JP4545645B2 - Cooling storage - Google Patents

Description

  The present invention relates to a cooling storage, and more particularly to improvement of operation control when the cooling operation is restarted after the defrosting operation is completed.

For example, a commercial refrigerator has a function of performing a defrosting operation between cooling operations. Structurally, a cooler and a cooling fan are provided in the storage chamber, and the cooler is circulated and connected by a refrigerant (for example, an inverter compressor), a refrigeration apparatus including a condenser, and a refrigerant pipe. In addition, a defrost heater is mounted.
Then, as shown in FIG. 11, in the cooling operation, the compressor, the condenser fan, and the cooling fan are driven, and cold air is generated by heat exchange while air in the storage chamber is drawn and passes through the cooler. This is again discharged toward the storage chamber. During this time, the internal temperature is detected, and the rotation speed of the compressor is controlled based on the detected temperature, so that the internal cooling temperature is maintained substantially constant.

  On the other hand, the defrosting operation is performed by energizing the defrosting heater in a state where the compressor, the condenser fan, and the cooling fan are stopped. During this time, when the temperature of the cooler is detected and reaches a predetermined temperature, it is considered that the defrosting is completed, the defrosting heater is turned off, the defrosting operation is finished, and then a predetermined draining time has passed. After that, only the compressor and the condenser fan are started (precooling operation), and the cooling fan is started after a predetermined time delay, so that the cooling operation is resumed. The reason for delaying the start of the cooling fan is that after the defrosting operation is finished, the cooler is still in a high temperature state, and when the cooling fan is driven, the warm air turns into the chamber and the chamber temperature rises. is there.

Here, during the defrosting operation, since the cooler is heated by the heater as described above, the low pressure in the refrigeration circuit increases. If the low pressure is high, a large starting torque is required when starting the compressor. In particular, when the ambient temperature of the refrigerator is high, the load is further increased, and the compressor may not be started due to insufficient torque.
Conventionally, as a countermeasure, for example, as disclosed in Patent Document 1, after the defrosting operation is completed, the cooling fan is activated before the compressor is activated. When the cooling fan is driven, the cooler is cooled and the low-pressure pressure is reduced, so that the compressor is more easily started.
JP-A-10-62058

However, driving the cooling fan shortly after the end of the defrosting operation also leads to an increase in the internal temperature as described above, and thus, before the compressor is started as in the prior art. If the cooling fan is always activated, it is not necessary to worry about the compressor's torque shortage, that is, if it is not necessary to cool the cooler with the cooling fan, the internal temperature will be increased unnecessarily. There was a problem of just inviting.
The present invention has been completed on the basis of the above circumstances, and its purpose is to suppress an unnecessary increase in the internal temperature of the compressor before restarting the cooling operation after the defrosting operation. It is in place to guarantee the start-up.

  As a means for achieving the above object, the invention of claim 1 is characterized in that in the storage chamber, a cooler connected to a refrigeration apparatus including a compressor, and circulating air to the storage chamber while passing through the cooler. A cooling fan for generating a flow is provided, and heating means capable of heating the cooler is provided. In the defrosting operation, the heating means is driven in a state where the compressor and the cooling fan are stopped. When the cooling operation is resumed after completion of the defrosting operation, the cooling operation is performed in a cooling storage in which the cooling fan is activated after a predetermined time delay after the compressor is activated. When restarting, only when it is detected that a predetermined operating condition is detected, a control means for operating the cooling fan in advance before starting the compressor is provided. You .

According to a second aspect of the present invention, in the first aspect of the present invention, the predetermined operating condition is characterized in that an ambient temperature of the cooling storage is equal to or higher than a predetermined temperature.
A third aspect of the invention is characterized in that, in the first aspect of the invention, the predetermined operating condition is that the compressor has failed to start when the cooling operation is resumed.
According to a fourth aspect of the present invention, in any one of the first to third aspects, the control means has a function of stopping the preceding operation of the cooling fan immediately after the compressor is started. It has a characteristic where it exists.

According to a fifth aspect of the present invention, the storage chamber is provided with a cooler connected to a refrigeration apparatus including a compressor, and a cooling fan that generates a circulating air flow in the storage chamber while passing through the cooler. A heating means capable of heating the cooler is provided, and the defrosting operation is performed by driving the heating means in a state where the compressor and the cooling fan are stopped, and the defrosting operation is completed. When the cooling operation is resumed later, in the cooling storage where the cooling fan is operated after the compressor is started and delayed, the cooling operation is restarted before the compressor is started. There is provided a control means for operating the fan in advance for a predetermined time, stopping the cooling fan for a time longer than the preceding operation time after starting the compressor, and thereafter operating the cooling fan in earnest. Characterized in was with.
The invention of claim 6 is characterized in that, in the apparatus of claim 5, the preceding operation time of the cooling fan is between 15 seconds and 60 seconds, and the stop time of the cooling fan is about 5 minutes.

<Invention of Claim 1>
When resuming the cooling operation, if it is detected that a predetermined operating condition that makes it difficult to start the compressor is detected, the cooling fan is operated in advance before the compressor is started. As a result, the temperature of the cooler is rapidly lowered, the low pressure of the refrigeration circuit is lowered, the necessary starting torque is lowered, and the subsequent starting of the compressor is ensured. Here, the preceding operation of the cooling fan sends the warm air after heat exchange into the storage room even for a short time, which causes an unexpected increase in the internal temperature. It is performed only in the case of the above, and is not performed when it is not necessary, so that it is possible to prevent the internal temperature from being unnecessarily increased.

<Invention of Claim 2>
When the ambient temperature at the installation position of the cooling storage is high, it is considered that the load is increased and it is difficult to start the compressor. Only when the ambient temperature is equal to or higher than the predetermined temperature, the cooling fan precedent operation is executed. That is, this is executed only when the cooling fan needs to be operated in advance.
<Invention of Claim 3>
The preceding operation of the cooling fan is executed based on the fact that the compressor has failed to start when the cooling operation is resumed. This is also performed only if a preceding operation of the cooling fan is necessary.
<Invention of Claim 4>
When the cooling fan is operated in advance, it is stopped immediately after the compressor is started, so that the rise in the internal temperature is kept to a minimum.

<Invention of Claim 5>
When restarting the cooling operation, the cooling fan is operated in advance immediately before starting the compressor, so the low pressure of the refrigeration circuit can be reduced, and the starting torque required when starting the compressor is reduced. Therefore, the startability of the compressor can be improved. Moreover, since the peak of the high pressure after starting is suppressed, the load applied to the compressor is reduced, and the high pressure protection device is prevented from operating unnecessarily. By suppressing the preceding operation time to the minimum necessary, the rise in the internal temperature can be minimized.
On the other hand, since the preceding operation of the cooling fan is stopped after the start of the compressor, the increase in the load of the compressor immediately after the start can be suppressed, which can contribute to the suppression of the increase in the high pressure and the stop of the cooling fan. Thus, the voltage drop can be suppressed, and the startability of the compressor can be improved. By taking a corresponding stop time longer than the preceding operation time, it is avoided that the high pressure is further increased due to turning the cooling fan in a state where the high pressure is high, and the high pressure protection device is disabled. It is prevented from working when necessary.

<Invention of Claim 6>
If the preceding operation time of the cooling fan is long, such as 3 to 5 minutes, it can be said that the low pressure can be lowered accordingly, but conversely the rise in the internal temperature becomes significant and it takes time to lower to the set temperature, This leads to wasted power consumption. On the other hand, if the preceding operation time of the cooling fan before starting the compressor is “15 to 60 seconds”, the increase in the internal temperature is minimized and the low pressure is reduced and the high pressure is reduced. It is effective to lower the peak.
On the other hand, if the time for stopping the cooling fan after the start of the compressor is short, for example, about 1 minute, the high pressure is still high at the end of the stop time. When the cooling fan is operated at that time, the warm internal air is applied to the cooler and the cooler is also warmed, so that the low pressure increases. That is, if the low pressure is increased by turning the cooling fan while the high pressure is high, the high pressure is further increased, and as a result, the high pressure protection device may be activated.
In this respect, since the present invention waits for about 5 minutes to wait for the high pressure to settle after starting the compressor, the high pressure further increases when the cooling fan enters full operation. Can be prevented.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.
<Embodiment 1>
A first embodiment of the present invention will be described with reference to FIGS. As shown in FIG. 1, the refrigerator according to the present embodiment has a refrigerator main body 10 composed of a vertically long heat insulating box with a front opening, and is supported by four legs 11 provided on the bottom surface. It is a storage room 12. A heat insulating door 13 is attached to the opening of the front surface of the storage chamber 12 so as to be swingable. A refrigeration unit 15 is installed on the upper surface of the main body 10 so as to close the window hole 14 opened in the ceiling wall. In the refrigeration unit 15, a refrigeration device 17 including an inverter compressor 18, a condenser 19 with a fan 19A and the like is mounted on the upper surface of a heat-insulating base 16, and a cooler 20 is suspended on the lower surface side. The refrigeration apparatus 17 and the cooler 20 are connected by circulation through a refrigerant pipe to form a known refrigeration circuit.

A drain pan 22 also serving as an air duct is stretched on the lower surface side of the window hole 14 in the ceiling portion of the storage chamber 12, and a cooler chamber 23 is formed above the drain pan 22. The cooler chamber 23 accommodates the cooler 20 described above, and a suction port 24 is provided on the front side (left side in FIG. 1) of the drain pan 22 and a cooling fan 25 is provided. Is provided with an air outlet 26.
For the defrosting operation, a defrosting heater 27 is attached to the cooler 20, and a drainage channel 28 connected to the outlet 22 </ b> A of the drain pan 22 is formed in the wall surface of the main body 10.

  The operation of the refrigerator is controlled on the basis of a predetermined program. Therefore, as shown in FIG. 2, a control means 30 having a microcomputer, a timer 31 and the like and storing the program is provided. ing. On the input side of the control means 30, an internal temperature sensor 33 that detects the internal temperature, a defrost switch 34 that is automatically operated by a 24-hour timer or manually operated, and further the temperature of the cooler 20 are set. A defrosting temperature sensor 35 that functions to detect and consider that defrosting is completed is connected. On the other hand, the compressor 18, the condenser fan 19A, the cooling fan 25, and the defrost heater 27 in the refrigeration apparatus 17 are connected to the output side.

  The basic operation will be described. In the cooling operation, the cooling fan 25 is driven while the compressor 18 and the condenser fan 19 </ b> A in the refrigeration apparatus 17 are operated, and the indoor air in the storage chamber 12 is sucked into the suction port 24 by the cooling fan 25. Is sucked into the cooler chamber 23, and cold air is generated by heat exchange while the air flows through the cooler 20, and the cold air is blown out from the outlet 26 along the inner surface of the storage chamber 12. Thus, cold air is circulated and supplied into the storage chamber 12. Meanwhile, the internal temperature is detected by the internal temperature sensor 33, and the rotation speed of the compressor 18 is controlled based on the difference between the detected temperature and the set temperature, so that the interior of the storage chamber 12 is maintained at substantially the set temperature. Is done.

  During the cooling operation, the defrosting operation is performed to remove frost attached to the cooler 20 and the like. This defrosting operation is performed by energizing and heating the defrost heater 27 in a state where the compressor 18, the condenser fan 19 </ b> A, and the cooling fan 25 are stopped, and the defrost water is received by the drain pan 22. After that, the water is drained out of the warehouse through the drainage channel 28 provided in the wall surface of the main body 10. If it is determined that the defrosting has been completed by the temperature detected by the defrosting temperature sensor 35, the defrosting heater 27 is turned off, the defrosting operation is terminated, and the cooling operation is resumed.

  In this embodiment, when restarting the cooling operation after the defrosting operation, the operation program is improved in order to reliably start the compressor 18. Specifically, the function is provided only when the low-pressure side of the refrigeration circuit is cooled before the compressor 18 is started, and the ambient temperature of the refrigerator is equal to or higher than a predetermined value. . Therefore, the condenser temperature sensor 37 is selected as the ambient temperature detection means and is connected to the input side of the control means 30. The condenser temperature sensor 37 is attached to the condenser 19 and is originally used to detect the temperature of the refrigerant when the refrigeration apparatus 17 is operated and to monitor whether there is an abnormality. It can be used to detect the temperature around the condenser 19, that is, the ambient temperature of the refrigerator.

Next, the operation of this embodiment will be described with reference to the timing chart of FIG. 3 and the flowchart of FIG.
As described above, the defrosting operation is performed by energizing the defrosting heater 27 while the compressor 18, the condenser fan 19A, and the cooling fan 25 are stopped. During this time, when the temperature of the cooler 20 is detected and reaches a predetermined temperature, it is considered that the defrosting has been completed, the defrosting heater 27 is turned off, and the defrosting operation is completed. Thereafter, after a predetermined draining time (several tens of seconds), a pre-cooling operation in which only the compressor 18 and the condenser fan 19A are started is performed, and the cooling fan 25 is further delayed by a predetermined time (several tens of seconds). By being activated, the cooling operation is resumed.

  In the present embodiment, as shown in FIG. 4, at the time when the defrosting operation is completed (step S <b> 10), the ambient temperature detected by the condenser temperature sensor 37 is compared with a predetermined set temperature in step S <b> 11. The As described above, during the defrosting operation, the cooler 20 is heated and the low pressure of the refrigeration circuit is increased, so that a large starting torque is required when the compressor 18 is started, and the ambient temperature of the refrigerator is particularly high. If the ambient temperature is equal to or higher than the set temperature, there is a concern that the torque will be insufficient, and if the ambient temperature is lower than the set temperature, it is determined that there is no concern about torque shortage. is doing.

  If the ambient temperature is equal to or higher than the set temperature ("Yes" in step S11), the cooling fan 25 is set in step S12 before a predetermined time (for example, 10 seconds) before the compressor 18 (condenser fan 19A) is activated. Is driven (preceding operation). Then, since the cooler 20 is heat-exchanged with the cooler interior air at a lower temperature than the cooler 20, the temperature is rapidly lowered, and accordingly, the low-pressure pressure of the refrigeration circuit is lowered, and the necessary starting torque is lowered. As a result, subsequently, in step S13, the compressor 18 (condenser fan 19A) is started and a precooling operation is performed.

When the pre-cooling operation is started, the cooling fan 25 is temporarily stopped immediately (several seconds later) (step S14). This is because, in the preceding operation of the cooling fan 25, the cooler 20 is not cooled, but the warm air generated by heat exchange is supplied to the storage chamber 12 side and the internal temperature rises. This is because after the startup is successful, the cooling fan 25 is immediately stopped to suppress the temperature rise of the storage chamber 12 as much as possible.
When a predetermined delay time has elapsed since the start of the precooling operation, the cooling fan 25 is driven again (full operation) in step S15, and the cooling operation is resumed. Since the cooler 20 is sufficiently cooled during the pre-cooling operation, there is no possibility that the temperature in the storage chamber 12 will be increased with the operation of the cooling fan 25.

  On the other hand, when the ambient temperature is lower than the set temperature at the end of the defrosting operation (step S11 is “No”), as shown by a chain line in the timing chart of the cooling fan 25 in FIG. Without operation, after the draining time has elapsed, the compressor 18 (condenser fan 19A) is started to perform precooling operation (step S16), and after the delay time has elapsed, the cooling fan 25 is driven in step S17. (Full-scale operation), cooling operation is resumed.

  As described above, in the first embodiment, when the ambient temperature at the refrigerator installation position is high, it is determined that starting of the compressor 18 is difficult due to the increased load, and the compressor 18 (condenser fan 19A) is determined. ) Is started, the cooling fan 25 is operated in advance. Thereby, the temperature of the cooler 20 is rapidly lowered, the low pressure of the refrigeration circuit is lowered, the necessary starting torque is lowered, and the subsequent starting of the compressor 18 is ensured. Although the preceding operation of the cooling fan 25 sends the warm air after heat exchange into the storage chamber 12 even in a short time, the internal temperature of the cooling fan 25 is unexpectedly increased. This process is performed only when the ambient temperature is high and exactly necessary, and is not performed when the ambient temperature is low and is not necessary. Therefore, it is possible to prevent the internal temperature from being unnecessarily increased. Also when the preceding operation of the cooling fan 25 is performed, the compressor 18 is stopped as soon as it is started, so that the rise in the internal temperature is kept to a minimum.

Further, when the cooling fan 25 is operated in advance, the defrost water droplets adhering to the cooler 20 and the cooling fan 25 are blown off and discarded on the drain pan 22, so that the defrost water is regenerated during the subsequent cooling operation. Freezing is prevented.
Since the existing condenser temperature sensor 37 is used to detect the ambient temperature of the refrigerator, it can be provided at low cost.

<Embodiment 2>
Next, a second embodiment of the present invention will be described with reference to FIGS. In the first embodiment, the preceding operation of the cooling fan 25 is executed only when the ambient temperature at the refrigerator installation position is high. In the second embodiment, the compressor 18 is activated to perform the precooling operation. Only when a start-up failure occurs at the timing, the start-up operation of the cooling fan 25 is executed before the compressor 18 is started again.

Therefore, a detection means 38 for detecting whether or not the compressor 18 is normally started is provided at the timing T1 of the initial precooling operation after the defrosting operation is completed. As shown by the chain line in FIG. Instead of the temperature sensor 37, it is connected to the input side of the control means 30.
This detection means 38 detects, for example, the energization state of the compressor 18, and considers that a start-up failure has occurred when a current (overcurrent) of a certain level or more flows. When an overcurrent flows, the energization of the compressor 18 is temporarily stopped, so that the energization stop state is detected, and the compressor 18 is regarded as having failed to start following a start failure. Also good. If it is detected that the compressor 18 has failed to start or has failed to start, the driving of the cooling fan 25 after the delay time is canceled, and instead the compressor 18 (condenser fan 19A) is started again, that is, the pre-cooling operation. The timing T2 at which is started is set.

The operation of the second embodiment will be described with reference to the timing chart of FIG. 5 and the flowchart of FIG.
After the defrosting operation is completed (step S20), as shown in step S21, at the timing T1 when the precooling operation is started, it is identified whether or not the compressor 18 has been successfully started, and if it cannot be started normally. (Step S21 is “No”). In Step S22, the start timing T2 of the second precooling operation is set after a predetermined waiting time from the start timing T1 of the first precooling operation.

Thereafter, in step S23, the cooling fan 25 is driven (preceding operation) before a predetermined time (for example, 10 seconds) before the start timing T2 of the second precooling operation set as described above. Accordingly, as described above, the low-pressure pressure is lowered as the temperature of the cooler 20 is lowered, and the necessary starting torque of the compressor 18 is lowered. As a result, subsequently, in step S24, the compressor 18 (condenser fan 19A) is started and a pre-cooling operation is performed. When the pre-cooling operation is started, the cooling fan 25 is temporarily stopped immediately (several seconds later) (step S25). Similarly, it is for suppressing the temperature rise of the storage chamber 12 as much as possible. When a predetermined delay time has elapsed since the start of the precooling operation, the cooling fan 25 is driven again in step S26 (full operation), and the cooling operation is resumed.
On the other hand, if the compressor 18 is successfully started at the start timing T1 of the first precooling operation ("Yes" in step S21), the cooling fan 25 is subsequently driven in step S27 after a predetermined delay time has elapsed (full operation). ), The cooling operation is resumed.

In the second embodiment, when it is detected that the compressor 18 has failed to start up and has failed to start, the start timing T2 of the second precooling operation is set, and the cooling fan is started before the compressor 18 is started. 25 is operated in advance. Similarly, the start-up of the compressor 18 is secured for the second time by lowering the low-pressure pressure of the refrigeration circuit and reducing the necessary start-up torque. This is performed only when the preceding operation of the cooling fan 25 is necessary, due to the fact that the starting failure has occurred in the compressor 18 and thus the starting failure, and is not performed when it is not necessary. Unnecessarily increasing the temperature in the cabinet is prevented. Similarly, when the preceding operation of the cooling fan 25 is performed, the compressor 18 is stopped as soon as it is activated, so that the rise in the internal temperature is kept to a minimum.
Similarly, when the cooling fan 25 is preliminarily operated, the defrost water droplets adhering to the cooler 20 and the cooling fan 25 are blown off and discarded on the drain pan 22, so that the defrost water is regenerated during the subsequent cooling operation. Freezing is prevented.

<Embodiment 3>
A third embodiment of the present invention will be described with reference to FIGS.
In the third embodiment, another improvement is added to the operation program in order to improve the startability of the compressor 18. Briefly, when restarting the cooling operation, the cooling fan 25 is operated for a predetermined time before the compressor 18 is started, and after the compressor 18 is started, the cooling fan 25 is stopped for a time longer than the preceding operation time, Thereafter, the cooling fan 25 is operated in earnest.

The operation of the third embodiment will be described with reference to the timing chart of FIG.
Similarly, the defrosting operation is performed by energizing the defrosting heater 27 while the compressor 18, the condenser fan 19A, and the cooling fan 25 are stopped. Thereafter, when it is considered that the defrosting is completed, for example, when the cooler 20 reaches a predetermined temperature, the defrosting heater 27 is turned off and the defrosting operation is completed.
When the defrosting operation is completed, after a predetermined draining time (several tens of seconds), a pre-cooling operation in which the compressor 18 and the condenser fan 19A are activated is performed, but the compressor 18 (the condenser fan 19A) is activated. Before a predetermined time (for example, 15 seconds), the cooling fan 25 is driven (preceding operation).
At the timing when the compressor 18 (condenser fan 19A) is activated (start of precooling operation), the cooling fan 25 that has been previously operated stops. This stop time is taken, for example, for 5 minutes. After the stop time has elapsed, the cooling fan 25 is driven again (full-scale operation), and the cooling operation is resumed.

In Embodiment 3, when the cooling operation is resumed, the cooling fan 25 is operated for 15 seconds immediately before the compressor 18 is started. Due to the heat exchange, the temperature is rapidly lowered, and the low pressure of the refrigeration circuit is also lowered accordingly. If it does so, since the start torque required at the time of starting of the compressor 18 may be small, startability improves.
Moreover, since the peak of the high pressure after starting will be suppressed if the low pressure just before starting of the compressor 18 is low, the load concerning the compressor 18 is reduced. In particular, when the room temperature is high, there is a concern that the high pressure protection device such as a high pressure switch may be activated due to an increase in pressure on the high pressure side, and the refrigeration apparatus may become inoperable. By being suppressed, an unnecessary operation of the high-pressure protection device is prevented, and the device can be operated even at a high temperature.

  Here, when the peak of the high pressure after starting the compressor 18 was measured, the result shown in the graph of FIG. 8 was obtained. As in this embodiment, when the cooling fan 25 is operated for 15 seconds before starting the compressor 18 (characteristic line X), the high pressure peak Pd (15 seconds) does not operate the cooling fan 25 (characteristic line O). ) About 150 kPa, compared to the high pressure peak Pd (0 second). When the cooling fan 25 is operated for 30 seconds before the compressor 18 is started (characteristic line Y), the high pressure peak Pd (30 seconds) is reduced by about 220 kPa, and is cooled for 60 seconds before the compressor 18 is started. When the fan 25 is operated (characteristic line Z), the high pressure peak Pd (60 seconds) is reduced by about 320 kPa.

As described above, when the cooling fan 25 is preliminarily operated immediately before the compressor 18 is started, it can be said that the peak of the high pressure can be lowered as the operation time becomes longer. It takes time to lower the temperature to the set temperature, leading to wasted power consumption. Therefore, in the refrigerator, the internal temperature when the cooling fan 25 was operated for 15 seconds before starting the compressor 18 was measured, and the result indicated by the characteristic line x in the graph of FIG. 9 was obtained. That is, the peak T (15 seconds) of the internal temperature was suppressed to less than 0 ° C., and it was confirmed that it could be applied to a refrigerator. In the graph, a characteristic line o indicates a case where the cooling fan 25 is not operated in advance.
Further, the internal temperature when the cooling fan 25 was operated for 30 seconds or 60 seconds before starting the compressor 18 was measured in the refrigerator, and the characteristic lines y and z in the graph of FIG. 10 were obtained. . Each of the peak T (30 seconds) and T (60 seconds) of the internal temperature was kept at around 13 ° C., and it was confirmed that the refrigerator was sufficiently applicable to a refrigerator.
Therefore, as shown in the graph of FIG. 8 above, if the preceding operation time of the cooling fan 25 before starting the compressor 18 is “15 to 60 seconds”, the rise in the internal temperature is minimized. However, it is effective in reducing the peak of high pressure.

On the other hand, after the compressor 18 is started, the operation of the cooling fan 25 is stopped, and after taking a stop time of “5 minutes” longer than the preceding operation time, the cooling fan 25 is fully operated.
The reason why the cooling fan 25 is stopped immediately after the compressor 18 is started is as follows. If the cooling fan 25 continues to be operated even after the compressor 18 is started, the internal air whose temperature has risen unexpectedly during the defrosting operation is directed to the cooler 20 to exchange heat, so the load increases rapidly. The burden on the compressor 18 is also increased, resulting in an increase in the high pressure. That is, stopping the cooling fan 25 after starting the compressor 18 can also contribute to suppressing an increase in the high pressure. Further, if the cooling fan 25 is stopped when the compressor 18 is started, the voltage drop can be suppressed by the capacity, and the startability of the compressor 18 is also improved.

The reason why the cooling fan 25 is stopped for about 5 minutes is as follows. For several minutes (for example, 2 to 3 minutes) after the compressor 18 is started, as shown in the graph of FIG. 8, the high pressure is still high. On the other hand, when the cooling fan 25 is operated immediately after the compressor 18 is started, the low-pressure pressure rises because the warm internal air is applied to the cooler 20 and warms the cooler 20 as described above. That is, if the cooling fan 25 is rotated and the low pressure is increased while the high pressure is high, the high pressure is further increased, which may cause the high pressure protection device to operate.
Therefore, in the present embodiment, the main purpose is to operate the cooling fan 25 after waiting for the high pressure to decrease to some extent after the compressor 18 is started. As a result, the stop time until the cooling fan 25 enters full-scale operation is “ “5 minutes”.

  As described above, according to the present embodiment, when restarting the cooling operation, the cooling fan 25 is operated in advance immediately before the compressor 18 is started, so that the low pressure of the refrigeration circuit can be reduced, The starting torque required at the time of starting the compressor 18 can be suppressed, and the startability of the compressor 18 can be improved. Further, since the peak of the high pressure after starting is suppressed, the load applied to the compressor 18 is reduced, and the high pressure protection device is prevented from operating unnecessarily. Moreover, since the preceding operation time is limited to “15 seconds”, the rise in the internal temperature can be minimized.

  On the other hand, since the operation of the cooling fan 25 is stopped after the start of the compressor 18, an increase in the load of the compressor 18 immediately after the start can be suppressed, which can contribute to the suppression of the increase in the high pressure and the cooling fan. The voltage drop can be suppressed by stopping 25, and the startability of the compressor 18 can be improved. Moreover, since the stop time is secured “about 5 minutes”, it is avoided that the high pressure is further increased due to the cooling fan 25 being rotated while the high pressure is high, and the high pressure protection device operates unnecessarily. It is prevented.

<Other embodiments>
The present invention is not limited to the embodiments described with reference to the above description and drawings. For example, the following embodiments are also included in the technical scope of the present invention, and further, within the scope not departing from the gist of the invention other than the following. Various modifications can be made.
(1) In Embodiment 1, you may prepare a temperature sensor separately in order to detect the ambient temperature of a refrigerator.
(2) When the ambient temperature of the refrigerator increases, the low pressure and the high pressure of the refrigeration circuit tend to increase. Therefore, the ambient temperature may be detected by detecting the low pressure or the high pressure.

(3) In the second embodiment, as a means for detecting the start failure of the compressor and the start failure, the state of power supply to the compressor is monitored on the microcomputer provided in the control means, It may be considered that a start-up failure has occurred when a certain current (overcurrent) flows, or that the start-up of the compressor has failed by detecting the energization stop state.
In addition, when an external detection means or a detection means on the microcomputer detects that the compressor has failed to start or has failed to start, an error signal is output, and this error signal is used to start the second precooling operation. It is good also as a trigger which sets a timing and performs preceding operation of a cooling fan.
(4) In the first and second embodiments, the various times related to the operation control are merely examples, and can be appropriately changed according to the specifications of the refrigerator. Also in the third embodiment, the time for basic operation control is merely an example.
(5) In the above embodiment, an inverter compressor having a variable rotation speed is exemplified as the compressor. However, a compressor having a constant rotation speed and a type in which the on-off operation is repeated to control the internal temperature. It may be used.

The longitudinal cross-sectional view of the refrigerator which concerns on Embodiment 1 of this invention Block diagram of operation control mechanism Driving timing chart Flow chart Operation timing chart according to Embodiment 2 Flow chart Operation timing chart according to Embodiment 3 Graph showing pressure change A graph showing changes in the internal temperature of the freezer The graph which shows the change of the inside temperature in the refrigerator Conventional operation timing chart

Explanation of symbols

  DESCRIPTION OF SYMBOLS 10 ... Refrigerator main body 12 ... Storage room 17 ... Refrigeration apparatus 18 ... Compressor 19A ... Condenser fan 20 ... Cooler 23 ... Cooler room 25 ... Cooling fan 27 ... Defrost heater (heating means) 30 ... Control means 37 ... Condensation Temperature sensor 38... Compressor start state detecting means

Claims (6)

The storage chamber is provided with a cooler connected to a refrigeration apparatus including a compressor, and a cooling fan that generates a circulating air flow in the storage chamber while passing through the cooler, and the cooler can be heated. When the heating means is driven in a state where the compressor and the cooling fan are stopped, and the cooling operation is resumed after the defrosting operation is completed. In the cooling storage where the cooling fan is activated after a predetermined time delay after the compressor is activated,
Control means for operating the cooling fan in advance before starting the compressor is provided only when it is detected that a predetermined operating condition is detected when restarting the cooling operation. To cool storage. The cooling storage according to claim 1, wherein the predetermined operating condition is that an ambient temperature of the cooling storage is equal to or higher than a predetermined temperature. The cooling storage according to claim 1, wherein the predetermined operating condition is that the compressor has failed to start when the cooling operation is resumed. The cooling storage according to any one of claims 1 to 3, wherein the control means has a function of stopping the preceding operation of the cooling fan immediately after the compressor is started. The storage chamber is provided with a cooler connected to a refrigeration apparatus including a compressor, and a cooling fan that generates a circulating air flow in the storage chamber while passing through the cooler, and the cooler can be heated. When the heating means is driven in a state where the compressor and the cooling fan are stopped, and the cooling operation is resumed after the defrosting operation is completed. In the cooling storage where the cooling fan is operated after a delay after starting the compressor,
When resuming the cooling operation, the cooling fan is operated in advance for a predetermined time before the compressor is started, and the cooling fan is stopped for a time longer than the preceding operation time after the compressor is started. A cooling storage comprising a control means for operating the cooling fan in earnest. The cooling storage according to claim 5, wherein the preceding operation time of the cooling fan is 15 to 60 seconds, and the stop time of the cooling fan is about 5 minutes.

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