DE69529929T2 - Control method for a refrigerator with a high-performance multi-evaporator circuit - Google Patents

Description

Background of the invention

The invention relates to a method for controlling a refrigerator having a high efficiency multiple evaporator circuit (H.M. CIRCULATION) for carrying out cooling and freezing at a constant temperature in each of divided compartments thereof using separate evaporators and their associated fans.

Generally, a refrigerator comprises a body 4 in which a freezing compartment 2 and a refrigerating compartment 3 are partitioned from each other by a central partition 1, with doors 5 and 6 provided as shown in Fig. 1. The refrigerator has a refrigeration cycle including a compressor 7, a condenser 8, a capillary tube 9 and an evaporator 10 which are connected in sequence by means of refrigeration tubes 11, forming a closed loop as shown in Fig. 2. In other words, the refrigerating medium performs the refrigeration cycle operation for the purpose of energy state conversion while passing through the refrigeration tubes 11 and various components.

In particular, the evaporator 10 absorbs the heat around its periphery and produces cooled air.

Referring to Fig. 1, the compressor 7 is mounted on the lower part of the body 4 and the evaporator 10 is mounted in the rear wall of the refrigerator compartment 2. A cooling fan 12 is provided above the upper part of the evaporator 10. A fan guide 14 and a cooled air duct 15 each having cooled air outlet parts 13 are provided at appropriate locations in the rear wall of the refrigerator body 4 so that part of the cooled air undergoing heat exchange in the evaporator 10 is supplied to the freezer compartment 2 via the outlet part 13 of the fan guide 14 and the rest is supplied to the refrigerator compartment 3 via the outlet part 13 of the cooled air duct 15. And then, after the cooled air is circulated in each compartment, it returns to the evaporator 10 again through first and second return passages 17 and 18 formed on a central partition wall 1 to undergo heat exchange. A control damper 18 serves to adjust an amount of cooled air to be supplied to the refrigerating compartment 3.

Referring to Fig. 3, the refrigerator is usually controlled according to the prior art method as follows: the temperature TF of the freezer compartment 3 (hereinafter referred to as "freezing temperature") is detected to determine whether the compressor 7 is operating or not. The freezing temperature TF is compared with the set freezing temperature TFS which is set in advance using a temperature setting device. Therefore, the control operates in step 110 to determine whether the freezing temperature TF is higher than the set freezing temperature TFS of the freezer compartment (hereinafter referred to as "set freezing temperature"). If the temperature TF is above the set freezing temperature TFS, step 110 proceeds to step 111 to turn on the compressor 7 and the cooling fan 10. If the freezing temperature TF is below the set freezing temperature TFS, step 110 proceeds to step 112 to turn off the compressor 7 and the cooling fan 10. After the respective operations of steps 111 and 112, the controller executes step 113 to determine whether the temperature TR of the refrigerating compartment 3 (hereinafter referred to as "refrigerating temperature") is higher than the set temperature TRS of the refrigerating compartment (hereinafter referred to as "set refrigerating temperature") which is previously set using a temperature setting device, according to their comparison results. If the refrigerating temperature TR is higher than the set refrigerating temperature TRS, step 113 proceeds to step 114 to open the control door 18. On the contrary, if the cooling temperature TR is below the set cooling temperature TRS, step 110 proceeds to step 115 to close the control flap 18.

Thus, during the operation of the compressor 7 and the cooling fan 10, the control damper 18 is operated to supply an appropriate amount of cooled air into the refrigerating compartment 3, but when the compressor 7 is turned off, even if the control damper 18 is opened based on the fact that the refrigerating temperature TR is higher than the set refrigerating temperature TRS, the supply of the cooled air into the refrigerating compartment 3 is not uniform under the non-operation of the cooling fan 10. This means the temperature rise in the refrigerating compartment 3. Further, the amount of cooled air in the refrigerating compartment 3 is not uniform. This means the temperature rise in the refrigerating compartment 3. Further, the amount of cooled air can be adjusted, but the temperature of the refrigerating compartment presents the larger deviation according to the operation or non-operation of the compressor 7. Consequently, the constant temperature refrigeration is very difficult.

The freezer compartment and the refrigerator compartment are set to be kept at 3ºC and -18ºC below the standard temperature condition, respectively. Then, there are problems in that there is no limitation in controlling the two temperature ranges using a heat source or a chiller and the energy efficiency reduction of the refrigerator. In other words, in case a heat exchanger controls two temperature ranges of the refrigerator and the freezer compartment by the predetermined temperatures, the heat exchanger, the refrigerator compartment and the freezer compartment may each show larger differences between their temperatures caused during operation and non-operation. This means the generation of the irreversible loss in thermodynamic terms, followed by the reduction of the energy efficiency.

The refrigerator is designed so that the freezer and refrigerator compartments communicate with each other through the ducts and the return passages. There are problems in that the moisture emitted from the food in the refrigerator compartment generates a lot of frost on the surfaces of the heat exchanger with lower temperature, an amount of wind passing through the heat exchanger is reduced, and thus the energy efficiency of the refrigerator is lowered.

The refrigerator has complex procedures for generating cooled air at the heat exchanger, passing it through the cooling channel, setting an amount of cooled air, and supplying the set amount of cooled air to the refrigerating compartment. It takes a long time to make the refrigerating compartment be maintained at the predetermined temperature of 3ºC. In particular, at the time of initially starting or restarting the refrigerator after the long-term stop, it takes a long time under the high temperature condition of about 30ºC to keep the refrigerating compartment at the It is also not possible to respond quickly to the temperature changes of the refrigerator compartment. Therefore, constant temperature cooling is not realized. For this purpose, it is proposed that the refrigerator provide an exclusive fan in each of the freezer and refrigerator compartments, but only one heat exchanger is installed in the freezer compartment. This not only has a limitation in cooling the refrigerator compartment at a high speed, but also a problem in that the respective control of the refrigerator and freezer compartments cannot be carried out.

The refrigerator also has a problem in that a large amount of frost is formed on the heat exchanger because the cooled air becomes humid air while returning to the heat exchanger through the return passage after circulating in the refrigerator compartment. The frost does not melt away while the refrigerator is not in use, so it causes the refrigerator compartment to be dried. As a result, the stored food in the refrigerator compartment cannot be kept fresh for a long period of time.

The refrigerator has a bad effect on the food and ice stored in the freezer due to the smells, etc. of foods such as fermented vegetables called kimchi, because the cooled air supplied separately to the refrigerator and freezer compartments is returned to the heat exchanger, mixed together, and then supplied to the latter.

The refrigerator requires the cooled air duct to distribute cooled air generated at the heat exchanger to the refrigerator or freezer compartment and return passages to guide cooled air to be returned to the heat exchanger. Thus, it causes the complex configuration and the loss of cooled air associated with it.

A typical prior art is U.S. Patent No. 5,150,583, which discloses a refrigerator having a freezer compartment provided with an evaporator and a fan and a refrigerating compartment provided with an evaporator and a fan. The refrigerator is said to presuppose the use of the non-azeotropic refrigerant mixture having two components having different boiling points from each other. In case of use, the non-point of a high temperature range is used for cooling the refrigerating compartment, and the refrigerant having the melting point of a low temperature range is used for cooling the freezer compartment. Therefore, it has an advantage in that two refrigerants enable the heat exchanger to have the smaller heat transfer temperature difference to air in the compartments from their own temperatures and lower the thermodynamic non-reversible loss, thereby improving the energy efficiency. However, it requires the wider heat transfer area of the heat exchanger to accomplish the predetermined heat transfer, which means that the heat exchanger becomes larger. A gas-liquid separator must also be provided in the piping because it is not necessary to introduce refrigerant which is evaporated in the high temperature region into the low temperature region. Setting the appropriate mixing ratio of the two refrigerants is difficult. Even if the mixing of two refrigerants is carried out precisely, the mixed state has the potential to be changeable in each component of the refrigeration cycle. The mixing ratio is also changeable according to the load condition of the compartments or the open air temperature outside the refrigerator. Furthermore, during mass production of products, it is more difficult to mix two refrigerants in the piping with the exact mixing ratio. If a predetermined allowable error exists in the sealed amount of coolant, the coolant mixture will degrade its own inherent performance.

US 5,150,583 shows various control systems for a refrigerator having a fresh food compartment and a freezer compartment. In Fig. 4 of this patent, a fresh food fan and compressors are shown which are activated when the temperature of the fresh food compartment rises above a predetermined point. When the temperature of the fresh food compartment rises above a predetermined point and the temperature of the freezer compartment rises above a predetermined temperature, the fan in the freezer compartment is activated.

An object of the invention is to provide a control method for a refrigerator with an H.M. cycle having independently divided freezing and refrigerating compartments provided with a cooling system (an evaporator and an air circulation fan) to control each compartment independently, thereby improving the cooling speed of each compartment.

Another object of the invention is to provide a control method for a refrigerator with an H. M. cycle having a refrigeration system provided with two evaporators and two fans, thereby simplifying the configuration of the refrigeration cycle and enabling a single refrigerant to be used, thereby improving mass production.

Another object of the invention is to provide a control method for a refrigerator with an HM circuit for simultaneously operating the freezer and the Cooling fan, which improves the cooling speed.

Another object of the invention is to provide a control method for a refrigerator with an H. M. cycle for turning on a compressor according to the condition of the freezer or refrigerator compartment and for independently controlling the freezer and refrigerator fans, thereby maintaining each compartment at the set temperature.

Another object of the invention is to provide a control method for a refrigerator with a H. M. circuit for enabling the refrigerator compartment to be maintained at the constant temperature even during cooling of the freezer compartment.

Another object of the invention is to provide a control method for a refrigerator with an H. M. circuit for enabling the freezer compartment itself to be maintained at the constant temperature during cooling of the refrigerator compartment, as well as for enabling the refrigerator compartment itself to be maintained at the constant temperature during cooling of the freezer compartment.

According to the present invention, claim 1 defines a method for controlling a refrigerator having a compressor, a freezer and a refrigerator compartment separated from each other, and a refrigeration cycle.

The set freezing temperature can be between -21ºC and -15ºC and the set cooling temperature is between -1ºC and 6ºC.

BRIEF DESCRIPTION OF THE DRAWINGS

The invention will now be described in detail with reference to the accompanying drawings, in which:

Fig. 1 is a side cross-sectional view showing the configuration of a conventional refrigerator;

Fig. 2 is a block diagram of a refrigeration cycle adapted to the conventional refrigerator of Fig. 1;

Fig. 3 is a flowchart showing a control method for the conventional refrigerator of Fig. 1;

Fig. 4 is a side cross-sectional view showing the configuration of a refrigerator with an H. M. cycle;

Fig. 5 is a block diagram of a refrigeration cycle adapted to the refrigerator of Fig. 4;

Fig. 6 is a block diagram showing a control part of the refrigerator with a H. M. circuit;

Fig. 7 is a flow chart showing a first embodiment of a control method of the refrigerator with an H. M. cycle; this method is not covered by the invention;

Fig. 8 is a flow chart illustrating the operation of a compressor, a refrigerator fan and a freezer fan according to the first embodiment;

Fig. 9 is a flowchart showing a second embodiment of a control method of the refrigerator with an HM circuit, which is not covered by the invention;

Fig. 10 is a flow chart illustrating the operation of a compressor, a refrigerator fan and a freezer fan according to the second embodiment;

Fig. 11 is a flow chart showing a third embodiment of a control method of the refrigerator with an H. M. cycle, which method is covered by the invention;

Fig. 12 is a flow chart showing a fourth embodiment of a control method of the refrigerator with an H.M. cycle, which is not covered by the invention;

Fig. 13 is a flow chart showing the operation of a compressor, a refrigerator fan and a freezer fan according to the fourth embodiment;

Fig. 14 is a flow chart showing a fifth embodiment of a control method of the refrigerator with an H. M. cycle; this method is not covered by the invention;

Fig. 15 is a flow chart showing the operation of a compressor, a refrigerator fan and a freezer fan according to the fifth embodiment;

Fig. 16 is a flow chart showing a sixth embodiment of a control method of the refrigerator with an H.M. cycle, which is not covered by the invention;

Fig. 17 is a flow chart showing the operation of a compressor, a refrigerator fan and a freezer fan according to the sixth embodiment;

Fig. 18 is a flow chart showing a seventh embodiment of a control method of the refrigerator with an H. M. cycle, which is not covered by the invention;

Fig. 19 is a flow chart showing the operation of a compressor, a refrigerator fan and a freezer fan according to the seventh embodiment;

Fig. 20 is a flow chart showing an eighth embodiment of a control method of the refrigerator with an H.M. cycle, which is not covered by the invention;

Fig. 21 is a flow chart showing the operation of a compressor, a refrigerator fan and a freezer fan according to the eighth embodiment;

Fig. 22, 23, 24 and 25 are each a flow chart showing a ninth embodiment, a tenth embodiment, an eleventh embodiment and a twelfth embodiment of a control method for the refrigerator with an H. M. cycle, wherein only the tenth embodiment is included in the invention.

DETAILED DESCRIPTION OF THE INVENTION

A refrigerator with a H. M. circuit will now be described in detail with reference to Figs. 4, 5 and 6.

As shown in Fig. 4, the refrigerator 20 with an H.M. cycle includes a body made of the heat-insulating configuration and divided into a freezing compartment 22 formed at the lower part thereof and a refrigerating compartment 23 formed at the upper part thereof to prevent the mixing of cooled air generated in each compartment with each other. In other words, the freezing compartment 22 and the refrigerating compartment 23 are separated from each other by a central partition wall 24, each of which is provided with a freezing door 25 and a refrigerating compartment door 26 to open/close them. Note here that any flow path for cooled air is not shown to communicate the freezing compartment and the refrigerating compartment with each other, while the central partition wall 24 does not provide a return passage therein unlike the prior art. A first heat exchanger or evaporator 27 and a refrigerating compartment fan 28 (hereinafter referred to as "refrigerating fan") are provided in the rear wall of the refrigerating compartment 23, and a first heat exchanger or evaporator 29 and a freezing compartment fan 30 (hereinafter referred to as "freezing fan") are mounted in the rear wall of the freezing compartment 22, each compartment fan comprising a fan motor. A compressor 31 is mounted in the lower part of the body 21.

The HM refrigeration cycle of the refrigerator is referred to Fig. 5. The compressor 31, a condenser 32, a capillary tube 33 and the first and second evaporators 27 and 29 are connected in series to form a closed loop. The cooling fan 28 and the freezing fan 30 are mounted near the first and second evaporators 27 and 29, respectively. When the refrigerant is passed in the arrow direction to induce its own associated phase changes, it is partially evaporated in the first and second evaporators 27 and 29 to absorb the heat from the air and to generate cooled air. The cooled air circulates in the refrigerator compartment 23 and the freezer compartment 22 by means of the cooling fan 28 and the freezer fan 30, respectively.

The refrigerator uses a refrigerant such as CFC-12 or HFC-134a, etc. The phase change of the refrigerant is explained as follows: the refrigerant is compressed at the high temperature and at the high pressure in the compressor 31. The compressed refrigerant is sent to the condenser 32 to be condensed by exchanging heat with the ambient air. The refrigerant flows through the capillary tube 33 or an expansion valve to reduce its pressure. And then the refrigerant is evaporated by passing through the first and second evaporators 27 and 29 in sequence, the first and second evaporators 27 and 29 being connected to each other in series without installing any structure therebetween. Therefore, the refrigerant flowing through the first evaporator 27 is partially evaporated and then sent to the second evaporator 29 to gasify the remaining refrigerant. The completely gasified refrigerant is supplied to the compressor 31, thereby completing an H. M. refrigeration cycle. The H. M. refrigeration cycle is repeated based on the operation of the compressor 31.

As described above, the refrigerator with an HM cycle includes two evaporators and two fans and uses a refrigerant as a working fluid. Consequently, it does not require components such as a gas-liquid separator between the evaporators or a valve for controlling the flow direction of the refrigerant. The serial arrangement of the evaporators simplifies the piping for the HM refrigeration cycle. The use of a refrigerant is very advantageous for mass production of the refrigerator because the performance change of the refrigeration cycle does not change slightly with the manufacturing procedures according to the distribution of the amount of the wrapped refrigerant as when the mixed refrigerant is used. Even when a refrigerant is used, the evaporation temperature is changed according to the temperature of air flowing through the evaporator, thereby lowering the non-reversible loss of thermodynamics. In other words, when the temperature of air flowing through the first evaporator is relatively higher, the evaporation temperature of the first evaporator is high. When the temperature of air flowing through the second evaporator is relatively lower, the evaporation temperature of the second evaporator is low. Therefore, it can reduce the temperature difference between before and after the cooling process to reduce the non-reversible loss of thermodynamics.

Referring to Fig. 6, the control part of a refrigerator with an HM cycle is described as follows. A control part 35 includes a door switch 36 for detecting the opening or closing of a door, a refrigerator compartment temperature sensor 37 for detecting the temperature of a refrigerator compartment, a freezer compartment temperature sensor 38 for detecting the temperature of a freezer compartment, an open air temperature sensor 39, a first cooling surface temperature sensor 40 and a second cooling surface temperature sensor 40' connected to the input part thereof, whereby the electrical signals detected by the switch and the sensors are input thereto. The control part 35 also includes a first switch 41, a second switch 42 and a third switch 43 connected to the output part thereof so that the compressor 31, the cooling fan 28 and the freezing fan 30 are turned on or off, respectively. The first switch 41, the second switch 42 and the third switch 43 are controlled by the control part 35 to turn on/off each of the compressor 31, the cooling fan 28 and the freezing fan 30. Thus, This is the independent control of the compressor 31, the cooling fan 28 and the freezing fan 30.

The control part 35 controls the operation of the compressor and the freezing and cooling fan in such a way that, if the temperature detected by the freezer sensor is above a previously set one suitable for storing frozen food, the compressor and the freezing and cooling fan are turned on. If not, the compressor and the freezing and cooling fan are turned off on the contrary. Herein, the set temperature of the freezer compartment means the temperature range of a compartment, for example -15ºC to -21ºC, belonging to the freezer compartment, within which range a user can select any of -21ºC (strong freezing), -18ºC (medium freezing) and -15ºC (weak freezing). The set temperature of the refrigerator compartment also means the temperature range of a compartment, for example, 6ºC to -1ºC, belonging to the refrigerator compartment, within which range a user can select any of -1ºC (strong cooling), 3ºC (medium cooling) and 6ºC (weak cooling).

The control part has another control method for a system in which, when the temperature of the freezing compartment is above the set freezing temperature and the temperature of the refrigerating compartment is above the set refrigerating temperature, when the temperature detected by the second refrigerating surface temperature sensor is above that of the freezing compartment, it sets the operating time of the compressor and the freezing and refrigerating fans to be delayed until the temperature of the second refrigerating surface temperature sensor becomes lower than that of the freezing compartment.

The control part has a further control method for a system in which, when the temperature of the freezer compartment is above the set freezing temperature and the temperature of the refrigerator compartment is above the set cooling temperature, the compressor is turned on but each of the freezer and refrigerator fans is controlled according to the temperatures of the freezer and refrigerator compartments.

The control part has another control method for a system in which, when the temperature of the freezer compartment is above the set freezing temperature and the temperature of the refrigerator compartment is above the set cooling temperature, the compressor and the cooling fan are first turned on to cool the refrigerator compartment, and then, when the temperature of the refrigerator compartment is below the set cooling temperature, the compressor and the freezing fan are turned on to cool the freezer compartment.

The control part has another control method for a system in which, when the temperature of the refrigerator compartment is above the set cooling temperature during cooling of the freezer compartment, the compressor and the freezing fan are turned on together with the cooling fan to carry out the cooling of the freezer and refrigerator compartments to the constant temperature.

The control part has another control method for a system in which, when the temperature of the refrigerating compartment becomes higher than the set refrigerating temperature by the predetermined temperature during cooling of the refrigerating compartment at the time of initial operation, the refrigerating fan is turned on together with the freezing fan to improve the cooling speeds of the freezing and refrigerating compartments. At this time, it is desirable that the temperature of the refrigerating compartment is higher than the set refrigerating temperature by 1ºC to 5ºC, particularly 2ºC.

The control part has a further control method for a system in which, when the temperature of the freezer compartment during cooling of the refrigerator compartment at the time of normal operation becomes higher than the set freezing temperature by the predetermined temperature, the freezing fan is turned on together with the cooling fan to carry out the cooling of the freezing and refrigerator compartments at the constant temperature. At this time, it is desirable that the temperature of the freezing compartment is higher than the set freezing temperature by 1ºC to 5ºC, particularly 2ºC.

The control part has another control method for a system in which, when the temperature of the freezing compartment becomes higher than the set freezing temperature by the predetermined temperature during cooling of the refrigerating compartment at the time of normal operation, the freezing fan is turned on together with the cooling fan to perform the cooling of the freezing and refrigerating compartments at the constant temperature. Whereas, when the temperature of the refrigerating compartment becomes higher than the set freezing temperature by the predetermined temperature during cooling of the freezing compartment at the time of normal operation, the cooling fan is turned on together with the freezing fan to perform the cooling of the freezing and refrigerating compartments at the constant temperature. At this time, it is desirable that the temperatures of the freezing and refrigerating compartments are each higher than their own set ones by 1ºC to 5ºC, particularly 2ºC.

The control part has another control method for a system in which it determines whether an open air condition outside the refrigerator is an overload condition which is predetermined according to the characteristics of the refrigerator, and when the condition of a compartment is beyond the set temperature which is predetermined to be suitable for storing food but both compartments can be cooled at the same time, it is not the overload condition. Thus, the Freezing and refrigerating fans are operated together to perform the cooling of the freezing and refrigerating compartments at the constant temperature. When it is difficult to cool both compartments together, only any one of the freezing and refrigerating fans is operated to perform the priority cooling of the corresponding compartment. Accordingly, when the open air condition outside the refrigerator is an overload condition, the compressor and the freezing and refrigerating fans are controlled according to one of the methods as described above. Next, the embodiments will be described one by one starting from the initial operation modes including overload operation modes designed for a number of embodiments indicating the normal operation modes of a refrigerator as follows:

According to a fully automatic operation and a control method therefor with the initial operation mode including the overload operation mode as shown in Fig. 22, a first control performs step 351 for comparing an open air temperature TA from a refrigerator with the reference temperature of the open air TA (hereinafter referred to as "reference temperature"), which is regarded as a standard for determining whether the open air condition outside the refrigerator is an overload or not. In other words, the reference temperature means that the open air does not have the high temperature to cause the overload operation of the refrigerator during the normal operation. In particular, it may be noted that the reference temperature gives certain changes to the operation method of the refrigerator in summer time, which is defined in this application as a temperature range of about 30°C-35°C, preferably 32°C. The temperature range is of course not limited to this, but changeable according to the performance and condition of the refrigerator. When the open air temperature TA is above the reference temperature of the Open air TAS, step 351 proceeds to routine A as shown in Fig. 9, which is the same as the second embodiment. The explanation of routine A is omitted here, but will be described in detail below.

If the open air temperature TA is below the open air reference temperature TAS, step 351 proceeds to step 352 to compare the freezing temperature TF with the freezing reference temperature TFR and the refrigerating temperature TR with the freezing reference temperature TRR. Note here that the definition of the reference temperature is for providing another temperature range similar to the temperature range of a compartment within the predetermined range outside a set temperature range. The refrigerating reference temperature is defined, for example, as the temperature range from the temperature outside a refrigerating set temperature to the temperature that users seem to feel like warm air. At that time, the preferable temperature range is 7ºC to 15ºC, more preferably 10ºC. The freezing reference temperature is also defined as the temperature range from the temperature outside a freezing set temperature to the temperature at which ice is formed in the freezer compartment. At this time the temperature range is -14ºC to -5ºC, preferably -10ºC.

When the freezing temperature TF is above the freezing reference temperature TFR and the refrigerating temperature TR is above the refrigerating reference temperature TRR, step 352 proceeds to routine B as shown in Fig. 16, which is the same as the sixth embodiment. The explanation of routine B is omitted here, but will be described in detail below.

If the freezing temperature TF is below the freezing reference temperature TFR or the cooling temperature TR is below the cooling reference temperature TRR, step 352 proceeds to routine C as shown in Fig. 9, which is the same as the second embodiment. The explanation of routine C is omitted here, but will be described in detail below.

According to the first control of the initial operation mode, when the open air temperature is above the reference temperature as described above, the freezing and refrigerating compartments are cooled simultaneously. If at this time the temperature of the second evaporator is above the freezing temperature, the operation of the freezing fan is delayed until the surface temperature of the second evaporator becomes below the freezing temperature. This prevents the reverse effect of raising the temperature of the freezing compartment. If the open air temperature is above the reference temperature, it is also determined whether the temperature of each compartment is above its reference temperature. If at this time the temperature of each compartment is below its reference temperature, the freezing and refrigerating compartments are all cooled simultaneously at the first time to reach their set temperatures. However, when the freezing and refrigerating compartments are all cooled, if the temperature of each compartment is above its reference temperature, any of the freezing and refrigerating compartments must be cooled first because it is difficult to cool the compartments to their set temperatures. Therefore, the ninth embodiment allows one compartment to be cooled first and then another compartment to be cooled so that both compartments can be cooled quickly to reach their set temperatures.

Referring to Fig. 23, a second control performs step 351 to compare an outdoor air temperature TA outside a refrigerator with a reference outdoor air temperature TAS. If the outdoor air temperature TA is above the reference open air temperature TAS, step 351 proceeds to routine A as shown in Fig. 11, which is the same as the third embodiment. The explanation of routine A is omitted here, but will be described in detail below.

If the open air temperature TA is below the open air reference temperature TAS, step 351 proceeds to step 352 to compare the freezing temperature TF with the freezing reference temperature TFR and the refrigerating temperature TR with the refrigerating reference temperature TRR. If the freezing temperature TF is above the freezing reference temperature TFR and the refrigerating temperature TR is above the refrigerating reference temperature TRR, step 352 then proceeds to routine B as shown in Fig. 16, which is the same as the sixth embodiment. The explanation of routine B is omitted here, but will be described in detail below.

When the freezing temperature TF is below the freezing reference temperature TFR or the refrigerating temperature TR is below the refrigerating reference temperature TRR, step 352 proceeds to routine C as shown in Fig. 9, which is the same as the second embodiment. The explanation of routine C is omitted here, but will be described in detail below.

According to the second control of the initial operation mode, when the open air temperature is above the reference temperature as described above, the freezer and refrigerator compartments are cooled separately. If the open air temperature is below the reference temperature, then it is determined whether the temperature of each compartment is below its reference temperature. If the temperature of each compartment is below its reference temperature, the freezer and refrigerator compartments are all cooled from the beginning to reach their set temperatures. If the If the temperature of each compartment is above their reference temperature, any of the freezer and refrigerator compartments will be cooled first so that both compartments can be cooled quickly to reach their set temperatures.

Referring to Fig. 24, a third control performs step 351 to compare an open air temperature TA outside a refrigerator with the reference open air temperature TAS. If the open air temperature TA is above the reference open air temperature TAS, step 351 proceeds to routine A as shown in Fig. 14, which is the same as the fifth embodiment. The explanation of routine A is omitted here, but will be described in detail below.

If the open air temperature TA is below the open air reference temperature TAS, step 351 proceeds to step 352 to compare the freezing temperature TF with the freezing reference temperature TFR and the refrigerating temperature TR with the refrigerating reference temperature TRR. If the freezing temperature TF is above the freezing reference temperature TFR and the refrigerating temperature TR is above the refrigerating reference temperature TRR, step 352 then proceeds to routine B as shown in Fig. 16, which is the same as the sixth embodiment. The explanation of routine B is omitted here, but will be described in detail below.

When the freezing temperature TF is below the freezing reference temperature TFR or the refrigerating temperature TR is below the refrigerating reference temperature TRR, step 352 proceeds to routine C as shown in Fig. 9, which is the same as the second embodiment. The explanation of routine C is omitted here, but will be described in detail below.

As described above, according to the third control of the initial operation mode, under the abnormal condition of the freezing and refrigerating compartments, when the open air temperature is above the reference temperature, the refrigerating compartment is cooled first, and then the freezing compartment is cooled when the refrigerating temperature becomes below the set refrigerating temperature. When the open air temperature is below the reference temperature, it is then determined whether the temperature of each compartment is below its reference temperature. When the temperature of each compartment is below its reference temperature, the freezing and refrigerating compartments are all cooled from the beginning to reach their set temperatures. When the temperature of each compartment is above its reference temperature, any one of the freezing and refrigerating compartments is cooled first so that both compartments can be quickly cooled to reach their set temperatures.

Referring to Fig. 25, a fourth control executes step 351 to compare an open air temperature TA outside a refrigerator with the reference open air temperature TAS. If the open air temperature TA is above the reference open air temperature TAS, step 351 proceeds to routine A as shown in Fig. 20, which is the same as the eighth embodiment. The explanation of routine A is omitted here, but will be described in detail below.

If the open air temperature TA is below the open air reference temperature TAS, step 351 proceeds to step 352 to compare the freezing temperature TF with the freezing reference temperature TFR and the refrigeration temperature TR with the refrigeration reference temperature TRR. If the freezing temperature TF is above the freezing reference temperature TFR and the refrigeration temperature TR is above the refrigeration reference temperature TRR, step 352 then proceeds to routine B as shown in Fig. 16, which is the same as the sixth embodiment. The explanation of the routine B is omitted here, but will be described in detail below.

When the freezing temperature TF is below the freezing reference temperature TFR or the refrigerating temperature TR is below the refrigerating reference temperature TRR, step 352 proceeds to routine C as shown in Fig. 9, which is the same as the second embodiment. The explanation of routine C is omitted here, but will be described in detail below.

As described above, according to the fourth control of the initial operation mode, under the abnormal condition of the freezing and refrigerating compartments, when the open air temperature is above the reference temperature, the refrigerating compartment is cooled first, and the freezing compartment is cooled when the refrigerating temperature becomes below the set refrigerating temperature. Therefore, it enables the freezing and refrigerating compartments to be kept at the constant temperature. When the open air temperature is below the reference temperature, it is then determined whether the temperature of each compartment is below the reference temperature. When the temperature of each compartment is below the reference temperature, the freezing and refrigerating compartments are all cooled from the beginning to reach their set temperatures. When the temperature of each compartment is above the reference temperature, any one of the freezing and refrigerating compartments is cooled first so that both compartments can be quickly cooled to reach their set temperatures.

On the other hand, the normal operation modes are as follows. As mentioned above, only the third and tenth embodiments are covered by the invention.

FIRST EXAMPLE OF IMPLEMENTATION

Referring to Figs. 7 and 8, the control part 35 compares the temperature TF of the freezing compartment with the set freezing temperature TFS in step 211. If the freezing temperature TF is higher than the set freezing temperature TFS, step 211 proceeds to step 212 to compare the cooling temperature TR of the refrigerating compartment with the set refrigerating temperature TRS. If the cooling temperature TR is above the set refrigerating temperature TRS, the control proceeds to step 213 to turn on the compressor and the freezing and refrigerating fan. This means using the freezing and refrigerating compartments which are subject to the high temperature state as is not desired, but as shown in Fig. 8A, both compartments are cooled simultaneously to take advantage of the improvement of their cooling speed. This situation occurs when both compartments are used frequently, the open air temperature outside the refrigerator is higher, or the refrigerator is restarted after not being used for a long period of time.

If the refrigeration temperature TR is below the refrigeration set temperature TRS in step 212, the control proceeds to step 214 to turn on the compressor and the freezing fan and turn off the refrigeration fan. Step 214 then returns to step 212. In this case, the freezing compartment is kept under the normal condition and the refrigerating compartment is not kept under the normal condition. Therefore, as shown in Fig. 8B, when the temperature of the refrigerating compartment is above the refrigeration set temperature during refrigeration of the freezing compartment, the compressor and the freezing fan are operated first and then the refrigerating fan is operated. Step 213 proceeds to step 215 to compare the freezing temperature TF with the freezing set temperature TFS. If the Freezing temperature TF is above the set freezing temperature TFS, step 215 returns to step 212. If the freezing temperature TF is below the set freezing temperature TFS, step 215 proceeds to step 216 to turn on the compressor and the cooling fan and turn off the freezing fan. This means that during the execution of step 213, if the cooling temperature becomes below the set cooling temperature, the cooling of the cooling compartment is stopped. If the freezing temperature becomes below the set freezing temperature, the cooling of the freezing compartment is also stopped. If the cooling compartment is used to be cooled first, step 214 is performed to stop the cooling of the cooling compartment, as shown in Fig. 8A.

If the freezing temperature TF is below the freezing set temperature TFS in step 211, the control proceeds to step 217 to compare the refrigerating temperature TR with a second refrigerating set temperature TRS2 which is higher than the refrigerating temperature TRS by the predetermined temperature of 1ºC to 5ºC. If the refrigerating temperature TR is above the second refrigerating set temperature TRS2, the control executes step 216 to turn on the compressor and the refrigerating fan and turn off the freezing fan. If the refrigerating temperature TR is below the second refrigerating set temperature TRS2 in step 217, step 217 proceeds to step 218 to stop the operation of the compressor and the freezing and refrigerating fans. In step 216, the freezing compartment is kept under the normal condition and the refrigerating compartment is kept under the abnormal condition of high temperature. Consequently, as shown in Fig. 8C, the compressor and the cooling fan are first operated under the condition that the freezer compartment is cooled according to its current state. In other words, after the refrigerator compartment is cooled below the set temperature, is set, the freezer compartment can be cooled. Otherwise, even before the refrigerator compartment is cooled below the set temperature, the freezer compartment can be cooled together with the refrigerator compartment if the freezer compartment has the temperature higher than the set freezing temperature.

Step 216 proceeds to step 219 to compare the refrigeration temperature TR with the refrigeration set temperature TRs. If the refrigeration temperature TR is below the refrigeration set temperature TRS, step 216 returns to step 211. If the refrigeration temperature TR is above the refrigeration set temperature TRS, step 216 proceeds to step 220 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, step 220 returns to step 212. If the freezing temperature TF is below the freezing set temperature TFS, the control executes step 216 to turn on the compressor and the refrigeration fan and turn off the freezing fan.

Step 218 proceeds to step 221 to determine whether a first surface temperature TES of the first evaporator is above 0ºC. If the first surface temperature TES is below 0ºC, step 221 proceeds to step 222 to turn off the compressor and the freezing fan and turn on the refrigerating fan and perform defrosting of the first evaporator. In other words, the operation of the refrigerating fan removes the frost on the first evaporator immediately after the compressor is turned off when the freezing and refrigerating compartments return to the normal state. This means using the fact that the refrigerating temperature is above that of the first evaporator during non-operation of the compressor. As shown in Fig. 8A, 8B and 8C, once the compressor is turned off, only the cooling fan is operated so that the cooling air with the relatively higher temperature is passed through the first evaporator to remove the frost thereon as well as to cool the refrigerator compartment. Therefore, an electric separate heater for consuming the power is not only omitted, but also the over-temperature rise can be prevented.

As described above, according to the first embodiment, both the freezing and refrigerating compartments subject to the abnormal condition are cooled together, thereby improving the cooling speed of both compartments (see Fig. 8A). Referring also to Figs. 8B and 8C, when the freezing compartment is under the abnormal condition and the refrigerating compartment is under the normal condition, cooling of the freezing compartment is performed first. On the contrary, when the refrigerating compartment is under the abnormal condition and the freezing compartment is under the normal condition, cooling of the refrigerating compartment is performed first. This means that during cooling of the freezing compartment, the refrigerating compartment is kept below the set cooling temperature. On the contrary, during cooling of the refrigerating compartment, the freezing compartment is kept below the set temperature. Once the compressor is turned off, only defrosting is performed on the first evaporator using air in the refrigerating compartment.

SECOND EXAMPLE

Referring to Figs. 9 and 10, the control part 35 compares the temperature TF of the freezer compartment with the set freezing temperature TFS in step 231. If the freezing temperature TF is above the set freezing temperature TFS, step 231 proceeds to step 232 to compare the cooling temperature TR of the refrigerator compartment with the set refrigeration temperature TRS. If the refrigeration temperature TR is above the set refrigeration temperature TRs, step 232 proceeds to step 233 to compare the freezing temperature TF and the surface temperature TFE of a second evaporator. If the freezing temperature TF is above the surface temperature TFE of the second evaporator (it is desirable that the freezing temperature TF is higher than the surface temperature TFE of the second evaporator by the temperature of 1ºC to 5ºC, particularly 2ºC), the control proceeds to step 234 to turn on the compressor and the freezing and refrigerating fans. On the contrary, if the freezing temperature TF is below the surface temperature TFE of the second evaporator, the control proceeds to step 235 to turn on the compressor and the refrigerating fan and turn off the freezing fan. In other words, when the freezing and refrigerating compartments are subject to the abnormal condition as one does not want, step 234 is performed to increase the cooling speed of both compartments. This means that when the surface temperature TFE of the second evaporator is above the freezing temperature TF as shown in Fig. 10A, the freezing fan is operated after being delayed by the predetermined time t, thereby saving power. This situation occurs when the residual refrigerant passed through the condenser and the capillary in the high temperature and high pressure state is introduced into the first and second evaporators with the compressor turned off after the normal operation, particularly when the surface temperature of the second evaporator is above the freezing temperature. If the freezing fan is operated at this time, it has a reverse effect that the temperature of the freezing compartment is rather increased. Due to this, the operation of the freezing fan is delayed until the surface temperature of the second evaporator falls below freezing temperature.

If the refrigeration temperature TR is below the set refrigeration temperature TRS in step 232, step 232 proceeds to step 236 to compare the freezing temperature TF with the second evaporator surface temperature TFE. If the freezing temperature TF is above the second evaporator surface temperature TFE (it is desirable that the freezing temperature TF be higher than the second evaporator surface temperature TFE by the temperature of 1ºC to 5ºC, particularly 2ºC), control proceeds to step 237 to turn on the compressor and the freezing fan while turning off the refrigeration fan. Otherwise, if the freezing temperature TF is below the second evaporator surface temperature TFE, control proceeds to step 238 to turn off the freezing and refrigeration fans and turn on only the compressor. In other words, when the freezer compartment is under the abnormal condition and the refrigerator compartment is under the normal condition, the freezer temperature and the surface temperature of the second evaporator are compared to determine whether the freezer fan needs to be operated. Then, steps 237 and 238 return to 231.

If the freezing temperature TF is above the freezing set temperature TFS, step 231 goes to step 239 to compare the refrigeration temperature TR with a second refrigeration set temperature TRS2 which is higher than the refrigeration set temperature TRS by the predetermined temperature of 1ºC to 5ºC. If the refrigeration temperature TR is above the second refrigeration set temperature TRS2, step 239 goes to step 235 to turn on the compressor and the refrigeration fan and turn off the freezing fan. If the refrigeration temperature TR is below the second refrigeration set temperature TRS2, step 239 goes to step 236 to turn on the compressor and the refrigeration fan and turn off the freezing fan. Step 239 to 240 to turn off the compressor and the freezer and refrigerator fans.

After performing steps 234 and 235, the control proceeds to step 241 to compare the freezing temperature TF with the set freezing temperature TFS. If the freezing temperature TF is above the set freezing temperature TFS, step 241 returns to step 233. If the freezing temperature TF is below the set freezing temperature TFS, the control proceeds to step 242 to compare the refrigeration temperature TR with the set refrigeration temperature TRS. If the refrigeration temperature TR is above the set refrigeration temperature TRS, step 242 returns to step 235. If the refrigeration temperature TR is below the set refrigeration temperature TRS, step returns to step 240. Next, step 240 proceeds to step 243 to compare the surface temperature TFE of the second evaporator with 0ºC. If the surface temperature TFE of the second evaporator is below 0ºC, control proceeds to step 244 to turn off the compressor and the freezing fan and turn on the cooling fan and to perform defrosting of the first evaporator as described in the first embodiment. Then, step 244 returns to step 243. If the surface temperature TFE of the second evaporator is above 0ºC, step 243 returns to step 231.

As described above, according to the second embodiment, when both the freezing and refrigerating compartments are subject to the abnormal condition, these compartments are cooled together, thereby improving the cooling speed of both compartments. Specifically, when the surface temperature of the second evaporator is above the freezing temperature, the operation of the freezing fan is delayed for the predetermined period of time, until the surface temperature of the second evaporator falls below the freezing temperature. This prevents the reverse effect of increasing the temperature of the freezer compartment. The other effects acting are the same as those of the first embodiment.

THIRD EXAMPLE

Referring to Fig. 11, control starts from step 251 to determine whether the freezing temperature TF is above the freezing set temperature TFS or the refrigerating temperature TR is above the refrigerating set temperature TRs. If the freezing temperature TF is above the freezing set temperature TFS or the refrigerating temperature TR is above the refrigerating set temperature TRS, control proceeds to step 252 to compare the refrigerating temperature TR with the refrigerating set temperature TRS. If the refrigerating temperature TR is above the refrigerating set temperature TRS, step 252 proceeds to step 253 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, control proceeds to step 254 to turn on the compressor and the freezing and refrigerating fans. If the freezer temperature TF is below the set freezer temperature TFS, the control proceeds to step 255 to turn on the compressor and the cooling fan and turn off the freezer fan.

On the other hand, if the refrigeration temperature TR is below the refrigeration set temperature TRS, step 252 jumps to step 256 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is below the freezing set temperature TFS, step 256 returns to step 251. If the freezing temperature TF is above the set freezing temperature TFS, control proceeds to step 257 to turn on the compressor and the freezing fan and turn off the refrigerating fan. In other words, even if any of the freezing and refrigerating compartments is subject to the abnormal condition, the compressor is operated while determining whether the freezing fan and/or the refrigerating fan is operated. Then, steps 254, 255 and 257 return to step 251.

The third embodiment allows the compressor to be operated according to the conditions of both the freezing and refrigerating compartments. Specifically, when the refrigerating temperature is above the set refrigerating temperature, the compressor is turned on regardless of the freezing temperature. In this case, it means that the refrigerating compartment has been used frequently and the temperature has been raised after the compressor was turned off. Therefore, in the case where it is required that both compartments be refrigerated respectively, the second embodiment has an advantage in that each compartment is refrigerated independently so as to be maintained at the set temperature.

If in step 251 the refrigeration temperature TR is below the refrigeration set temperature TRS or the freezing temperature TF is below the freezing set temperature TFS, the control proceeds to step 258 to turn off the compressor and the freezing and refrigerating fans. Step 258 proceeds to step 259 to determine whether the first surface temperature TES of the first evaporator is above 0ºC. If the first surface temperature TES is below 0ºC, step 259 proceeds to step 260 to turn off the compressor and the freezing fan and turn on the refrigerating fan and perform defrosting of the first evaporator. Next, step 260 returns to step 259. If the first surface temperature TES is above 0ºC, step 259 returns to step 251.

As described above, the third embodiment is intended to control each compartment independently, thereby enabling each compartment to be maintained at the set temperature.

FOURTH EXAMPLE

Referring to Figs. 12 and 13, in step 261, it is determined whether the freezing temperature TF is above the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, control proceeds to step 262 to compare the refrigeration temperature TR with the refrigeration set temperature TRS. If the refrigeration temperature TR is above the refrigeration set temperature TRS, control proceeds to step 263 to turn on the compressor and the refrigeration fan and turn off the freezing fan. If the refrigeration temperature TR is below the refrigeration set temperature TRS, control proceeds to step 264 to turn on the compressor and the refrigeration fan and turn off the refrigeration fan. In other words, the fourth embodiment has a feature of cooling the refrigerating compartment before the freezing compartment when all the compartments are under the abnormal condition. At this time, the temperature of the second evaporator is higher than the refrigeration temperature, the temperature of the first evaporator is lower than the refrigeration temperature, or the difference between the temperatures of the first evaporator and the refrigeration compartment is smaller than that between the temperatures of the second evaporator and the freezing compartment. Thus, as shown in Fig. 13A, after the refrigeration compartment is first cooled and then the temperature of the second evaporator has dropped sufficiently, the freezing fan is operated to cool the freezer compartment. Therefore, although the freezing temperature is lower than that of the second evaporator, it can reduce the bad effect caused by the operation of the freezing fan and the power consumption. In other words, when the compressor is turned on according to the freezing temperature, the temperature of the second evaporator is above the freezing temperature and the temperature of the first evaporator is kept below the freezing temperature. If the freezing fan is operated at this time, since the temperature of the second evaporator is above the freezing temperature, the temperature of the freezer compartment is rather increased, thereby consuming the unnecessary energy. Thus, the cooling fan is operated first because the temperature of the first evaporator is lower than the cooling temperature. This means the reduction of the energy consumption.

On the other hand, step 263 returns to step 262. If the refrigeration temperature TR is below the refrigeration set temperature TRS, the control proceeds to step 264 to compare the freezing temperature TF with the freezing set temperature TFS. In other words, when the freezing compartment is under the abnormal condition and the refrigerating compartment is under the normal condition from the first, the compressor and the freezing fan are operated while the refrigerating fan is turned off, as shown in Fig. 13B. However, when the refrigerating compartment is transferred to the normal condition by being refrigerated under the abnormal condition of the freezing and refrigerating compartments, the control executes step 264 to turn on the compressor and the freezing fan and operate them and turn off the refrigerating fan. The situation shown in Fig. 13B may also happen when the freezing temperature is raised relatively faster than the refrigerating temperature or the freezing compartment is used frequently when the temperature of the open air is relatively lower, for example below 10ºC, or below normal temperature.

Next, control proceeds to step 265 to compare the freezer temperature TF with the set freezer temperature TFS. If the freezer temperature TF is above the set freezer temperature TFS, control proceeds to step 264 to turn on the compressor and the freezer and refrigerator fans. If the freezer temperature TF is below the set freezer temperature TFS, control proceeds to step 266 to turn off the compressor and the freezer and refrigerator fans. If the freezer temperature TF is below the set freezer temperature TFS, control also performs step 266.

Step 266 proceeds to step 267 to determine whether the first surface temperature TES of the first evaporator is above 0ºC. If the first surface temperature TES is below 0ºC, the control proceeds to step 268 to turn off the compressor and the freezing fan and turn on the cooling fan and to carry out defrosting of the first evaporator. If, on the contrary, the first surface temperature TES is above 0ºC, step 267 returns to step 261.

As described above, under the abnormal condition of the freezing and the refrigerating compartments, the fourth embodiment allows the refrigerating compartment to be cooled first and then the freezing compartment to be cooled when the refrigerating temperature becomes below the set refrigerating temperature. It induces the efficient use of the energy. The operation of any of the freezing and refrigerating fans reduces the peak pressure of the compressor to improve the efficiency of the compressor.

FIFTH EXAMPLE

Referring to Figs. 14 and 15, in step 271, it is determined whether the freezing temperature TF is above the set freezing temperature TFS. If the freezing temperature TF is above the set freezing temperature TFS, control proceeds to step 272 to compare the refrigeration temperature TR with the set refrigeration temperature TRS. If the refrigeration temperature TR is above the set refrigeration temperature TRS, control proceeds to step 273 to turn on the compressor and refrigeration fan and turn off the freezing fan. If the refrigeration temperature TR is below the set refrigeration temperature TRS, control proceeds to step 267 to turn on the compressor and refrigeration fan and turn off the refrigeration fan.

When the refrigeration temperature TR is below the set refrigeration temperature TRS in step 272, the control proceeds to step 274 to turn on the compressor and the freezing fan and turn off the refrigeration fan. In other words, when the freezing compartment is under the abnormal condition and the refrigerating compartment is under the normal condition of the former, the compressor and the freezing fan are operated while the refrigerating fan is turned off, as shown in Fig. 15B. However, when the refrigerating compartment is brought into the normal condition by being refrigerated under the abnormal condition of the freezing and refrigerating compartments, the control executes step 274 to turn on the compressor and the freezing fan and turn off the refrigerating fan, as shown in Fig. 15A. Step 274 proceeds to step 275 to turn on the compressor and the freezing fan and turn off the refrigerating fan. with the refrigeration set temperature TRS. If the refrigeration temperature TR is above the refrigeration set temperature TRS, step 275 proceeds to step 276 to turn on the compressor and the freezing and refrigerating fans. Then, in step 277, it is determined whether the refrigeration temperature TR is above the refrigeration set temperature TRS. If the refrigeration temperature TR is below the refrigeration set temperature TRS, control proceeds to step 279 to turn on the compressor and the freezing fan and turn off the refrigerating fan. If the refrigeration temperature TR is above the refrigeration set temperature TRS in step 277, step 277 proceeds to step 278 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, step 278 returns to step 276 to turn on the compressor and the freezing and refrigerating fans. If the freezing temperature TF is below the freezing set temperature TFS, step 278 proceeds to step 280 to turn off the compressor and the freezing and refrigerating fans. On the other hand, step 279 proceeds to step 281 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, step 281 returns to step 277 to compare the refrigerating temperature TR with the refrigerating set temperature TRS. If the freezing temperature TF is below the freezing set temperature TFS, step 281 proceeds to step 280 to turn off the compressor and the freezing and refrigerating fans.

If the refrigeration temperature TR is below the set refrigeration temperature TRS, step 275 also proceeds to step 282 to compare the freezing temperature TF with the set freezing temperature TFS. If the freezing temperature TF is above the set freezing temperature TFS, step 282 returns to step 274. If the freezing temperature TF is below the set freezing temperature TFS, control proceeds to step 280 to turn off the compressor and the freezing and cooling fans. If the freezing temperature TF is below the set freezing temperature TFS in step 271, control also jumps to step 280 to turn off the compressor and the freezing and cooling fans.

Under the abnormal condition of the freezing and refrigerating compartments, as described above, the fifth embodiment enables the refrigerating compartment to be cooled first and then the freezing compartment to be cooled when the refrigerating temperature becomes below the set refrigerating temperature or is under the normal state of the first, like the fourth embodiment. Therefore, the fifth embodiment enables the freezing and refrigerating compartments to be cooled to the constant temperature because the freezing compartment is cooled together with the refrigerating compartment when the refrigerating temperature becomes higher than the set refrigerating temperature during cooling of the freezing compartment. This means that this embodiment has further advantages with those of the fourth embodiment.

On the other hand, step 280 proceeds to step 283 to determine whether the first surface temperature TES of the first evaporator is above 0ºC. If the first surface temperature TES is below 0ºC, the control proceeds to step 284 to turn off the compressor and the freezing fan and turn on the cooling fan and perform the defrosting of the first evaporator, like the other embodiments.

SIXTH EXAMPLE OF IMPLEMENTATION

Referring to Figs. 16 and 17, in step 291, it is determined whether the freezing temperature TF is above the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, control proceeds to step 292 to compare the refrigeration temperature TR with the second refrigeration set temperature TRS2 which is higher than the refrigeration temperature TRS by the predetermined temperature. If the refrigeration temperature TR is above the second refrigeration set temperature TRS2, step 292 proceeds to step 293 to turn on the compressor and the refrigeration fan and turn off the freezing fan. If the refrigeration temperature TR is below the second refrigeration set temperature TRS2, step 292 proceeds to step 294 to turn on the compressor and the freezing and refrigeration fans.

In other words, when the freezer compartment is under the abnormal condition due to the detection of the freezer temperature, the refrigerator compartment is cooled first regardless of its current state. Then, when the refrigerator temperature reaches the second set cooling temperature which is higher than the set cooling temperature by the predetermined temperature, the freezer compartment starts cooling. This prevents the cooling delay of the freezer compartment due to the cooling delay of the refrigerator compartment. At this time, it is desirable that the second set cooling temperature is higher than the set cooling temperature by 1ºC to 5ºC, particularly 2ºC. Thus, even before the refrigerator temperature reaches the set cooling temperature, the freezer compartment is cooled, thereby improving the cooling speed of both compartments. It is possible that this situation occurs at the start of operation.

After performing step 294, control proceeds to step 295 to compare the refrigeration temperature TR with the refrigeration set temperature TRS. If the refrigeration temperature TR is above the refrigeration set temperature TRs, step 295 proceeds to step 296 to compare the freezing temperature TF with the freezing set temperature TFS. However, if the refrigeration temperature TR is below the refrigeration set temperature TRS in step 295, control proceeds to step 297 to turn on the compressor and the freezing fan and turn off the refrigeration fan. If the freezing temperature TF is above the freezing set temperature TFS in step 296, step 296 returns to step 294 to turn on the compressor and the freezing and refrigeration fans. If the freezing temperature TF is below the set freezing temperature TFS, step 296 goes to step 298 to turn off the compressor and the freezing and cooling fans. On the other hand, step 297 goes to step 299 to compare the freezing temperature TF with the set freezing temperature TFS. If the freezing temperature TF is above the set freezing temperature TFS, step 299 returns to step 295. If the freezing temperature TF is below the set freezing temperature TFS, step 299 goes to step 298 to turn off the compressor and the freezing and cooling fans. If the freezing temperature TF is below the set freezing temperature TFS, the control also goes to step 298 to turn off the compressor and the freezing and cooling fans.

On the other hand, step 298 proceeds to step 300 to determine whether the first surface temperature TES of the first evaporator is above 0ºC. If the first surface temperature TES is below 0ºC, the control proceeds to step 300 to turn off the compressor and the freezing fan and to turn on the cooling fan. to switch on and defrost the first evaporator, as in the other embodiments.

When the freezing compartment is under the abnormal condition as a result of the detection of the freezing temperature, cooling of the refrigerating compartment starts as described above regardless of its current state. Therefore, the sixth embodiment can save energy like another embodiment and is also expected to improve the operating efficiency of the compressor by reducing the operating time thereof. Further, when the refrigerating temperature reaches the second set refrigerating temperature which is higher than the refrigerating set temperature, cooling of the refrigerating compartment starts, thereby increasing the cooling speed of both compartments.

SEVENTH EXAMPLE OF IMPLEMENTATION

Referring to Figs. 18 and 19, in step 311, it is determined whether the freezing temperature TF is above the set freezing temperature TFS. If the freezing temperature TF is above the set freezing temperature TFS, control proceeds to step 312 to compare the refrigeration temperature TR with the set refrigeration temperature TRS. If the refrigeration temperature TR is above the set refrigeration temperature TRS, control proceeds to step 313 to turn on the compressor and the refrigeration fan and turn off the freezing fan. If the refrigeration temperature TR is below the set refrigeration temperature TRS, control proceeds to step 314 to turn on the compressor and the refrigeration fan and turn off the refrigeration fan.

Step 313 proceeds to step 315 to compare the freezing temperature TF with a second set freezing temperature TFS2 which is the predetermined temperature is higher than the freezing temperature TFS. If the freezing temperature TF is below the second set freezing temperature TFS2, step 315 returns to step 312. If the freezing temperature TF is below the second set freezing temperature TFS2, control proceeds to step 316 to turn on the compressor and the freezing and refrigerating fan. In other words, as shown in Fig. 19A, under the abnormal condition of the freezing and refrigerating compartments, the refrigerating compartment is cooled first. Then, in order to prevent an abrupt rise in the freezing temperature during cooling of the refrigerating compartment, the freezing fan is operated when the freezing temperature becomes the second set freezing temperature which is higher than the set freezing temperature. This situation occurs when freezing is frequently used during cooling of the refrigerating compartment. At this time, it is desirable that the second set freezing temperature is higher than the set freezing temperature by 1ºC to 5ºC, particularly 2ºC.

Step 316 proceeds to step 317 to compare the refrigeration temperature TR with the refrigeration set temperature TRs. If the refrigeration temperature TR is above the refrigeration set temperature TRS, step 317 proceeds to step 318 to compare the freezing temperature TF with the freezing set temperature TFS. However, if the refrigeration temperature TR is below the refrigeration set temperature TRS in step 317, control proceeds to step 319 to turn on the compressor and the freezing fan and turn off the refrigeration fan. If the freezing temperature TF is above the freezing set temperature TFS, step 319 returns to step 316 to turn on the compressor and the freezing and refrigeration fans. If the freezing temperature TF is below the freezing set temperature TFS, step 319 returns to step 318. 320 to turn off the compressor and the freezer and refrigerator fans.

Step 319 also goes to step 321 to compare the freezer temperature TF with the set freezer temperature TFS. If the freezer temperature TF is above the set freezer temperature TFS, step 321 returns to step 319. If the freezer temperature TF is below the freezer set temperature TFS, step 321 returns to step 320 to turn off the compressor and the freezer and refrigeration fans. If the freezer temperature TF is below the freezer set temperature TFS in step 311, this step also jumps to step 320 to turn off the compressor and the freezer and refrigeration fans.

On the other hand, step 314 proceeds to step 322 to compare the freezing temperature TF with the set freezing temperature TFS. If the freezing temperature TF is above the set freezing temperature TFS, step 322 returns to step 314. If the freezing temperature TF is below the freezing set freezing temperature TFS, step 322 returns to step 320 to turn off the compressor and the freezing and refrigerating fans.

Step 320 proceeds to step 323 to determine whether the first surface temperature TES of the first evaporator is above 0ºC. If the first surface temperature TES is below 0ºC, the control proceeds to step 324 to turn off the compressor and the freezing fan and turn on the cooling fan and perform defrosting of the first evaporator, which is the same as another embodiment described above.

As described above, under the abnormal condition of the freezing and refrigerating compartments, the refrigerating compartment is cooled first and then the freezing compartment itself is cooled during the cooling of the refrigerating compartment when the freezing temperature becomes high regardless of the cooling level of the refrigerating compartment. Therefore, this enables the freezing and refrigerating compartments to be kept at the constant temperature. Actually, the seventh embodiment adopts the methods of first performing the cooling of the refrigerating compartment. It induces the efficient use of the energy. The operation of any of the freezing and refrigerating fans reduces the peak pressure of the compressor to improve the efficiency of the compressor.

EIGHTH EXAMPLE OF IMPLEMENTATION

Referring to Figs. 20 and 21, the eighth embodiment is modified from the seventh embodiment. First, the control performs step 331 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, the control proceeds to step 332 to compare the refrigeration temperature TR with the refrigeration set temperature TRS. If the refrigeration temperature TR is above the refrigeration set temperature TRS, the control proceeds to step 333 to turn on the compressor and the refrigeration fan and turn off the freezing fan. If the refrigeration temperature TR is below the refrigeration set temperature TRS, the control proceeds to step 334 to turn on the compressor and the refrigeration fan and turn off the refrigeration fan.

Step 333 proceeds to step 335 to compare the freezing temperature TF with a second set freezing temperature TFS2 which is set by the predetermined temperature is higher than the freezing temperature TFS. If the freezing temperature TF is below the second set freezing temperature TFS2, step 334 returns to step 332 to compare the refrigerating temperature TR with the refrigerating set temperature TRS. If the freezing temperature TF is above the second set freezing temperature TFS2, control proceeds to step 336 to turn on the compressor and the freezing and refrigerating fan. In other words, as shown in Fig. 21A, under the abnormal condition of the freezing and refrigerating compartments, the refrigerating compartment is cooled first. Then, in order to prevent the abrupt rise of the freezing temperature during cooling of the refrigerating compartment, the freezing fan is operated when the freezing temperature becomes the second set freezing temperature which is higher than the freezing set temperature. This situation occurs when freezing is frequently used during cooling of the refrigerating compartment. At this time, it is desirable that the second set freezing temperature be 1ºC to 5ºC, especially 2ºC higher than the set freezing temperature.

Step 336 proceeds to step 337 to compare the refrigeration temperature TR with the refrigeration set temperature TRs. If the refrigeration temperature TR is above the refrigeration set temperature TRS, step 337 proceeds to step 338 to compare the freezing temperature TF with the freezing set temperature TFS. If the refrigeration temperature TR is below the refrigeration set temperature TRS, control proceeds to step 334 to turn on the compressor and the freezing fan and turn off the refrigeration fan. If the freezing temperature TF is above the freezing set temperature TFS, step 338 returns to step 336 to turn on the compressor and the freezing fan and turn off the refrigeration fan. If the freezing temperature TF is below the freezing temperature TFS, step 338 returns to step 339 to turn off the compressor and the freezing and cooling fans.

On the other hand, step 334 advances to step 340 to compare the freezing temperature TF with the freezing set temperature TFS. If the freezing temperature TF is above the freezing set temperature TFS, step 340 advances to step 341 to compare the refrigerating temperature TR with the refrigerating set temperature TRS. If the refrigerating temperature TR is below the refrigerating set temperature TRS, the control executes step 339 to turn off the compressor and the freezing and refrigerating fans. If the refrigerating temperature TR is above the refrigerating set temperature TRS in step 341, step 336 is executed. If the refrigerating temperature TR is below the refrigerating set temperature TRS in step 341, step 334 is executed. If the freezing temperature TF in step 331 is below the set freezing temperature TFS, step 39 is performed to turn off the compressor and the freezing and cooling fans.

Step 339 proceeds to step 342 to compare the first surface temperature TES of the first evaporator with 0ºC. If the first surface temperature TES is below 0ºC, control proceeds to step 324 to turn off the compressor and the freezing fan and turn on the cooling fan and perform defrosting of the first evaporator, which is the same as another embodiment described above.

As described above, under the abnormal condition of the freezer and refrigerator compartments, the refrigerator compartment is cooled first and then the freezer compartment itself is cooled during the cooling of the refrigerator compartment when the Freezing temperature becomes high regardless of the cooling level of the refrigerator compartment. Therefore, this enables the freezing and the refrigerator compartment to be kept at the constant temperature. In fact, the seventh embodiment adopts the methods of first performing the cooling of the refrigerator compartment. It induces the efficient use of the energy. The operation of any of the freezing and the refrigerator fans reduces the peak pressure of the compressor to improve the efficiency of the compressor.

Consequently, a refrigerator comprises independently divided freezing and cooling compartments, each of which is equipped with an evaporator and an air circulation fan, so that each of them is controlled to reduce the temperature difference between the compartment and its evaporator, thereby reducing the thermodynamic non-reversible loss according to the system control and improving the energy efficiency.

Also, cooled air in the refrigerator compartment cannot circulate into the freezer compartment, so that an amount of frost condensing on a second evaporator is reduced, thereby improving the heat transfer efficiency of the second evaporator, and defrosting of a first evaporator is performed by using the cooling air having a relatively higher temperature while turning off a compressor and then allowing the melting moisture to circulate to create the high humidity environment in the refrigerator compartment, thereby enabling the preservation of fresh food for a long period of time.

The refrigerator also includes independently divided freezer and refrigerator compartments, which are equipped with a cooling system to regulate each compartment, improving the cooling speed of each compartment.

The refrigerator also includes independently divided freezer and refrigerator compartments, equipped with a cooling system to control each compartment independently, thus improving the air circulation speed, as well as to accurately detect the temperature by means of a sensor installed in each compartment, thus quickly responding to the temperature rise.

The refrigerator also includes completely separate freezer and refrigerator compartments to prevent odors emitted by stored foods such as pickled vegetables from circulating into each other.

The refrigerator also includes a cooling system provided with two evaporators arranged in series with each other and two fans, which simplifies the arrangement of the refrigeration cycle and allows a single refrigerant to be used, thereby improving mass production.

Claims (2)

1. A method for controlling a refrigerator with a compressor, a freezer and a refrigerator compartment, which are separate from each other, a first evaporator and a cooling fan, which are attached to the refrigerator compartment, and a second evaporator and a freezer fan, which are attached to the freezer compartment, and a cooling cycle, which comprises the following steps: i) in step 251, determining whether the freezing temperature is above a set freezing temperature or the cooling temperature is above a set cooling temperature; ii) in step 252, comparing the refrigeration temperature with the refrigeration set temperature if the freezer temperature is above the freezer set temperature or if the refrigeration temperature is above the refrigeration set temperature; iii) in step 253, comparing the freezing temperature with the freezing set temperature if the cooling temperature is above the cooling set temperature; iv) in step 254, switching on the compressor and the freezing and cooling fans if the freezing temperature is above the set freezing temperature; v) in step 255, switching on the compressor and the cooling fan and switching off the freezing fan if the Freezing temperature is below the set freezing temperature; vi) in step 256, comparing the freezing temperature with the set freezing temperature if the cooling temperature in step 252 is below the set cooling temperature; vii) in step 257, switching on the compressor and the freezer fan and switching off the cooling fan if the freezer temperature in step 256 is above the set freezer temperature; and viii)executing step 251 if the freezing temperature in step 256 is below the set freezing temperature. 2. Control method according to claim 1, wherein the set freezing temperature is between -21ºC and -15ºC and the set cooling temperature is between -1ºC and 6ºC.