transfer efficiency due to natural convection between the air and frost in the cooler housing chamber 8 than the defrosting in the blown state, and the energy saving performance is low. It is a frost means. However, in this embodiment, the defrosting operation by the third defrosting means is performed from the state that almost all the frost has been dissolved, that is, the cooler temperature is higher than the refrigerator temperature maintained at the plus temperature. Therefore, the influence of the reduction in energy saving performance due to the defrosting operation by the defrosting means 3 is relatively small.

  As described above, in the defrosting mode 4, by combining the defrosting operations by the first to third defrosting means, it is possible to perform defrosting that is flexible and energy saving, and shortens the defrosting time. In the meantime, the freezer compartment temperature is prevented from rising during that time.

  Next, when the cooler temperature exceeds 8 ° C. (step S213), the defrosting heater 22 is turned off and the defrosting operation in the defrosting mode 4 is ended (step S214), as shown by the section TD in FIG. , And waits for 5 minutes in the state of “compressor OFF, internal fan OFF, refrigerator compartment damper close, freezer compartment damper close, defrost heater OFF” (step S215). By the section TD of this progress, the dripping time from the cooler 7 of the defrost water and the upper cover 53 (see FIG. 5) to the eaves 23 (see FIG. 5) is secured, and the normal cooling operation is resumed in the middle of the dripping again. It is difficult for a situation such as freezing and blocking of a part of the cooler storage chamber 8 to occur.

  In addition, the defrosting operation by the third defrosting unit shown in FIG. 6 is not included so that the defrosting operation by the third defrosting unit is terminated when the cooler temperature exceeds 8 ° C. in step S213. Since the defrosting completion determination temperature (cooler temperature> 0.5 ° C.) in the defrosting mode is set at a relatively high temperature, substantially complete defrosting can be performed.

  After 5 minutes of the elapsed section TD have elapsed, as shown in the elapsed section TE of FIG. 10, first, only the compressor 24 is turned ON (“compressor ON, internal fan OFF, defrost heater OFF, refrigeration. Chamber damper closed, freezer compartment damper ") (step S216), wait for 2 minutes (step S217), and then resume normal cooling operation. The waiting time of 2 minutes is such that the cooler 7 whose temperature is high when the defrosting operation in the defrosting mode 4 is finished and the surrounding air are sent to the respective chambers as they are, and This is to make it difficult for the problem of warming the chamber to occur, and is usually provided to cool the interior of the cooler housing chamber 8 before resuming the cooling operation.

  As described above, the operation when the defrosting condition 4 is satisfied and the defrosting mode 4 is performed has been described. In the defrosting mode 4, the defrosting operation is performed by the first defrosting unit. , A step of checking the freezer temperature is provided at each stage of the defrosting operation by the second defrosting means and the defrosting operation by the third defrosting means (step S206, step S209 and step S212), If it is determined in those steps that the temperature of the freezer compartment is significantly increased (the freezer compartment temperature is higher than −10 ° C.), the defrost mode 4 is shifted to the defrost mode 5.

(Transition from defrost mode 4 to defrost mode 5)
9 again, during the defrosting operation in the defrosting mode 4, in step S206, step S209, or step S212, the freezer temperature becomes higher than −10 ° C., and the process proceeds to step S301. The case where it transfers to the defrost by the defrost mode 5 from the defrost mode 4 is demonstrated.

  In step S301, it is checked whether or not the cooler temperature is higher than 5 ° C. If the cooler temperature is higher than 5 ° C (Yes), the process proceeds to step S302, and if not (No), the process proceeds to step S305. move on.

  In step S302, the state is "internal fan OFF, refrigerator compartment damper closed, freezer compartment damper closed, defrost heater OFF", and "compressor ON" is set (step S303). In step S304, it is checked whether or not two minutes have elapsed since the compressor was turned on (ON). If two minutes have elapsed (Yes), the process proceeds to step S305, and if not (No), step S305 is performed. S304 is repeated. In step S305, it is checked whether FLAGi = 1. If FLAGi = 1 (Yes), the process proceeds to step S306. If not (No), the process proceeds to step S401.

  Here, since FLAGi = 1 is stored in step S201, the answer is Yes and the defrosting mode 5 is selected (step S306).

  Further, when the cooler temperature is higher than 5 ° C. in step S301, only the compressor is turned on in step S303, and then waiting for 2 minutes is performed before the cooling operation is started. This is because by cooling the inside of the storage chamber 8, the high temperature air in the cooler storage chamber 8 is sent as it is to each chamber in the cabinet, and the problem of heating each chamber in the cabinet is less likely to occur.

  The defrosting operation in the defrosting mode 5 is set to start when the freezer temperature becomes lower than −25 ° C. during the freezer cooling operation as shown in FIG. Thus, the freezer compartment cooling operation is once started (step S307), and it is checked in step S308 whether or not the freezer compartment temperature is lower than −25 ° C. In the freezer compartment cooling operation, the freezer compartment temperature is lower than −25 ° C. If not (No), the process returns to step S307 and continues until the freezer temperature is lower than −25 ° C. (step S308). When the freezer temperature is lower than −25 ° C. in step S308 (Yes), the process proceeds to step S309, stores FLAGi = 2, moves to step S204 (see FIG. 8), and is performed by the first defrosting means. The defrosting operation, “defrosting by the internal fan” is performed, and then it is checked whether or not FLAGi = 2 (step S205).

  Here, since FLAGi = 2 is stored in step S309, the process proceeds to step S208, and the defrosting operation by the second defrosting unit is performed without performing the defrosting operation by the first defrosting unit. "Defrosting with internal blower + defrosting heater" is performed. Thereafter, in step S209 or step S212, the normal cooling operation is returned to the normal cooling operation through the steps already described except when the freezer temperature is again satisfied to be higher than −10 ° C. (Yes).

(Operational effect of defrost mode 5)
In the middle of the defrosting operation in the defrosting mode 4, the cause of the remarkable increase in the freezer temperature in either step S 206, step S 209, or step S 212 is that the user accidentally creates the ice making room 3 or the upper stage. It is conceivable that the freezer 4 and the lower freezer 5 are opened and closed, and food with relatively high temperature is stored. However, the amount of frost is large and it takes too long to defrost, or the lower The return cold air from the freezer compartment 5 carries a large amount of moisture to the cooler storage compartment 8, and frost is generated in places where it is difficult to defrost in the defrosting operation with the internal fan 9 operating. It is considered that there is a large amount of frost, the defrosting time is extended by the influence of the frost, and the freezer temperature becomes higher than −10 degrees.

  In any case, there is a possibility that the frozen food stored in the upper freezer compartment 4 or the lower freezer compartment 5 can be dissolved. Step S307 for recooling is provided, and the upper freezer compartment 4 and the lower freezer compartment 5 are cooled to a low temperature. This eliminates the possibility that the frozen food stored in the upper freezer compartment 4 and the lower freezer compartment 5 can be dissolved while the reliability defrosting is being performed. Moreover, in the process of the defrost mode 4, when the cause of the remarkable increase in freezer temperature is that the amount of frost is large and the defrost time is too long, it is desirable to shorten the defrost time.

  Therefore, in the defrost mode 5, the defrost mode by the 1st defrost means in the defrost mode 4 and step S204 in which "defrost by an internal fan" is implemented do not pass through 2nd. The defrosting operation by the defrosting means, “defrosting by the internal fan + defrost heater” is started (step S208). Since the 2nd defrosting means adds the effect which turns on the defrost heater 22 compared with a 1st defrosting means, if it is the same amount of frost, it can defrost in a short time. As a result, the defrosting mode 5 can reduce the defrosting time, and the longer the defrosting time, the less the trouble caused by the temperature increase in the ice making chamber 3, the upper freezing chamber 4, and the lower freezing chamber 5 is less likely to occur. Defrosting operation with high performance.

  In addition, even if the step of the defrosting operation by the first defrosting unit is omitted, the energy saving effect by performing the defrosting operation by the second defrosting unit can be obtained. As a result, the energy saving performance is not significantly deteriorated.

(Defrost mode 6)
Next, the case where FLAGi = 1 is not set in step S305 (No) and the process proceeds to step S401 and the defrost mode 6 is selected will be described.

  As shown in FIG. 6, the defrosting in the defrosting mode 6 is performed in a normal cooling operation (freezing room cooling operation, refrigerating room cooling operation, or freezing room / refrigeration room simultaneous cooling operation), and the freezer temperature is lower than −25 ° C. And when the refrigerator compartment temperature is lower than 2 ° C., the normal cooling operation is once started in step S402, and in step S403, any one of the cooling operation modes, It is checked whether the freezer compartment temperature is lower than −25 ° C. and the refrigerator compartment temperature is lower than 2 ° C. If not satisfied (No), step S402 is continued and satisfied ( If yes, the process proceeds to step S404.

  In step S404, the defrosting operation by the third defrosting means, "defrosting by the defrosting heater", ("compressor OFF, internal fan OFF, refrigerator compartment damper closed, freezer compartment damper closed", defrosting is performed. The heater 22 outputs 160 W). Then, it returns to step S212, and returns to a normal cooling operation | movement through the step already demonstrated after that.

  In the process of defrosting mode 6, if the freezer temperature is higher than −10 ° C. again in step S212 (Yes), since FLAGi = 2 is still stored in step S309, defrosting mode 6 is set again. Will be implemented.

(Operational effect of defrost mode 6)
Next, when the temperature of the freezer compartment is remarkably increased from the defrost mode 5 again, an operation effect by shifting to the defrost mode 6 will be described.

  In the defrosting mode 4, the defrosting mode 4 is first performed, and when the temperature in the freezer compartment rises significantly in the process, the defrosting mode 5 is entered. When the increase is significant, the mode is shifted to the defrost mode 6. That is, the defrost mode 6 is performed when it is determined that the temperature increase in the freezer compartment is marked twice in the process of ensuring the reliability defrosting. Although the timing of opening and closing of 3a, 4a, 5a, 5b may coincide, defrosting operation in the operating state of the internal fan 9 (defrosting by the first defrosting means or the second defrosting means) In the operation), there is a high possibility that a lot of frost is formed in a place where defrosting is difficult.

  Therefore, in this embodiment, when it is determined that the temperature increase in the freezer compartment twice is significant, defrosting is difficult in the defrosting operation in the operating state of the internal fan 9 by shifting to the defrosting mode 6. Even if a lot of frost is generated in the place, the defrosting can be surely performed, so that the refrigerator is highly reliable.

  According to the present embodiment described above, a plurality of defrosting modes that combine the defrosting operations by the first to third defrosting means are set, the defrosting mode 4 is prepared, and the defrosting by the defrosting mode 4 is further performed. When the freezer temperature rises during the operation, the defrosting operation is interrupted, the normal cooling operation is resumed, and then the defrosting operation can be resumed by the defrosting modes 5 and 6. Therefore, energy saving performance and reliability can be achieved at the same time, and furthermore, there is no possibility that the temperature of the freezing temperature zone rises excessively during the defrosting operation and the stored items cannot be maintained within a predetermined temperature range and are unraveled. .

<Modification>
Next, a modification of this embodiment will be described.

  In the refrigerator 1 of the above-described embodiment, the rotational speed of the internal blower 9 is reduced during the defrosting operation by the second defrosting unit with respect to the normal cooling operation, which can cool the refrigerator compartment 2. Since it is for adjusting so that the air temperature of about 0-4 degreeC can be obtained, in the 1st modification, it is ensured that the air temperature of about 0-4 degreeC which can cool the refrigerator compartment 2 is obtained. For this purpose, at least one additional temperature sensor for detecting the temperature of the air flowing in the refrigerator compartment air duct 11 or the outlet 2c is provided, and the signal is input to the control board 31 (see FIG. 3). . And the control board 31 outputs the output of the defrost heater 22 so that it may become said air temperature of about 0-4 degreeC based on the signal from the said additional temperature sensor during the defrost operation by a 2nd defrost means. The configuration is adjusted.

  Further, in the second modification, in addition to the adjustment of the output of the defrost heater 22 at this time, the rotation speed of the internal fan 9 is also adjusted.

  As described above, in the first modification example or the second modification example, the temperature of the air flowing in the refrigerating chamber air duct 11 or the air outlet 2c is directly detected to adjust the output of the defrost heater 22 or rotate the internal fan 9. Since the speed is adjusted, the temperature of the refrigerator compartment during the defrosting operation by the second defrosting means can be reliably performed so that the refrigerator compartment temperature is maintained or lowered.

  Further, the output of the defrost heater 22 and the rotational speed of the internal fan 9 are flexibly changed in accordance with the change in the temperature of the air flowing in the refrigerator compartment air duct 11 after the start of the defrosting operation by the second defrosting means. Therefore, it is possible to flexibly cope with changes in the degree of heat exchange between frost and air according to the progress of defrosting in the cooler 7.

1 Refrigerator 2 Refrigerated room (refrigerated temperature zone)
3 Ice making room (freezing temperature zone)
4 Upper freezer room (freezing temperature room)
5 Lower freezer compartment (freezing temperature zone)
6 Vegetable room (refrigerated temperature room)
7 Cooler 8 Cooler storage chamber 9 Blower (blower)
DESCRIPTION OF SYMBOLS 10 Heat insulation box 11 Refrigerating room air duct 12 Upper stage freezer room air duct 13 Lower stage freezer room air duct 16 Refrigerating room return duct 17 Freezer room return port 20 Refrigerating room damper 22 Defrost heater 24 Compressor 50 Freezer room damper 53 Top cover

Claims (9)

At least a freezing temperature zone chamber, a refrigeration temperature zone chamber, a compressor, a cooler that cools the freezing temperature zone chamber and the refrigeration temperature zone chamber in common, and the cold air cooled by the cooler, the freezing temperature A blower that circulates between the belt chamber and the refrigeration temperature zone chamber, a freezer damper that controls the blower from the cooler to the refrigeration temperature zone chamber, and a refrigeration that controls the blower from the cooler to the refrigeration temperature zone chamber In a refrigerator comprising a room damper and a defrosting heater for defrosting frost adhering to the cooler,
When the compressor is stopped, the freezing chamber damper is closed, the refrigeration chamber damper is opened, the defrost heater is de-energized, and the blower is operated to perform defrosting. Means,
When the compressor is stopped, the freezing chamber damper is closed, the refrigeration chamber damper is opened, the defrost heater is energized, and the blower is operated to perform defrosting. When,
A third defrosting means for defrosting the compressor when the compressor is stopped, closing the freezer damper, closing the refrigerator compartment damper, energizing the defrost heater, and stopping the blower With
A plurality of defrosting modes for performing a defrosting operation by combining one or more of the first defrosting means, the second defrosting means, and the third defrosting means;
Wherein a plurality of defrosting mode by selecting one of the defrosting mode performing defrosting operation, then, the defrosting heater is energized state, have rows defrosting performing defrosting the fan as a stop state,
The selected defrost mode is for determining the completion of defrost according to the temperature of the cooler, and the defrost completion determination temperature for determining the defrost completion is different depending on the selected defrost mode, The defrosting completion determination temperature in the defrosting mode in which the defrosting operation by the third defrosting unit is performed is set higher than the defrosting completion determination temperature in the defrosting mode in which the third defrosting unit is not performed. refrigerator, characterized in that that. At least a freezing temperature zone chamber, a refrigeration temperature zone chamber, a compressor, a cooler that cools the freezing temperature zone chamber and the refrigeration temperature zone chamber in common, and the cold air cooled by the cooler, the freezing temperature A blower that circulates between the belt chamber and the refrigeration temperature zone chamber, a freezer damper that controls the blower from the cooler to the refrigeration temperature zone chamber, and a refrigeration that controls the blower from the cooler to the refrigeration temperature zone chamber In a refrigerator comprising a room damper and a defrosting heater for defrosting frost adhering to the cooler,
When the compressor is stopped, the freezing chamber damper is closed, the refrigeration chamber damper is opened, the defrost heater is energized, and the blower is operated to perform defrosting. When,
A third defrosting means for defrosting the compressor when the compressor is stopped, closing the freezer damper, closing the refrigerator compartment damper, energizing the defrost heater, and stopping the blower With
A plurality of defrosting modes for performing a defrosting operation by combining one or more of the first defrosting means, the second defrosting means, and the third defrosting means;
After the defrosting operation by the second defrosting means, it has a second defrosting mode for performing the defrosting operation by the third defrosting means,
In the second defrosting mode, the defrosting operation by the second defrosting means is such that the temperature of the cooler is higher than a predetermined first cooler temperature of 0 ° C. or higher, and the temperature of the cooler is Refrigerator said ends when it becomes higher than the temperature of the refrigeration temperature zone compartment, the defrosting operation by the third defrosting means, characterized in Rukoto be implemented.   3. The refrigerator according to claim 1, wherein an energization amount of the defrost heater is adjusted during a defrosting operation by the second defrosting unit.   The refrigerator according to claim 1 or 2, wherein a rotation speed of the blower is adjusted during a defrosting operation by the second defrosting means. The defrosting operation according to the third defrosting means refrigerator according to claim 1 or 2 the temperature of the cooler is characterized in that it ends when elevated to a predetermined second cooler temperature. During the defrosting operation performed by the selected defrosting mode, when the temperature of the freezing temperature zone compartment rises above a predetermined freezing temperature zone compartment upper limit temperature is, it implement the third defrosting means The refrigerator according to any one of claims 1 to 5, wherein: The freezing temperature zone compartment upper limit temperature, the refrigerator according to claim 6, characterized in Rukoto differ by the selected defrosting mode. Frozen in the third direction of the defrosting means Contact defrosting mode defrosting operation is performed by Keru freezing temperature zone compartment upper limit temperature, the third defrost mode defrosting operation by the defrosting means is not implemented in the The refrigerator according to claim 7, wherein the refrigerator is set to be higher than a temperature zone upper limit temperature . The refrigeration temperature zone upper limit temperature in the defrosting mode in which only the defrosting operation by the first defrosting means is performed depends on the defrosting operation by the second defrosting means or the third defrosting means. the refrigerator according to claim 7 or 8 is set lower than the freezing temperature zone compartment upper limit temperature in the defrosting mode including the defrosting operation, characterized in Rukoto.

Images