Abstract:
Disclosed is a temperature control method for a refrigerator which can minimize a deviation in refrigerant compartment temperature while minimizing the power consumption of the refrigerator. The temperature control method includes the steps of (A) comparing a sensed temperature of a freezing compartment with a predetermined maximum freezing compartment temperature and a predetermined minimum freezing compartment temperature, respectively, thereby controlling a compressor and a circulating fan to be turned on or off such that the sensed freezing compartment temperature is ranged between the predetermined maximum and minimum freezing temperatures, (B) comparing, following the step (A), a sensed temperature of a refrigerating compartment defined with a plurality of refrigerating chambers therein, with a predetermined maximum refrigerating compartment temperature and a predetermined minimum refrigerating compartment temperature, respectively, thereby controlling a damper to be opened or closed and the circulating fan to be turned on or off such that the sensed refrigerating compartment temperature is ranged between the predetermined maximum and minimum refrigerating temperatures, and (C) discharging cold air into at least one of the refrigerating chambers when the damper is closed, and the compressor and the circulating fan are turned on.

Description:
BACKGROUND OF THE INVENTION 
   1. Field of the Invention 
   The present invention relates to a temperature control method for a refrigerator, and more particularly to a temperature control method for a refrigerator which can supply cold air to insufficiently cooled regions in a refrigerating compartment of the refrigerator without an additional turning-on of a compressor and circulating fan included in the refrigerator, thereby being capable of minimizing a temperature deviation of the refrigerating compartment while minimizing the power consumption of the refrigerator. 
   2. Description of the Related Art 
   Generally, a refrigerator is an apparatus in which freezing and refrigerating compartments are maintained at desired low temperatures by a refrigerant cooling cycle consisting of a compressor, a condenser, a capillary valve, and an evaporator. 
     FIG. 1  is a perspective view of a conventional refrigerator, illustrating the condition in which freezing and refrigerating compartments are in an opened state. 
   As shown in  FIG. 1 , the conventional refrigerator includes a refrigerator body in which a freezing compartment F and a refrigerating compartment R are defined by a barrier  2  at opposite sides of the barrier  2 , respectively. A freezing compartment door  4  is hingably mounted to the refrigerator body in front of the freezing compartment F. A refrigerating compartment door  6  is also hingably mounted to the refrigerator body in front of the refrigerating compartment R. 
     FIG. 2  is a front view showing the inner structure of the conventional refrigerator.  FIG. 3  is a side view showing the inner structure of the refrigerating compartment in the conventional refrigerator. 
   An evaporator  8  is installed in rear of the freezing compartment F. The evaporator  8  absorbs heat from air in the freezing compartment F or refrigerating compartment R through heat exchange between the air and a refrigerant passing through the evaporator  8 . In accordance with the heat absorption, the refrigerant evaporates. A circulating fan  10  is also installed in rear of the freezing compartment F in order to forcibly convect the air, cooled in accordance with the heat absorption of the evaporator  8 , into the freezing compartment F or refrigerating compartment R. 
   The freezing compartment F is provided, at the upper portion of a rear wall thereof, with cold air discharge holes  12  adapted to discharge the air cooled by the evaporator  8 , that is, cold air, into the freezing compartment F in accordance with the operation of the circulating fan  10 . The freezing compartment F is also provided, at the lower portion of the rear wall thereof, with cold air return holes  14  adapted to return the cold air, used to cool the freezing compartment F to a desired freezing temperature, to the evaporator  8 . 
   The freezing compartments F is partitioned into a plurality of freezing chambers F 1  to F 6 . A plurality of shelves  15  to  19  are installed in the freezing chamber F such that they are vertically spaced apart from one another. Food or containers may be laid on the shelves  15  to  19 . 
   The barrier  2  is provided, at its upper portion, with a cold air discharge duct  21  for partially discharging the cold air produced by the evaporator  8  into the refrigerating compartment R in accordance with the operation of the circulating fan  10 . The barrier  2  is also provided, at its lower portion, with a cold air return duct  22  for returning the cold air, used to cool the freezing compartment F to a desired freezing temperature, to the evaporator  8 . 
   A damper  24  is installed at one side of the cold air discharge duct  21  or at the upper portion of the refrigerating compartment R. The damper  24  is opened or closed to determine whether nor not the cold air has to be discharged into the refrigerating compartment R. 
   On the other hand, the refrigerating compartment R is partitioned into a plurality of refrigerating chambers R 1  to R 6 . A plurality of refrigerating compartment shelves  25  to  28  are installed in the refrigerating chamber R such that they are vertically spaced apart from one another. Food or containers may be laid on the refrigerating compartment shelves  25  to  28 . 
   A plurality of baskets  31  to  35  adapted to receive food or containers are mounted to the back surface of the refrigerating compartment door  6  such that they are vertically spaced apart from one another. 
   The refrigerating compartment shelves  25  to  29  are spaced apart from the baskets  31  to  35  respectively arranged adjacent thereto and from the back surface of the refrigerating compartment door  6 , so as to define a cold air passage. 
   The reference numeral  44  designates a freezing compartment temperature sensor for sensing a temperature at one side of the freezing compartment F, and the reference numeral  45  designates a refrigerating compartment temperature sensor for sensing a temperature at one side of the refrigerating compartment R. 
     FIG. 4  is a control block diagram of the conventional refrigerator. 
   As shown in  FIG. 3 , the conventional refrigerator further includes a compressor  41  for compressing a gaseous refrigerant of low temperature and low pressure emerging from the evaporator  8 , thereby producing a gaseous refrigerant of high temperature and high pressure, a condenser for discharging heat from the gaseous refrigerant of high temperature and high pressure into the atmosphere, thereby condensing the gaseous refrigerant to produce a liquid refrigerant of intermediate temperature and high pressure, a capillary valve for reducing the pressure of the high-pressure liquid refrigerant emerging from the condenser, and a compressor cooling fan  42  for cooling the compressor  41  in order to prevent the compressor  41  from over-heating. 
   The refrigerator also includes a temperature setting unit  43  for setting predetermined maximum and minimum temperatures of the freezing and refrigerating compartments F and R, and a control unit  46  for comparing sensed temperatures of the freezing and refrigerating compartments F and R with the predetermined maximum and minimum temperatures associated therewith, respectively, thereby controlling the opening/closing of the damper  24  and the turning-on/off of the circulating fan  10 , compressor  41 , and compressor cooling fan  42 . 
   The predetermined maximum and minimum temperatures may be set to correspond to a temperature obtained by adding a predetermined temperature tolerance to a desired temperature set by the user, and a temperature obtained by deducting the predetermined temperature tolerance from the set temperature, respectively. Alternatively, the predetermined maximum and minimum temperatures may be independently set. 
   Now, a temperature control method for the conventional refrigerator having the above mentioned configuration will be described. 
     FIG. 5  is a flow chart illustrating the temperature control method for the conventional refrigerator. 
   First, the control unit  46  compares the temperature T f  of the freezing compartment F sensed by the freezing compartment temperature sensor  44  with the predetermined maximum temperature T f max of the freezing compartment F (S 1 ). 
   The predetermined maximum freezing compartment temperature T f max corresponds to a temperature obtained by adding a predetermined temperature tolerance to a desired freezing compartment temperature set by the user. 
   The control unit  46  turns on the circulating fan  10 , compressor  41 , and compressor cooling fan  42  when it determines that the temperature T f  of the freezing compartment F is equal to or more than the predetermined maximum temperature T f max of the freezing compartment F (S 2 ). 
   When the circulating fan  10  and compressor  41  are turned on, air present in the freezing compartment F circulates between the evaporator  20  and the freezing compartment F, thereby causing the freezing compartment F to be cooled to a desired freezing temperature. 
   Thereafter, the control unit  46  compares the temperature T r  of the refrigerating compartment R sensed by the refrigerating compartment temperature sensor  45  with the predetermined maximum temperature T r max of the refrigerating compartment R (S 3 ). 
   The predetermined maximum refrigerating compartment temperature T r max corresponds to a temperature obtained by adding a predetermined temperature tolerance to a desired refrigerating compartment temperature set by the user. 
   The control unit  46  opens the damper  24  when it determines that the temperature T r  of the refrigerating compartment R is equal to or more than the predetermined maximum temperature T r max of the refrigerating compartment R (S 4 ). 
   When the damper  24  is opened, a part of the air cooled by the evaporator  8  is discharged into the refrigerating compartment R via the cold air discharge duct  21 . The discharged cold air cools the interior of the refrigerating compartment R to a desired refrigerating temperature while being convected in the interior of the refrigerating compartment R. Subsequently, the cold air flows toward the lower portion of the refrigerating compartment R, and then returns to the evaporator  8  through the cold air return duct  22 . 
   On the other hand, if it is determined at step S 3  that the temperature T r  of the refrigerating compartment R is less than the predetermined maximum temperature T r max of the refrigerating compartment R, the control unit  46  then compares the temperature T r  of the refrigerating compartment R with the predetermined minimum temperature T r min of the refrigerating compartment R (S 5 ). 
   The predetermined minimum refrigerating compartment temperature T r min corresponds to a temperature obtained by deducting a predetermined temperature tolerance to a desired refrigerating compartment temperature set by the user. 
   The control unit  46  closes the damper  24  when it determines that the temperature T r  of the refrigerating compartment R is less than the predetermined minimum temperature T r min of the refrigerating compartment R (S 6 ). 
   When the damper  24  is closed, the cold air is discharged into the refrigerating compartment R no longer. Accordingly, the interior of the refrigerating compartment R is not over-cooled. 
   On the other hand, if it is determined at step S 1  that the temperature T f  of the freezing compartment F is less than the predetermined maximum temperature T f max of the freezing compartment F, the control unit  46  then compares the temperature T f  of the freezing compartment F with the predetermined minimum temperature T f min of the freezing compartment F (S 7 ). 
   The predetermined minimum freezing compartment temperature T f min corresponds to a temperature obtained by deducting a predetermined temperature tolerance to a desired freezing compartment temperature set by the user. 
   When it is determined that the temperature T f  of the freezing compartment F is less than the predetermined maximum temperature T f max of the freezing compartment F, the control unit  46  turns off the compressor  41  and compressor cooling fan  42 . 
   In the OFF state of the compressor  41 , the refrigerant temperature of the evaporator  20  increases with the lapse of time. As a result, the temperature of the cold air circulating between the freezing compartment F and the evaporator  8  is increased due to a load in the freezing compartment F, so that the interior of the freezing compartment F is not over-cooled. 
   Thereafter, the control unit  46  again compares the temperature T r  of the refrigerating compartment R sensed by the refrigerating compartment temperature sensor  45  with the predetermined maximum temperature T r max of the refrigerating compartment R (S 9 ). 
   When it is determined that the temperature T r  of the refrigerating compartment R is equal to or more than the predetermined maximum temperature T r max of the refrigerating compartment R, the control unit  46  again opens the damper  24 , and again turns on the circulating fan (S 10 ). 
   When the damper  24  is opened, and the circulating fan  10  is turned on, a part of the air cooled by the evaporator  8  is discharged into the refrigerating compartment R via the cold air discharge duct  21 . The discharged cold air cools the interior of the refrigerating compartment R to a desired refrigerating temperature while being convected in the interior of the refrigerating compartment R. Subsequently, the cold air flows toward the lower portion of the refrigerating compartment R, and then returns to the evaporator  8  through the cold air return duct  22 . 
   On the other hand, if it is determined at step S 9  that the temperature T r  of the refrigerating compartment R is less than the predetermined maximum temperature T r max of the refrigerating compartment R, the control unit  46  then again compares the temperature T r  of the refrigerating compartment R with the predetermined minimum temperature T r min of the refrigerating compartment R (S 11 ). 
   The control unit  46  again closes the damper  24  and turns off the circulating fan  10  when it determines that the temperature T r  of the refrigerating compartment R is less than the predetermined minimum temperature T r min of the refrigerating compartment R (S 12 ). 
   When the damper  24  is closed, and the circulating fan  10  is turned off, the cold air is discharged into the refrigerating compartment R no longer. Accordingly, the interior of the refrigerating compartment R is not over-cooled. 
   However, the above mentioned convention refrigerator temperature control method has a limitation in uniformly convecting the cold air, discharged into the refrigerating compartment R, in the interior of the refrigerating compartment R. For this reason, in the refrigerating compartment R, there may be an insufficiently cooled region where convection of the cold air is ineffectively carried out. As a result, there may be a temperature deviation in the refrigerating compartment R. 
   In order to eliminate such a temperature deviation in the refrigerating compartment R, a proposal for separately discharging cold air into the insufficiently cooled region has been made. In accordance with this proposal, a second cold air discharge duct is provided in the interior of the barrier  2 , and a nozzle is connected to the second cold air discharge duct while being arranged such that it injects cold air into the insufficiently cooled region. In accordance with such a configuration, it is possible to more or less reduce the temperature deviation of the refrigerating compartment R caused by the non-uniform cold air convection. However, such a temperature deviation reduction is low in a state in which both the nozzle and the damper  24  are opened. 
   SUMMARY OF THE INVENTION 
   The present invention has been made in view of the above mentioned problems involved with the related art, and an object of the invention is to provide a temperature control method for a refrigerator which can minimize a deviation in refrigerant compartment temperature while minimizing the power consumption of the refrigerator. 
   In accordance with one aspect, the present invention provides a temperature control method for a refrigerator comprising the steps of: (A) comparing a sensed temperature of a freezing compartment defined in the refrigerator with a predetermined maximum freezing compartment temperature and a predetermined minimum freezing compartment temperature, respectively, thereby controlling a compressor and a circulating fan included in the refrigerator to be turned on or off such that the sensed freezing compartment temperature is ranged between the predetermined maximum and minimum freezing temperatures; (B) comparing, following the step (A), a sensed temperature of a refrigerating compartment, defined in the refrigerator while being defined with a plurality of refrigerating chambers therein, with a predetermined maximum refrigerating compartment temperature and a predetermined minimum refrigerating compartment temperature, respectively, thereby controlling a damper included in the refrigerator to be opened or closed and the circulating fan to be turned on or off such that the sensed refrigerating compartment temperature is ranged between the predetermined maximum and minimum refrigerating temperatures; and (C) discharging cold air into at least one of the refrigerating chambers when the damper is closed at the step (B) under a condition in which the compressor and the circulating fan are turned on at the step (A). 
   In accordance with another aspect, the present invention provides a temperature control method for a refrigerator comprising the steps of: (A) comparing a sensed temperature of a freezing compartment defined in the refrigerator with a predetermined maximum freezing compartment temperature and a predetermined minimum freezing compartment temperature, respectively, thereby controlling a compressor and a circulating fan included in the refrigerator to be turned on or off such that the sensed freezing compartment temperature is ranged between the predetermined maximum and minimum freezing temperatures; (B) comparing, following the step (A), a sensed temperature of a refrigerating compartment, defined in the refrigerator while being defined with a plurality of refrigerating chambers therein, with a predetermined maximum refrigerating compartment temperature and a predetermined minimum refrigerating compartment temperature, respectively, thereby controlling a damper included in the refrigerator to be opened or closed and the circulating fan to be turned on or off such that the sensed refrigerating compartment temperature is ranged between the predetermined maximum and minimum refrigerating temperatures; and (C) discharging cold air into at least one of the refrigerating chambers in response to an opening signal outputted from a nozzle timer included in the refrigerator when the damper is closed at the step (B) under a condition in which the compressor and the circulating fan are turned on at the step (A). 

   
     BRIEF DESCRIPTION OF THE DRAWINGS 
     The above objects, and other features and advantages of the present invention will become more apparent after reading the following detailed description when taken in conjunction with the drawings, in which: 
       FIG. 1  is a perspective view of a conventional refrigerator, illustrating the condition in which freezing and refrigerating compartments are in an opened state; 
       FIG. 2  is a front view showing the inner structure of the conventional refrigerator; 
       FIG. 3  is a side view showing the inner structure of the refrigerating compartment in the conventional refrigerator; 
       FIG. 4  is a control block diagram of the conventional refrigerator; 
       FIG. 5  is a flow chart illustrating a temperature control method for the conventional refrigerator; 
       FIG. 6  is a front view illustrating the inner structure of a refrigerator according to the present invention; 
       FIG. 7  is a side view illustrating the inner structure of a refrigerating compartment in the refrigerator according to the present invention; 
       FIG. 8  is a control block diagram of the refrigerator according to the present invention; 
       FIG. 9  is a flow chart illustrating a temperature control method for the refrigerator having the above described configuration in accordance with an embodiment of the present invention; and 
       FIG. 10  is a timing diagram illustrating operations of the refrigerator carried out in accordance with the temperature control method of the present invention. 
   

   DESCRIPTION OF THE PREFERRED EMBODIMENTS 
   Now, preferred embodiments of the present invention will be described in detail with reference to the annexed drawings. 
     FIG. 6  is a front view illustrating the inner structure of a refrigerator according to the present invention.  FIG. 7  is a side view illustrating the inner structure of a refrigerating compartment in the refrigerator according to the present invention. 
   The refrigerator of the present invention shown in  FIGS. 6 and 7  has the same basic structure as that of the conventional refrigerator shown in  FIGS. 2 and 3 . Constituent elements included in the basic structure shown in  FIGS. 6 and 7  are designated by the same reference numerals as those of  FIGS. 2 and 3 , respectively, and no detailed description thereof will be given. In the refrigerator of the present invention, as shown in  FIGS. 6 and 7 , a second cold air discharge duct  52  is formed at the barrier  2  such that it communicates, at one end thereof, with the cold air discharge duct  21  while communicating, at the other end thereof, with a part of the refrigerating chambers R 1  to R 6 , for example, the refrigerating chambers R 2 , R 3 , and R 4 . Nozzles  62  to  64  are mounted to the other end of the second cold air discharge duct  52  in order to inject cold air, passing through the second cold air discharge duct  52 , into the refrigerating chambers R 2  to R 4 , respectively. Nozzle motors  72  to  74  are coupled to respective nozzles  62  to  64 . Each of the nozzle motors  72  to  74  serves to rotate an associated one of the nozzles  62  to  64  between a closed position where the outlet of the associated nozzle is directed toward the barrier  2  and an opened position where the outlet of the associated nozzle is directed toward an associated one of the refrigerating chamber R 2  to R 4 . The refrigerator of the present invention has the same structure as that of the conventional refrigerator, except for the second cold air discharge duct  52 , nozzles  62  to  64 , and nozzle motors  72  to  74 . 
     FIG. 8  is a control block diagram of the refrigerator according to the present invention. 
   Under the condition in which both the circulating fan  10  and the compressor  41  are in their ON state, and the damper  24  is in its closed state, the control unit  46  turns on the nozzle motors  72  to  74  in order to open respective outlets of the nozzles  62  to  64 . 
   The refrigerator according to the illustrated embodiment of the present invention further includes a nozzle timer  82  for periodically outputting an opening signal and a closing signal in order to open and close the nozzles  62  to  64  at intervals of a predetermined time. When the nozzle timer  82  outputs an opening signal under the condition in which both the circulating fan  10  and the compressor  41  are in their ON state, and the damper  24  is in its closed state, the control unit  46  turns on the nozzle motors  72  to  74  to open respective outlets of the nozzles  62  to  64 . 
     FIG. 9  is a flow chart illustrating a temperature control method for the refrigerator having the above described configuration in accordance with an embodiment of the present invention. 
   First, the control unit  46  compares the temperature T f  of the freezing compartment F sensed by the freezing compartment temperature sensor  44  with the predetermined maximum temperature T f max of the freezing compartment F (S 11 ). 
   When it is determined at step S 11  that the temperature T f  of the freezing compartment F is equal to or more than the predetermined maximum temperature T f max of the freezing compartment F, the control unit  46  turns on the circulating fan  10  and compressor  41  (S 12 ). 
   The control unit  46  also turns on the compressor cooling fan  42 , simultaneously with the turning-on of the compressor  41 . 
   When the circulating fan  10  and compressor  41  are turned on, air present in the freezing compartment F circulates between the evaporator  20  and the freezing compartment F, thereby causing the freezing compartment F to be cooled to a desired freezing temperature. 
   Thereafter, the control unit  46  compares the temperature T r  of the refrigerating compartment R sensed by the refrigerating compartment temperature sensor  45  with the predetermined maximum temperature T r max of the refrigerating compartment R (S 13 ). 
   The control unit  46  opens the damper  24  when it determines that the temperature T r  of the refrigerating compartment R is equal to or more than the predetermined maximum temperature T r max of the refrigerating compartment R (S 14 ). 
   When the damper  24  is opened, a part of the air cooled by the evaporator  8  is discharged into the upper portion of the refrigerating compartment R via the cold air discharge duct  21 . The discharged cold air cools the interior of the refrigerating compartment R to a desired refrigerating temperature while being convected in the interior of the refrigerating compartment R. Subsequently, the cold air flows toward the lower portion of the refrigerating compartment R, and then returns to the evaporator  8  through the cold air return duct  22 . 
   During the above operation, the control unit  46  also controls the nozzle motors  72  to  74  to cause respective outlets of the nozzles  62  to  64  to are directed toward the barrier  2 , irrespective of an opening/closing signal from the nozzle timer  82  (S 15 ). Accordingly, the nozzles  62  to  64  are maintained in their closed state. 
   In the closed state of the nozzles  62  to  64 , the cold air passing through the cold air discharge duct  21  cannot be injected into the refrigerating chambers R 2 , R 3 , and R 4  through the nozzles  62  to  64 . That is, the whole part of the cold air is discharged into the upper portion of the refrigerating compartment R. The cold air introduced into the refrigerating compartment R cools the interior of the refrigerating compartment R to a desired refrigerating temperature while being convected throughout the interior of the refrigerating compartment R. 
   On the other hand, if it is determined at step S 13  that the temperature T r  of the refrigerating compartment R is less than the predetermined maximum temperature T r max of the refrigerating compartment R, the control unit  46  then compares the temperature T r  of the refrigerating compartment R with the predetermined minimum temperature T r min of the refrigerating compartment R (S 16 ). 
   The control unit  46  closes the damper  24  when it determines that the temperature T r  of the refrigerating compartment R is less than the predetermined minimum temperature T r min of the refrigerating compartment R (S 17 ). 
   When the damper  24  is closed, the cold air is discharged into the refrigerating compartment R no longer. Accordingly, the interior of the refrigerating compartment R is not over-cooled. 
   Meanwhile, under the condition in which both the circulating fan  10  and the compressor  41  are in their ON state, and the damper  24  is in its closed state, the control unit  46  controls the nozzle motors  72  to  74  to cause respective outlets of the nozzles  62  to  64  to be directed toward the refrigerating chambers R 2 , R 3 , and R 4  (S 19 ). In this state, the nozzles  62  to  64  are opened. 
   Alternatively, the control unit  46  may be configured to control the nozzle motors  72  to  74  to cause respective outlets of the nozzles  62  to  64  to be directed toward the refrigerating chambers R 2 , R 3 , and R 4 , in response to an opening signal outputted from the nozzle timer  82  under the condition in which both the circulating fan  10  and the compressor  41  are in their ON state, and the damper  24  is in its closed state (S 18  and S 19 ). 
   That is, it may be possible to determine whether or not the nozzles  62  to  64  have to be opened, only based on the states of the circulating fan  10 , compressor  41 , and damper  24 . Alternatively, this determination may be achieved, based on the operation of the nozzle timer  82  in addition to the states of the circulating fan  10 , compressor  41 , and damper  24 . 
   When the nozzles  62  to  64  are opened, the cold air, which has been confined in the second cold air discharge duct  52  due to the closed state of the damper  24 , is discharged into the refrigerating chambers R 2 , R 3  and R 4  through the opened nozzles  62  to  64 , respectively. 
   The discharged cold air cools the refrigerating chambers R 2 , R 3 , and R 4  to a desired refrigerating temperature. Subsequently, the cold air flows toward the lower portion of the refrigerating compartment R, and then returns to the evaporator  8  through the cold air return duct  22 . 
   Thus, it is possible to cool, to a desired refrigerating temperature, insufficiently cooled regions formed when the temperature T r  of the refrigerating compartment R is less than the predetermined maximum temperature T r max of the refrigerating compartment R, without additional operations of the compressor  41  and circulating fan  10 . 
   When the control unit  46  is configured to take into consideration the opening/closing signal outputted from the nozzle timer  82  in determining the opening/closing of the nozzles  62  to  64 , it controls the nozzle motors  72  to  74  so that the outlets of the nozzles  62  to  64  are directed toward the barrier  2  in response to a closing signal outputted from the nozzle timer  82 , even when both the circulating fan  10  and the compressor  41  are in their ON state, and the damper  24  is in its closed state (S 18  and S 20 ). 
   In the closed state of the nozzles  62  to  64 , no cold air is discharged into the refrigerating chambers R 2 , R 3  and R 4  through the nozzles  62  to  64 . Accordingly, the refrigerating chambers R 2 , R 3 , and R 4  are not over-cooled. 
   Thus, it is possible to minimize the temperature deviation of the refrigerating compartment while preventing the insufficiently cooled regions from being over-cooled, by discharging cold air into the insufficiently cooled regions only in response to an opening signal outputted from the nozzle timer  82 , that is, only when the nozzle timer  82  is in its ON state. 
   On the other hand, if it is determined at step S 11  that the temperature T f  of the freezing compartment F is less than the predetermined maximum temperature T f max of the freezing compartment F, the control unit  46  then compares the temperature T f  of the freezing compartment F with the predetermined minimum temperature T f min of the freezing compartment F (S 21 ). 
   When it is determined that the temperature T f  of the freezing compartment F is less than the predetermined maximum temperature T f max of the freezing compartment F, the control unit  46  turns off the compressor  41 . 
   The control unit  46  also turns off the compressor cooling fan  42 , simultaneously with the turning-off of the compressor  41 . 
   In the OFF state of the compressor  41 , the refrigerant temperature of the evaporator  20  increases with the lapse of time. As a result, the temperature of the cold air circulating between the freezing compartment F and the evaporator  8  is increased due to a load in the freezing compartment F, so that the interior of the freezing compartment F is not over-cooled. 
   Thereafter, the control unit  46  again compares the temperature T r  of the refrigerating compartment R sensed by the refrigerating compartment temperature sensor  45  with the predetermined maximum temperature T r max of the refrigerating compartment R (S 23 ). 
   When it is determined that the temperature T r  of the refrigerating compartment R is equal to or more than the predetermined maximum temperature T r max of the refrigerating compartment R, the control unit  46  again opens the damper  24 , and again turns on the circulating fan (S 24 ). 
   When the damper  24  is opened, and the circulating fan  10  is turned on, a part of the air cooled by the evaporator  8  is discharged into the refrigerating compartment R via the cold air discharge duct  21 . The discharged cold air cools the interior of the refrigerating compartment R to a desired refrigerating temperature while being convected in the interior of the refrigerating compartment R. Subsequently, the cold air flows toward the lower portion of the refrigerating compartment R, and then returns to the evaporator  8  through the cold air return duct  22 . 
   During the above operation, the control unit  46  also controls the nozzle motors  72  to  74  to cause respective outlets of the nozzles  62  to  64  to be directed toward the barrier  2 , irrespective of an opening/closing signal from the nozzle timer  82  (S 25 ). Accordingly, the nozzles  62  to  64  are maintained in their closed state. 
   In the closed state of the nozzles  62  to  64 , the cold air passing through the cold air discharge duct  21  cannot be injected into the refrigerating chambers R 2 , R 3 , and R 4  through the nozzles  62  to  64 . That is, the whole part of the cold air is discharged into the upper portion of the refrigerating compartment R. The cold air introduced into the refrigerating compartment R cools the interior of the refrigerating compartment R to a desired refrigerating temperature while being convected throughout the interior of the refrigerating compartment R. 
   On the other hand, if it is determined at step S 23  that the temperature T r  of the refrigerating compartment R is less than the predetermined maximum temperature T r max of the refrigerating compartment R, the control unit  46  then compares the temperature T r  of the refrigerating compartment R with the predetermined minimum temperature T r min of the refrigerating compartment R (S 26 ). 
   The control unit  46  closes the damper  24  while turning off the circulating fan  10  when it determines that the temperature T r  of the refrigerating compartment R is less than the predetermined minimum temperature T r min of the refrigerating compartment R (S 27 ). 
   When the damper  24  is closed, and the circulating fan  10  is turned off, the cold air is discharged into the refrigerating compartment R no longer. Accordingly, the interior of the refrigerating compartment R is not over-cooled. 
   Since the circulating fan  10  is in its OFF state, the control unit  46  controls the nozzle motors  72  to  74  so that respective outlets of the nozzles  62  to  64  are directed toward the barrier  2 , irrespective of an opening/closing signal from the nozzle timer  82  (S 15 ). Accordingly, the nozzles  62  to  64  are maintained in their closed state. 
   In the closed state of the nozzles  62  to  64 , the cold air passing through the cold air discharge duct  21  cannot be injected into the refrigerating chambers R 2 , R 3 , and R 4  through the nozzles  62  to  64 . Accordingly, the refrigerating chambers R 2 , R 3 , and R 4  are not over-cooled. 
   That is, when the circulating fan  10  is turned off in the closed state of the damper  24 , the nozzles  62  to  64  are closed in spite of the closed state of the damper  24 . Accordingly, it is possible to prevent the nozzle motors  72  to  74  from operating unnecessarily, thereby preventing an unnecessary increase in power consumption. 
   The ON/OFF timing of the compressor  41 , circulating fans  10 , and damper  24 , and the opening/closing timing of the nozzles  62  to  64  are shown in FIG.  10 . 
     FIG. 10  is a timing diagram illustrating operations of the refrigerator carried out in accordance with the temperature control method of the present invention. 
   In  FIG. 10 , “P 1 ”, “P 2 ” and “P 3 ” are periods in which cold air is discharged through the nozzles  62  to  64 , respectively. In the periods P 1 , P 2 , and P 3 , the circulating fan  10 , compressor  41 , and nozzle timer  82  are in their ON state, whereas the damper  24  is in its OFF (closed) state. 
   The ON/OFF states of the compressor  41 , circulating fans  10 , and damper  24 , and the opening/closing state of the nozzles  62  to  64  have a relation shown in Table 1. 
   
     
       
             
             
             
             
             
           
         
             
                 
               TABLE 1 
             
             
                 
                 
             
             
                 
               Compressor 
               Circulating Fan 
               Damper 
               Nozzles 
             
             
                 
                 
             
           
           
             
                 
               ON 
               ON 
               ON 
               Closed 
             
             
                 
               ON 
               ON 
               OFF 
               Opened 
             
             
                 
               OFF 
               ON 
               ON 
               Closed 
             
             
                 
               OFF 
               OFF 
               OFF 
               Closed 
             
             
                 
                 
             
           
        
       
     
   
   As shown in Table 1 and  FIG. 10 , cold air is discharged into the insufficiently cooled regions of the refrigerating compartment R when the circulating fan  10  and compressor  41  are in their ON state, and the damper  24  is in its OFF state, or when the nozzle timer is in its ON state under the condition in which the circulating fan  10  and compressor  41  are in their ON state, and the damper  24  is in its OFF state. Accordingly, it is possible to reduce the temperature deviation of the refrigerating compartment R without an additional turning-on of the circulating fan  10  and compressor  41 . 
   As apparent from the above description, in accordance with the refrigerator temperature control method according to the present invention, cold air is discharged into a part of the refrigerating chambers when the circulating fan and compressor are in their ON state, and the damper is in its OFF state. Accordingly, it is possible to reduce a temperature deviation occurring in the refrigerating compartment. Also, such a temperature deviation reduction can be achieved in accordance with opening/closing of the nozzles without additional operations of the compressor and circulating fan. Accordingly, an improvement in power consumption efficiency can be achieved. 
   Also, cold air may be discharged into a part of the refrigerating chambers in response to an opening signal outputted from the nozzle timer under the condition in which the circulating fan and compressor are in their ON state, and the damper is in its OFF state. In this case, there is an advantage in that it is possible to prevent the refrigerating chambers, supplied with the cold air through the nozzles, from being over-cooled. 
   Although the preferred embodiments of the invention have been disclosed for illustrative purposes, those skilled in the art will appreciate that various modifications, additions and substitutions are possible, without departing from the scope and spirit of the invention as disclosed in the accompanying claims.