RU2409794C1 - Refrigerator - Google Patents

Abstract

FIELD: heating.

SUBSTANCE: refrigerator has assembly compartment, compressor arranged in assembly compartment, and cooling fan of assemblies for air cooling assemblies, which is located in assembly compartment, ambient temperature sensor having the possibility of ambient temperature measurement around the refrigerator, failure monitor having the possibility of detecting emergency stop of cooling fan of assemblies, controller having the possibility to stop the compressor if failure monitor detects emergency stop of cooling fan of assemblies and if ambient temperature measured with ambient temperature sensor is higher than the specified value and display device having the possibility of displaying the failure of the cooling fan assemblies when the controller stops the compressor.

EFFECT: refrigerator is capable of preventing excess temperature increase of assembly compartment in which assembly cooling fan is installed, and temperature of outer housing of refrigerator of cooling fan of assemblies is stopped in case of fault.

17 cl, 11 dwg

Description

BACKGROUND OF THE INVENTION

FIELD OF THE INVENTION

The present invention relates to a refrigerator.

State of the art

The refrigerator has an aggregate compartment of limited volume to accommodate units such as a compressor and condenser. The units generate heat and therefore a cooling fan is also installed in the aggregate compartment to cool the units. There is the possibility of failures or stops of the cooling fan for units. If a unit, such as a compressor, is used continuously while the unit cooling fan is stopped, the temperature of the compressor increases, heating the refrigerant in the compressor and increasing the temperature of the cooling pipe laid on the outside of the refrigerator case. At high ambient temperatures, the temperature of the outer casing increases excessively.

In order to deal with such an emergency stop of the cooling fan of the refrigerator unit, prior art, such as Japanese publication of the unexamined patent application No. 2003-121032, discloses a technique for preventing food spoilage in the refrigerator in the event of failure of the unit cooling fan. If the cooling fan of the units stops abnormally, then in the prior art, the compressor in the unit compartment operates at a low speed without tripping the overload relay, thereby continuously cooling the inside of the refrigerator. In the prior art, however, when the refrigerator compressor at an emergency stop of the cooling fan of the units starts to operate at a low speed, the ambient temperature is not checked. If the ambient temperature during malfunctions of the unit cooling fan is relatively low, the compressor can operate continuously in normal mode, without generating heat or without excessive increase in refrigerant temperature. In this case, forced operation of the compressor at a low speed impairs the cooling efficiency of the refrigerator.

SUMMARY OF THE INVENTION

An object of the present invention is to provide a refrigerator capable of coping with an emergency stop of the unit cooling fan for cooling the unit compartment of the refrigerator and preventing an excessive temperature increase of the compressor installed in the unit compartment and the temperature of the external refrigerator case.

To accomplish the task, an aspect of the present invention provides a refrigerator having an aggregate compartment, a compressor disposed in the aggregate compartment, and an aggregate cooling fan for air cooling units housed in the aggregate compartment. The refrigerator includes an ambient temperature sensor configured to measure the ambient temperature around the refrigerator; a failure monitor configured to detect an emergency stop of the unit cooling fan; a controller configured to stop the compressor if the failure monitor detects an emergency stop of the unit cooling fan and if the ambient temperature measured by the ambient temperature sensor is higher than a predetermined value; and a display device configured to display a failure of the unit cooling fan when the controller stops the compressor.

Another aspect of the present invention provides a refrigerator having an aggregate compartment, a compressor disposed in the aggregate compartment, and a unit cooling fan for air cooling units housed in the aggregate compartment. The refrigerator includes an ambient temperature sensor configured to measure the ambient temperature around the refrigerator; a failure monitor configured to detect an emergency stop of the unit cooling fan; a controller configured to operate the compressor at a speed below normal operating speed if the monitor detects an emergency stop of the cooling fan of the units to monitor failures and if the ambient temperature measured by the ambient temperature sensor is above a predetermined value; and a display device configured to display a failure of the cooling fan of the units when the controller operates the compressor at a reduced speed.

Another aspect of the present invention provides a refrigerator having an aggregate compartment, a compressor disposed in the aggregate compartment, and a unit cooling fan for air cooling units housed in the aggregate compartment. The refrigerator includes an ambient temperature sensor configured to measure the ambient temperature around the refrigerator; a failure monitor configured to detect an emergency stop of the unit cooling fan; a controller configured to perform periodic compressor operation at intervals shorter than normal intervals if the failure monitor detects an emergency stop of the unit cooling fan and if the ambient temperature measured by the ambient temperature sensor is higher than the set value; and a display device, configured to display a failure of the cooling fan of the units when the controller implements the periodic operation of the compressor.

Thus, a refrigerator in accordance with any of the above aspects, upon an emergency stop of the unit cooling fan, displays a malfunction and stops the compressor or operates at a low compressor speed, or operates in periodic compressor operation if the ambient temperature is higher than the set value. Accordingly, stopping the unit cooling fan never causes an excessive temperature increase in the unit compartment due to heating of the compressor. This prevents an excessive increase in the temperature of the refrigerant and the temperature of the outer case of the refrigerator due to the passage of the refrigerant through the pipe laid on the outer case of the refrigerator.

Brief Description of the Drawings

Figure 1 is a sectional view of a refrigerator for which embodiments of the present invention are implemented;

Figure 2 - refrigeration cooling cycle;

Figure 3 is a perspective view of the inside of the aggregate compartment of the refrigerator;

4 is a block diagram of a refrigerator controller in accordance with 1 embodiment of the present invention;

FIG. 5 is a flowchart according to 1 embodiment implemented with the controller shown in FIG. 4;

FIG. 6 is a flowchart according to an embodiment 2 implemented with the controller shown in FIG. 4;

FIG. 7 is a flowchart according to Embodiment 3 implemented with the controller shown in FIG. 4;

Fig. 8 is a flowchart according to an embodiment 4 carried out with the controller shown in Fig. 4;

FIG. 9 is a flowchart according to an embodiment 5 carried out with the controller shown in FIG. 4;

FIG. 10 is a block diagram of a controller in accordance with an embodiment of the present invention applied to the refrigerator shown in FIG. 1; and

FIG. 11 is a flowchart of an embodiment 6 with the controller shown in FIG. 10.

Detailed Description of Embodiments

Embodiments of the present invention will be explained in detail with reference to the drawings.

1 embodiment

1 shows a refrigerator 1, on which 1 embodiment and other embodiments of the present invention are implemented. The refrigerator 1 has a thermally insulated housing 2, divided into a refrigerator 4 and a freezer 6.

Behind the refrigerator 4 there is an evaporator 7 of the refrigerator and a fan 8 of the refrigerator. Behind the freezer 6 there is an evaporator 14 of the freezer and a fan 13 of the freezer. Aggregate compartment 10 is formed in the lower rear part of the freezer chamber 6. In the aggregate compartment 10 are a compressor 11, a radiating pipe 25, a three-way valve 15, etc.

Figure 2 shows the cooling cycle of the refrigerator 1. The compressor 11 for pumping refrigerant is connected to a condenser 12, which is connected to a three-way valve 15. The three-way valve 15 is connected through a pipe to the capillary tube 16 of the freezer and the evaporator 14 of the freezer, connected in series. The three-way valve 15 through the pipeline is also connected to the capillary tube 17 of the refrigerator and the evaporator 7 of the refrigerator, connected in series. These two pipelines are connected in parallel with each other and together are connected to the suction side of the compressor 11. Between the outlet of the evaporator 14 of the freezer and the suction side of the compressor 11, a check valve 18 is connected.

A three-way valve 15 switches four modes containing a fully open mode for passing refrigerant to both the evaporator 7 of the refrigerator and the evaporator 14 of the freezer, the refrigerator mode for passing refrigerant only to the evaporator 7 of the refrigerator, the freezer mode for passing refrigerant only to the evaporator 14 of the freezer, and closed mode, in which the refrigerant does not pass either to the evaporator 7 of the refrigerator, or to the evaporator 14 of the freezer.

If the temperatures of the refrigerating chamber 4 and the freezing chamber 6 are higher than the set temperatures, for example, when the refrigerator 1 is turned on, then the three-way valve 15 is set to fully open mode, so that the refrigerant leaving the compressor 11 passes through the condenser 12 to the three-way valve 15 and is divided through capillary tubes 16 and 17, evaporates by the evaporator 7 of the refrigerator and the evaporator 14 of the freezer, passes through the battery and the suction tube and returns to the compressor 11. The evaporator 7 of the refrigerator and the evaporator 14 of the freezer o they provide cold air, which is blown by the refrigerator fan 8 and the freezer fan 13 into the refrigerator 4 and the freezer 6, respectively, to cool or freeze the foodstuffs stored therein.

If the freezer 6 is cooled to the set temperature, and the refrigerator 4 is not yet cooled to the set temperature, the three-way valve 15 switches to the refrigerator mode so that the refrigerant passes only to the evaporator 7 of the refrigerator, so that the evaporator 7 of the refrigerator and fan 8 of the refrigerator blow cold air into refrigerator compartment 4.

If only the temperature in the freezer 6 is higher than the set temperature, the three-way valve 15 switches to the freezer mode so that the refrigerant leaving the compressor 11 passes through the condenser 12 to the capillary tube 16 of the freezer, evaporates by the evaporator 14 of the freezer and returns through the battery to the compressor 11. B As a result, the freezer evaporator 14 provides cold air, which is sent by the freezer fan 13 to the freezer 6, thereby cooling the freezer 6.

When the refrigerating chamber 4 and the freezing chamber 6 are cooled to the set temperatures, the temperature sensors located in appropriate places in the refrigerator 1 detect this and the three-way valve 15 alternately switches to the refrigerator mode and the freezer or compressor 11 and the fans 8 and 13 are stopped. These actions are controlled by the controller 21.

Figure 3 is a perspective view showing the inside of the aggregate compartment 10. In the aggregate compartment 10 are a compressor 11, a connecting pipe installed at the bottom of the aggregate compartment 10 and connected to a condenser 12, a three-way valve 15, capillary tubes 16 and 17, a radiating pipeline 25 and other parts used in the cooling cycle, and piping. The aggregate compartment 10 also includes an aggregate cooling fan 20, which draws in external air into the aggregate compartment 10 for cooling heat-generating parts, such as a compressor 11 and a radiating pipe 25. The aggregate cooling fan 20 is controlled by a controller 21.

To ensure a wide area of radiation, the radiating pipe 25 extends from the condenser 12, is laid along the upper and lower surfaces of the outer casing of the refrigerator 1, returns to the aggregate compartment 10 and is connected to a three-way valve 15.

If the refrigerator 1 is in an atmosphere with a high temperature or is exposed to an atmosphere with a high temperature in the summer, the mode of insufficient heat radiation will cause a malfunction of the cooling fan 20 of the units. In this case, the compressor 11 should operate without cooling. If this situation continues to exist, the temperature in the aggregate compartment 10 becomes excessively high, which will excessively increase the temperature of the outer casing of the refrigerator 1.

Fig. 4 is a flowchart showing the control functions of the controller 21 of the refrigerator 1 in accordance with 1 embodiment, and Fig. 5 is a flowchart of the control operations in accordance with 1 embodiment carried out by the controller 21 shown figure 4. According to the control flow shown in FIG. 5, when the unit cooling fan 20 stops abnormally, the controller 21 controls the compressor 11 to prevent the temperature of the outer case of the refrigerator 1 from rising excessively due to an emergency stop of the fan 20.

The ambient temperature sensor 22 is located in a suitable place on the refrigerator 1, such as the back side, the upper side or the side of the unit compartment 10, in order to measure the ambient temperature and transmit the measured temperature to the controller 21. The display device 23 is placed together with the temperature adjustment panel in appropriate place on the door of the refrigerator compartment 4. The display device 23 displays the information provided by the controller 21. The controller 21 receives the operation signal from the power supply switch 24 of the refrigerator 1 and turns on or off the compressor 11 and the unit cooling fan 20. At the same time, the controller 21 monitors the fan 20 and detects an emergency stop.

The control operation of the compressor 11 performed by the controller 21 when the unit cooling fan 20 is stopped abnormally will be explained with reference to the flowchart shown in FIG.

When the power supply is turned on, the controller 21 in step S1 starts the compressor 11 and in step S2, the unit cooling fan 20. In step S3, the controller 21 does a check to determine if the fan 20 is working. If the fan 20 is operating normally (NO in step S3), the controller 21 continues to operate normally.

If the unit cooling fan 20 has stopped abnormally, the controller 21 attempts to restart the fan 20 a predetermined number N times (N is, for example, 3), passing through steps S3-S5. The restart operation is preferably repeated at predetermined intervals of the order of five minutes, twenty minutes and one hour. If the fan 20 restarts N times during the restart operation, the controller 21 determines that the fan 20 is in good condition and returns to normal operation (NO in step S5 and NO in step S3).

If the unit cooling fan 20 does not restart after N times the restart operation (YES in step S5), the controller 21 in step S6 checks to make sure that the ambient temperature measured by the ambient temperature sensor 22 is higher than the set value Tref1 (= 31 ° C ) or Tref2 (= 33 ° C) in step S6. This setpoint can be selected as desired.

If at step S6 the ambient temperature is higher than the set value Tref2, the controller 21 at step S7 stops the compressor 11, because if the compressor 11 is continuously running, the temperature in the unit compartment 10 increases, which should unnecessarily increase the temperature of the outer case of the refrigerator 1. After that in step S8, the controller 21 shows the failure of the unit cooling fan 20 on the display device 23. If the ambient temperature is lower than the set value Tref1 in step S6, the controller 21 in step S9 continuously uses the compressor 11 to cool the food in the refrigerator 1. At this time, the fan 20 is still faulty and therefore the controller 21 in step S10 displays a failure of the fan 20 on the device 23 displays. If the ambient temperature drops below the set value Tref1 after stopping the compressor 11, the controller 21 starts compressor 11 again to resume the cooling cycle.

Observing on the display device 23 information about the failure of the fan 20 for cooling the units, the user turns off and then on again the power source. The controller 21 in steps S11 and S12 determines that this normal on / off operation is performed by the user and starts the refrigerator 1 again.

If the failure of the unit cooling fan 20 continues to exist after the user turns the refrigerator 1 on and off several times, the user must call the service engineer. The maintenance engineer in step S11 checks the refrigerator 1, using the power supply switch 24 in a special way. With this special operation, the controller 21 determines in step S12 that maintenance / repair work is required, and in step S13 starts operation in the maintenance / repair mode.

According to 1 embodiment, if the fan 20 crashes, the controller 21 attempts to restart the unit cooling fan 20 N times and determines whether the fan 20 is actually malfunctioning. If the fan 20 restarts during the restart operation N times, the controller 21 resumes normal operation. Thus, Embodiment 1 is able to determine with certainty whether the fan 20 is really defective.

If the unit cooling fan 20 does not restart after performing N restarts, the controller 21 determines that the fan 20 is faulty. In this case, the controller 21 checks the ambient temperature to see if it is higher than the set value, and determines whether the continuous operation of the compressor 11 with the fan 20 stopped really increases the temperature of the outer case of the refrigerator 1. If the ambient temperature is higher than the set value, the controller 21 stops the compressor 11 to protect the outer case of the refrigerator 1 from excessive heat.

According to 1 embodiment, the failure of the unit cooling fan 20 is determined by the result of N restarts. This is not a limitation of the present invention. For example, the failure of the fan 20 can be detected when an emergency stop is detected. This should simplify the management process.

According to 1 embodiment, the compressor 11 is stopped if the ambient temperature measured by the ambient temperature sensor 22 is above a predetermined value. This is not a limitation of the present invention. For example, the present invention may adopt a simpler control procedure for stopping the compressor 11 upon detecting an emergency stop of the unit cooling fan 20.

2 embodiment

The refrigerator 1 according to Embodiment 2 of the present invention will be explained with reference to FIGS. 4 and 6. The refrigerator 1 corresponding to Embodiment 2 is structurally the same as in Embodiment 1 shown in FIGS. 1-3. Accordingly, a subsequent explanation will be made using the same reference numbers for matching parts.

2, the implementation differs by the compressor control procedure 11 performed by the controller 21 during an emergency stop of the unit cooling fan 20. During an emergency stop of the fan 20, the controller 21 continuously uses the compressor 11 by reducing its rotation speed, thus continuing the cooling cycle of the refrigerator 1 as much as the conditions allow. If the fan 20 continues to be inactive after N restarts, the controller 21 determines that the fan 20 is faulty and stops the compressor 11 depending on the ambient temperature in order to suspend the cooling cycle.

The functional configuration of the controller 21 is the same as in the 1 embodiment shown in FIG. 4. The control sequence provided by the controller 21 according to the software installed therein is shown in FIG. 6. If the compressor 11 has a control type with an inverter, then the continuous operation of the compressor 11 is carried out by reducing the operating frequency to a minimum value. If you use the type of compressor 11 operating at a constant speed, then instead of minimizing its operating frequency, the compressor 11 periodically turns on and off at predetermined intervals.

When the power supply is turned on, the controller 21 starts the compressor 11 in step S1, starts the unit cooling fan 20 in step S2, and controls the operation of the fan 20 in step S3. If the fan 20 does not cause a malfunction (NO in step S3), the controller 21 continues to operate normally.

If the unit cooling fan 20 crashes, the controller 21 reduces the rotation speed of the compressor 11 to a predetermined value and continuously uses the compressor 11 in step S4A. The controller 21 in steps S3-S5 tries to restart the fan 20 a predetermined number N times at predetermined intervals like 1 embodiment . If the fan 20 is restarted during the restart operation N times, the controller 21 determines that the fan 20 is operational and returns to normal operation (NO in step S5 and NO in step S3).

If the unit cooling fan 20 does not restart after the restart operation N times (YES in step S5), the controller 21 in step S6 determines whether the ambient temperature measured by the ambient temperature sensor 22 is higher than the set value Tref1 (= 31 ° C) or Tref2 (= 33 ° C). Temperature conditions are the same as in 1 embodiment.

The steps that follow step S6 are the same as in 1 embodiment.

Thus, Embodiment 2 operates and provides an effect similar to Embodiment 1. In addition, embodiment 2 transfers the compressor 11 to a lower rotation speed if the unit cooling fan 20 crashes, thereby continuing the cooling cycle. At the same time, Embodiment 2 attempts to restart the fan 20 N times. Accordingly, Embodiment 2 can inhibit the temperature increase in the refrigerator 1 during periods of attempts to restart the fan 20, thereby preventing food spoilage in the refrigerator 1.

According to Embodiment 2, the compressor 11 is stopped in step S7 if, in step S6, the ambient temperature measured by the ambient temperature sensor 22 is above a predetermined value. This is not a limitation of the present invention. For example, according to the present invention, the compressor 11 can stop regardless of the ambient temperature if the unit cooling fan 20 still continues to be inactive after a restart operation N times performed when an emergency stop of the fan 20 is detected.

3 embodiment

The refrigerator 1 corresponding to the 3rd embodiment of the present invention will be explained with reference to FIGS. 4 and 7. The refrigerator 1 corresponding to the 3rd embodiment is structurally the same as the refrigerator corresponding to the 1st embodiment shown in FIGS. 1-3. Accordingly, a subsequent explanation will be made using the same reference numerals for matching parts.

3, the implementation differs by the compressor control procedure 11 performed by the controller 21 when the unit cooling fan 20 crashes. When the fan 20 stops abnormally, the controller 21 tries to restart the fan 20 N times. If the fan 20 still continues to be idle after performing the restart operation N times, the controller 21 determines that the fan 20 is faulty and stops the compressor 11 depending on the ambient temperature, after which if the ambient temperature is lower than the set value, the controller 21 restarts the compressor 11 Thus, if conditions permit, in the 3rd embodiment, the cooling cycle is periodically activated.

The functional configuration of the controller 21 is the same as in the 1 embodiment shown in FIG. 4. The sequence of operations performed by the controller 21 in accordance with the software installed in it, such as shown in Fig.7.

When the power supply is turned on, the controller 21 in step S1 starts the compressor 11, in step S2 starts the unit cooling fan 20 and in step S3 controls the operation of the fan 20. Steps S1-S10 3 of the embodiment are the same as in 1 embodiment shown in figure 5.

If an emergency stop of the unit cooling fan 20 is detected, the controller 21 stops or continues the operation of the compressor 11 depending on the ambient temperature and displays the failure of the fan 20 on the display device 23. After that, the controller 21 continuously monitors the surrounding temperature. If the ambient temperature measured by the ambient temperature sensor 22 in step S21 after stopping the compressor 11 is equal to or lower than the set value Tref1, then the controller 21 in step S22 determines whether the set time has passed after the stop of the compressor 11. If the ambient temperature is equal to or lower than the set Tref1 and if, after stopping the compressor 112, the set time has passed, the controller 21 in step S3 restarts the compressor 11. At this time, the fan 20 is still idle, then, therefore, the controller 21 in step S24 continuously the fan 20 fails on the display device 23.

The processes that follow step S24 are the same as those that follow step S11 in the 1 embodiment shown in FIG. 5. Watching the information about the failure of the unit cooling fan 20 on the display device 23, the user in this case turns off the power supply and then turns it on again. If this is a standard on / off operation, the controller 21 determines that the on / off operation has been performed by the user, and restarts the refrigerator 1 in steps S11 and S12.

If the failure of the unit cooling fan 20 continues after the user has turned the refrigerator 1 on and off several times, the user must call the service engineer. The maintenance engineer in step S11 checks the refrigerator 1, in a special way using the power switch 24. With this special operation, the controller 21 determines in step S12 that maintenance / repair work is required, and in step S13 starts the maintenance / repair mode S13.

Thus, Embodiment 3 works and provides an effect similar to Embodiment 1. The compressor 11 in the 3 embodiment stops if the unit cooling fan 20 crashes and if the ambient temperature is high. After that, if the ambient temperature decreases to the set value Tref1 and if the set time elapses after the compressor 11 has stopped, in the 3rd embodiment, the compressor 11 is restarted to restart cooling of the inside of the refrigerator 1. This prevents the temperature of the outer case of the refrigerator 1 from rising too much. for stopping the compressor 11 and due to the high ambient temperature, and also prevents food spoilage in the refrigerator.

According to a third embodiment, the failure of the unit cooling fan 20 is determined by the result of the restart operation N times. This is not a limitation of the present invention. For example, the failure of the fan 20 can be detected when an emergency stop is detected. This should simplify the management process.

4 embodiment

A refrigerator 1 corresponding to an embodiment 4 of the present invention will be explained with reference to FIGS. 4 and 8. A refrigerator 1 corresponding to an embodiment 4 is structurally the same as a refrigerator corresponding to an embodiment 1 shown in FIGS. 1-3. Accordingly, a subsequent explanation will be made using the same reference numerals for matching parts.

4, the implementation differs by the compressor control procedure 11 performed by the controller 21 when the unit cooling fan 20 crashes. When the fan 20 stops abnormally, the controller 21 uses the compressor 11 at a low speed to continue the cooling cycle as long as the conditions allow. If the fan 20 still continues to be idle after performing the restart operation N times, the controller 21 determines that the fan 20 is faulty and, depending on the ambient temperature, stops the compressor 11 to suspend the cooling cycle. Like option 3, the controller 21 continuously monitors the ambient temperature and, if it falls below a predetermined value and if a predetermined time has passed after stopping the compressor 11, restarts the compressor 11 to re-enable cooling inside the refrigerator 1.

The functional configuration of the controller 21 is the same as in the 1 embodiment shown in FIG. 4. The control sequence carried out by the controller 21 in accordance with the software installed therein is shown in FIG. The continuous operation of the compressor 11 by reducing the speed of rotation is carried out, reducing the operating frequency of the compressor 11 to a minimum value if the compressor 11 has a control type with an inverter. If the compressor 11 operates at a constant speed, then the compressor 11 operates periodically at predetermined intervals instead of reducing its operating frequency.

When the power supply is turned on, the controller 21 in step S1 starts the compressor 11, in step S2 starts the unit cooling fan 20 and in step S3 controls the operation of the fan 20. Steps S3-S10 and S11-S13 are the same as in the 2 embodiment shown in Fig.6. Steps S21-S24 following step S8 are the same as steps 3 of the embodiment shown in FIG. 7.

Thus, Embodiment 4 works and provides an effect similar to Embodiment 1. Like Embodiment 2, Embodiment 4 operates such that when fan 20 crashes, compressor 11 operates at a low speed to continue the cooling cycle as long as conditions permit. If the fan 20 still continues to be idle after performing the restart operation N times, in the 4th embodiment, it is determined that the controller 20 is faulty and, depending on the ambient temperature, the compressor 11 is stopped to stop the cooling cycle. This prevents an excessive temperature increase inside the refrigerator 1 during the restart operation, and also prevents food spoilage in the refrigerator 1.

Like the 3 embodiment, in the 4 embodiment, the compressor 11 stops if the unit cooling fan 20 crashes and if the ambient temperature is high. In an embodiment 4, the ambient temperature is continuously monitored, and if it falls below a predetermined value and if a predetermined time has passed after the compressor 11 has stopped, the compressor 11 is restarted to restart cooling of the inside of the refrigerator 1. Like the 3 embodiment in 4 embodiment, it is prevented excessive increase in temperature of the outer case of the refrigerator 1 due to the stop of the compressor 11 and due to the high ambient temperature, and food spoilage is also prevented s products in the refrigerator.

5 embodiment

The refrigerator 1 corresponding to the 5th embodiment of the present invention will be explained with reference to Figs. 4 and 9. The refrigerator 1 corresponding to the 5th embodiment is structurally the same as the refrigerator corresponding to the 1st embodiment shown in Figs. 1-3. Accordingly, a subsequent explanation will be made using the same reference numerals for matching parts.

5, an embodiment is distinguished by a compressor 11 control procedure performed by the controller 21 when the unit cooling fan 20 crashes. When the fan 20 stops abnormally, the controller 21 tries to restart the fan 20 N times. If the fan 20 still continues to be idle after performing the restart operation N times, the controller 21 determines that the fan 20 is malfunctioning and, depending on the ambient temperature, changes the rotation speed of the compressor 11 The 5 embodiment differs from the 2 embodiment shown in Fig. 6 in that the controller 21 corresponding to the 5 embodiment for controlling compressor 11 uses two views of these values Tref1 (= 31 ° C) / Tref2 (= 33 ° C) and Tref3 (= 35 ° C) / Tref4 (= 37 ° C).

The functional configuration of the controller 21 is the same as in the 1 embodiment shown in FIG. 4. The control sequence carried out by the controller 21 in accordance with the software installed therein is shown in FIG. 9.

The continuous operation of the compressor 11 by reducing its rotation speed is carried out by reducing the operating frequency of the compressor 11 to a minimum value if the compressor 11 has a control type with an inverter. If the compressor 11 operates at a constant speed, then the compressor 11 operates periodically at predetermined intervals instead of minimizing its operating frequency.

When the power supply is turned on, the controller 21 starts the compressor 11 in step S1, starts the unit cooling fan 20 in step S2, and controls the operation of the fan 20 in step S3. If the fan 20 does not cause a malfunction (NO in step S3), the controller 21 continues to operate normally.

If the unit cooling fan 20 shuts down abnormally, the controller 21, in steps S3-S5, like 1 embodiment, tries to restart the fan 20 a predetermined number N times at predetermined intervals. If the fan 20 restarts while repeating the restart operation N times, the controller 21 determines that the fan 20 is operational and returns to normal operation (NO in step S5 and NO in step S3).

If the unit cooling fan 20 still continues to be idle after performing the restart operation N times (YES in step S5), the controller 21 in step S6 checks whether the ambient temperature measured by the ambient temperature sensor 22 is higher than the first setpoint Tref1 ( = 31 ° C) / Tref2 (= 33 ° C). The temperature conditions are the same as in 1 embodiment. If the ambient temperature is lower than the first setpoint Tref1 / Tref2, when the fan 20 abnormally stops to stop cooling of the unit compartment 10, the compressor 11 can be used continuously without excessively increasing the temperature of the outer case of the refrigerator 1. Accordingly, if NO is selected in step S6, the controller 21 in step S9 continuously uses the compressor 11 and displays the emergency stop of the fan 20 on the display device 23 in order to inform the user of a failure in step S10.

If at step S6 the ambient temperature is higher than the first setpoint Tref1 (= 31 ° C) / Tref2 (= 33 ° C), the controller 21 proceeds to steps S7A-S7C because if the compressor 11 is used continuously, the temperature of the unit compartment 10 is excessive increases. If the ambient temperature is lower than the second setpoint Tref3 / Tref4 with the emergency cooling fan 20 in step S7A, the temperature of the aggregate compartment 10 and the outer case of the refrigerator 1 will not increase excessively and therefore, in step S7B, the controller 21 continuously uses compressor 11 at normal rotation speed R1. Namely, instead of operating the compressor 11 with a high rotation speed R2 (> R1) to compensate for the increase in temperature by stopping the fan 20, the controller 21 maintains the normal rotation speed of the compressor 11 in order to prevent food spoilage in the refrigerator 1.

If at step S7A the ambient temperature is higher than the second setpoint Tref3 / Tref4 when the unit cooling fan 20 is abnormally stopped, the temperatures of the unit compartment 10 and the outer case of the refrigerator 1 are excessively increased. In this case, the controller 21 in step S7C continuously uses the compressor 11, reducing its rotation speed to R3 (<R1). In any case, in step S8, an emergency stop of the fan 20 is displayed on the display device 23.

From step S11, the processes are the same as in 1 embodiment. If the failure of the unit cooling fan 20 continues after the user turns the refrigerator 1 on and off several times, the user must call the service engineer. The maintenance engineer in step S11 checks the refrigerator 1, in a special way using the power supply switch 24. With this special operation, the controller 21 determines in step S12 that maintenance / repair work is required, and in step S13 starts operation in the maintenance / repair mode.

Thus, Embodiment 5 utilizes and provides an effect similar to Embodiment 1. In addition, Embodiment 5 uses two kinds of values of predetermined ambient temperature values. If the ambient temperature exceeds 35 ° C, the 5 embodiment continuously uses the compressor 11 at a low rotation speed to prevent the temperature of the refrigerator 1 from rising. If the ambient temperature is higher than this, the 5 embodiment further reduces the rotation speed of the compressor 11 to continue the cooling cycle at minimum possibility to prevent excessive temperature rise of the outer case of the refrigerator 1 and food spoilage in the refrigerator 1.

6 embodiment

The refrigerator 1 corresponding to the 6th embodiment of the present invention will be explained with reference to FIGS. 10 and 11. The refrigerator 1 corresponding to the 6th embodiment is structurally the same as in the 1st embodiment shown in FIGS. 1-3, with the exception of the control circuit shown in FIG. 10. The following explanation will be made using the same reference numerals for the matching parts as used in Embodiment 1.

6, the embodiment is characterized in that a temperature sensor 26 (FIG. 10) of the aggregate compartment is installed in the aggregate compartment 10 to measure the temperature in the aggregate compartment 10. If the aggregate cooling fan 20 stops abnormally, the controller 21 controls the compressor 11 in accordance with the ambient temperature, measured by the ambient temperature sensor 22, and the temperature of the aggregate compartment is measured by the temperature sensor 26. If the fan 20 stops abnormally, the controller 21 tries to restart fan 20 N times. If the fan 20 still continues to be idle after performing the restart operation N times, the controller 21 determines that the fan 20 is faulty and, depending on the ambient temperature and the temperature of the unit chamber, lowers the rotation speed of the compressor 11 or stops it. It is preferable to install the temperature sensor 26 near the fuel part, such as a compressor 1 and a radiating pipe 25 in the aggregate compartment 10.

The functional configuration of the controller 21 in accordance with the software installed therein is as shown in FIG. 10, and the control flow carried out by the controller 21 is shown in FIG. 11. When the power supply is turned on, the controller 21 starts the compressor 11 in step S1, starts the unit cooling fan 20 in step S2, and controls the operation of the fan 20 in step S3. If the fan 20 does not cause a malfunction (NO in step S3), the controller 21 continues to operate normally.

If the unit cooling fan 20 crashes, the controller 21 attempts to restart the fan 20 a predetermined number N times at predetermined intervals in steps S3-S5 like 1 embodiment. If the fan 20 restarts during a repeated N-time restart operation, the controller 21 determines that the fan 20 is operational and returns to normal operation (NO in step S5 and NO in step S3).

If the unit cooling fan 20 does not restart after repeating the restart operation N times (YES in step S5), the controller 21 in step S36 checks whether the ambient temperature measured by the ambient temperature sensor 22 is higher than the set value Tref1 (= 31 ° C) / Tref2 (= 33 ° C). The temperature conditions are the same as in 1 embodiment. If the ambient temperature is lower than the set value Tref1 / Tref2, when the fan 20 has stopped abnormally in order to stop cooling the unit chamber 10, the compressor 11 can be continuously used without excessively raising the temperature of the unit compartment 10 and the temperature of the outer case of the refrigerator 1. Accordingly, if it is selected for step S6 NO, the controller 21 in step S9 continuously uses the compressor 11 and displays the emergency stop of the fan 20 on the display device 23 to inform the user of the failure in step S10.

If in step S6 the ambient temperature is higher than the set value Tref1 / Tref2, the controller 21 in step S31 checks the temperature in the aggregate compartment, measured by the temperature sensor 26. If the temperature in the aggregate compartment is higher than the set value, the controller 21 in step S32 stops the compressor 11 in order to prevent the temperature of the aggregate compartment 10 and the outer case of the refrigerator 1 from becoming too high. After that, in step S8, the controller 21 displays an emergency stop of the unit cooling fan 20 on the display device 23 , thus informing the user of the failure.

From step S11, the processes are the same as in 1 embodiment. If the failure of the unit cooling fan 20 continues after the user turns the refrigerator 1 on and off several times in step S11, the user must call the service engineer. The maintenance engineer in step S11 checks the refrigerator 1, in a special way using the power supply switch 24. With this special operation, the controller 21 determines in step S12 that maintenance / repair work is required, and in step S13 starts operation in the maintenance / repair mode.

Thus, the 6th embodiment works and provides an effect similar to the 1st embodiment. In addition, in the 6th embodiment, a temperature sensor 26 is installed to measure the temperature in the unit compartment 10. If the unit cooling fan 20 crashes, the 6 embodiment controls the compressor 11 in accordance with the ambient temperature measured by the temperature sensor 26. If both measured temperatures are high, the compressor 11 in the 6th embodiment is stopped. Namely, the compressor 11 in the 6th embodiment is stopped only when the temperature of the outer case of the refrigerator 1 is expected to rise excessively, thereby preventing such an excessive temperature rise.

Instead of stopping the compressor 11 in the 6th embodiment, the compressor 11 can continuously operate, reducing its rotation speed. Continuous operation of the compressor by lowering its rotation speed is carried out by lowering the operating frequency of the compressor 11 to a minimum value if the compressor 11 has an inverter type control. If the compressor 11 has a type with a constant speed, then instead of lowering the frequency of its operation, the compressor 11 operates periodically at predetermined intervals.

Claims (17)

1. A refrigerator having an aggregate compartment, a compressor housed in the aggregate compartment, and a unit cooling fan for air cooling units housed in the aggregate compartment, the refrigerator comprising:
an ambient temperature sensor configured to measure an ambient temperature around the refrigerator;
a failure monitor configured to detect an emergency stop of the unit cooling fan;
a controller configured to stop the compressor if the failure monitor detects an emergency stop of the unit cooling fan and if the ambient temperature measured by the ambient temperature sensor is higher than the set value; and a display device configured to display a failure of the unit cooling fan when the controller stops the compressor. 2. The refrigerator according to claim 1, additionally containing a temperature sensor in the aggregate compartment, configured to measure the temperature in the aggregate compartment, the controller being configured to stop the compressor if the failure monitor detects an emergency stop of the cooling unit and if the ambient temperature measured the environmental sensor is higher than the set value, and if the temperature in the aggregate compartment, measured by the temperature sensor in the aggregate compartment, is higher than the set value. 3. The refrigerator according to claim 1, in which the controller is configured to access the ambient temperature measured by the ambient temperature sensor when a predetermined time elapses after the controller stops the compressor, and with the ability to restart the controller if the ambient temperature is lower set value. 4. The refrigerator according to claim 1, wherein the failure monitor is configured to attempt to restart the unit cooling fan a predetermined number of times after the unit cooling fan has stopped, and if the unit cooling fan still continues to be inactive after a predetermined number of restart attempts, determining an emergency stop of the compressor and messages to the controller about an emergency stop. 5. The refrigerator according to claim 1, in which the controller is configured to perform periodic operation of the compressor at intervals shorter than normal intervals if the failure monitor detects an emergency stop of the cooling unit and stops the compressor if the failure monitor subsequently detects an emergency stop of the fan cooling units a predetermined number of times. 6. A refrigerator having an aggregate compartment, a compressor housed in the aggregate compartment, and a unit cooling fan for air cooling units housed in the aggregate compartment, the refrigerator comprising:
an ambient temperature sensor configured to measure an ambient temperature around the refrigerator;
a failure monitor configured to detect an emergency stop of the unit cooling fan;
a controller configured to perform slow-down operation of the compressor at a speed below the normal operating speed, if the failure monitor detects an emergency stop of the unit cooling fan and if the ambient temperature measured by the ambient temperature sensor is above a predetermined value; and a display device configured to display a failure of the cooling fan of the units when the controller performs slow-motion operation of the compressor. 7. The refrigerator according to claim 6, in which the controller is configured to change the deceleration of the compressor speed relative to the normal operating speed in accordance with the ambient temperature measured by the ambient temperature sensor. 8. The refrigerator according to claim 6, further comprising an aggregate compartment temperature sensor configured to measure temperature in the aggregate compartment, wherein the controller is configured to perform slow-down operation of the compressor at a speed below normal operating speed if the failure monitor detects an emergency stop of the unit cooling fan and if the ambient temperature measured by the ambient temperature sensor is higher than the set value, and if the temperature in the aggregate compartment is measured the temperature sensor of the aggregate compartment is higher than the set value. 9. The refrigerator according to claim 6, in which the controller is configured to access the ambient temperature measured by the ambient temperature sensor when a predetermined time elapses after the controller performs slower operation of the compressor, and with the ability to restore the compressor at normal speed, if the ambient temperature is lower than the set value. 10. The refrigerator according to claim 6, in which the failure monitor is configured to attempt to restart the unit cooling fan a predetermined number of times after the unit cooling fan stops, and if the unit cooling fan still continues to be inactive after a predetermined number of restart attempts, determining an emergency stop of the compressor and messages to the controller about an emergency stop. 11. The refrigerator according to claim 6, in which the controller is configured to perform periodic operation of the compressor at intervals shorter than normal intervals if the failure monitor detects an emergency stop of the cooling unit and stops the compressor if the failure monitor subsequently detects an emergency stop of the fan cooling units set number of times. 12. A refrigerator having an aggregate compartment, a compressor housed in the aggregate compartment, and a unit cooling fan for air cooling units housed in the aggregate compartment, the refrigerator comprising:
an ambient temperature sensor configured to measure an ambient temperature around the refrigerator;
a failure monitor configured to detect an emergency stop of the unit cooling fan;
a controller configured to periodically run the compressor at intervals shorter than normal intervals if the failure monitor detects an emergency stop of the unit cooling fan and if the ambient temperature measured by the ambient temperature sensor is higher than the set value; and a display device configured to display a failure of the cooling fan of the units when the controller performs periodic operation of the compressor. 13. The refrigerator according to item 12, in which the controller is configured to change intervals during periodic operation of the compressor in accordance with the ambient temperature measured by the ambient temperature sensor. 14. The refrigerator according to item 12, further comprising:
temperature sensor of the aggregate compartment, configured to measure temperature in the aggregate compartment,
the controller is configured to perform periodic operation of the compressor if the temperature of the aggregate compartment, measured by the temperature sensor of the aggregate compartment is higher than a predetermined value. 15. The refrigerator according to item 12, in which the controller is configured to access the ambient temperature measured by the ambient temperature sensor when a predetermined time elapses after the controller performs periodic operation of the compressor, and with the possibility of restoring normal operation of the compressor, if temperature is below set point. 16. The refrigerator according to clause 16, in which the failure monitor is configured to attempt to restart the unit cooling fan a predetermined number of times after the unit cooling fan has stopped, and if the unit cooling fan still continues to be inactive after a predetermined number of restart attempts, determining an emergency stop of the compressor and messages to the controller about an emergency stop. 17. The refrigerator according to item 12, in which the controller is configured to perform periodic operation of the compressor at intervals shorter than normal intervals if the failure monitor detects an emergency stop of the cooling unit and stops the compressor if the failure monitor subsequently detects an emergency stop of the fan cooling units a predetermined number of times.

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