JP7507338B2 - refrigerator - Google Patents

Description

This disclosure relates to refrigerators.

Patent Document 1 discloses a refrigerator that improves efficiency by storing cold in a cold storage unit at night when the door is opened less and the outside temperature is low, and discharging the cold storage unit in the evening when the door is opened more frequently and the load is greater, thereby cooling the freezer compartment. This refrigerator is provided with a cold storage unit and a cold storage fan in the freezer compartment, and has a function for switching between storing and discharging cold by operating the cold storage fan.

JP 2012-07760 A

This disclosure provides a refrigerator that uses a cold storage material and can release heat at any time, resulting in a highly energy-efficient refrigerator.

The refrigerator in the present disclosure includes a cooler that is part of a cooling cycle, a cold storage material that is in thermal contact with an inlet pipe of the cooler, a cooling chamber that houses the cooler and the cold storage material and is separated from the interior of the refrigerator, a heat insulating member that insulates the cooler and the cold storage material within the cooling chamber, a cooling fan that circulates the cold air generated by the cooler and/or the cold storage material into the refrigerator, an air path switching means that selectively directs air from the cooling fan to the cooler and the cold storage material, and a control unit that controls the cooling cycle, the cooling fan, and the air path switching means.

The refrigerator disclosed herein can suppress the release of cold caused by an increase in the surrounding temperature by controlling the air path switching means with a control unit and selectively directing air from a cooling fan to the cooler and the cold storage material. Therefore, the release of cold can be performed at any time, making it a highly energy-efficient refrigerator.

1 is a cross-sectional view of a refrigerator in a cold storage mode according to a first embodiment of the present invention; FIG. 3 is a cross-sectional view of the refrigerator in a cooling mode according to the first embodiment. Flowchart of cold storage in the refrigerator in the first embodiment Flowchart for cooling the refrigerator in the first embodiment Timing chart showing temperatures of various parts of a refrigerator in the first embodiment Cross-sectional view of a refrigerator according to a second embodiment. Flowchart for cooling a refrigerator in the second embodiment Timing chart showing temperatures of various parts of a refrigerator in accordance with a second embodiment

(Knowledge and other information that forms the basis of this disclosure)
In the refrigerator industry, proposals have been made not only to use the cold generated by the cooling cycle directly to cool the inside of the refrigerator, but also to store the cold in a cold storage material and use it to cool the inside of the refrigerator when the cooling cycle is not operating.

For example, a refrigerator stores latent heat storage material filled in a resin container inside the cabinet, and during normal cooling, the storage material stores cold heat (storages cold), and when the temperature inside the cabinet rises due to a power outage or other reason, the stored cold heat suppresses the temperature rise inside the cabinet (discharges cold).

However, with this technology, the ice pack would always release heat whenever the temperature inside the refrigerator rose, making it difficult to control the timing of this release.

To solve this problem, Patent Document 1 also proposes a technology to control the storage and release of cold using a cold storage fan. However, the cold storage unit installed inside the freezer is exposed to the freezer, and even when the cold storage fan is not operating, a sudden rise in the temperature of the surrounding air or the air flow inside the freezer can cause cold storage and release at unintended times. This means that the cold storage unit is not able to store cold in the evening when it is actually necessary to release the cold, and there is a risk that the operation will not be highly efficient.

The inventors believed that constant contact of the cold storage material with the air inside the refrigerator would make it difficult to control the timing of cold storage and release, and came up with the subject of this disclosure to solve this problem.

To solve the problems of the conventional technology, the present disclosure provides a refrigerator that can be cooled at any time.

Below, the embodiments will be described in detail with reference to the drawings. However, more detailed explanation than necessary may be omitted. For example, detailed explanation of already well-known matters or duplicate explanation of substantially the same configuration may be omitted.

The accompanying drawings and the following description are provided to enable those skilled in the art to fully understand the present disclosure, and are not intended to limit the subject matter described in the claims.

(Embodiment 1)
Hereinafter, the first embodiment will be described with reference to FIGS. 1 to 5. FIG.

[1-1. Configuration]
1 and 2, a refrigerator 1 in this embodiment is composed of an insulated box 3 divided into upper and lower parts by a partition 2, and the area above the partition 2 is a refrigerator compartment 4 in which the interior temperature is maintained at a refrigeration temperature range of about 4° C. (upper limit value Tr2, lower limit value Tr1), and the area below the partition 2 is a freezer compartment 5 in which the interior temperature is maintained at a freezing temperature range of about −18° C. (upper limit value Tf2, lower limit value Tf1). The front is closed by insulated doors 6 and 7 which can be opened and closed freely.

The rear of the freezer compartment 5 is provided with a cooling compartment 9 separated from the interior of the freezer compartment 5 by a freezer duct 8. Inside the cooling compartment 9, a cooler 11 is provided on the front side, which is connected to a compressor 10, a radiator (not shown), and a capillary (not shown) as an expansion means to form a cooling cycle (not shown), and a cold storage and release means 12 is provided on the rear side as a cold storage material filled in a case with a latent heat storage material (freezing point Tc<Tf1) such as a highly water-absorbent resin, and an insulating partition 13 is provided between them as an insulating member that thermally insulates the two.

The cold storage and release means 12 is in thermal contact with an inlet pipe 14 that connects the capillary (not shown) to the cooler 11.

Above the cooler 11 and cold storage/discharge means 12 in the cooling chamber 9, there is a cooling fan 15 that circulates the cold air generated by the cooler 11 to the refrigerator chamber 4 and the freezer chamber 5.

The freezer duct 8 has a number of freezer outlets 16 that blow the cold air discharged by the cooling fan 15 into the freezer chamber 5, and a freezer intake 17 that draws the air that has cooled the freezer chamber 5 from the freezer chamber 5 into the cooling chamber 9.

The partition 2 is equipped with a refrigerator discharge air duct 18 that blows the cold air discharged by the cooling fan 15 into the refrigerator compartment 4, and a refrigerator intake air duct (not shown) that draws the cold air that has cooled the refrigerator compartment 4 from the refrigerator compartment 4 into the cooling compartment 9, as well as a refrigerator damper 19 that opens and closes to allow or block the flow of cold air from the refrigerator discharge air duct 18 to the refrigerator duct 21 (described below).

The refrigerator compartment 4 is provided with a refrigerator duct 21 having multiple refrigerator outlets 20 that blow the cold air blown out from the refrigerator outlet air duct 18 into the refrigerator compartment 4. Between the heat-insulating partition 13 and the cooling fan 15, a cold storage damper 22 is provided as an air duct switching means that selectively flows the air sucked into the cooling compartment 9 from the freezer suction port 17 to either the cooler 11 or the cold storage and release means 12.

In addition, each storage compartment (refrigeration compartment 4, freezer compartment 5) is equipped with a refrigeration sensor 23 and a freezer sensor 24 that detect the internal temperature, and a control unit 25 that controls each device based on the temperatures detected by these sensors is provided on the top surface of the refrigerator 1.

[1-2. Operation]
An example of the operation and function of the refrigerator 1 according to the first embodiment configured as above will be described below.

The operation of the refrigerator 1 to store and release cold at any time will be described with reference to Figs. 1 to 5. The refrigerator 1 of the present disclosure switches between cold storage operation and cold release operation by the control unit 25.

First, the cold storage operation will be described with reference to Figures 1 and 3. When the cold storage operation is started, in step S1, the control unit 25 compares with the freezing sensor 24 whether the temperature in the freezing chamber 5 is higher than the upper limit value Tf2, and if it is lower, the process of step S1 is repeated, and if it is higher, the process proceeds to step S2.

In step S2, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is higher than the lower limit Tr1. If it is lower, the process proceeds to step S5, where freezing operation and cold storage operation are started, and if it is higher, the process proceeds to step S3, where refrigeration operation and cold storage operation are started. In refrigeration operation and cold storage operation, the compressor 10 and cooling fan 15 are operated, and the refrigeration damper 19 is opened. At the same time, the cold storage damper 22 is opened on the cooler 11 side, and the process proceeds to step S4.

During refrigeration and cold storage operation, the high-temperature, high-pressure gas refrigerant compressed by the compressor 10 flows to a radiator (not shown) where it is cooled, releasing heat and liquefying. It is then depressurized by a capillary (not shown) to become a low-temperature, low-pressure gas-liquid two-phase flow, which flows from the inlet pipe 14 to the cooler 11. It then evaporates by exchanging heat with the outside air in the cooler 11, and generates cold air using the latent heat of evaporation.

The generated cold air is then blown by the cooling fan 15 through the freezer duct 8 and out of the freezer outlet 16 into the freezer chamber 5, cooling the interior of the freezer chamber 5, before being sucked into the cooling chamber 9 through the freezer inlet 17.

At the same time, the cold air that has flowed through the refrigerator exhaust air duct 18 flows from the refrigerator damper 19 to the refrigerator duct 21, is blown out from the refrigerator exhaust port 20 into the refrigerator compartment 4, cools the refrigerator compartment 4, and is sucked into the cooling compartment 9 through the refrigerator intake air duct (not shown).

At this time, the inlet pipe 14 is also cooled, so the cold storage and release means 12 is cooled and stores cold, but the cold storage and release means 12 is surrounded and insulated by the insulated box body 3, the cold storage damper 22, and the insulated partition 13, and no air flows through it, so it does not release cold.

In step S4, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is lower than the lower limit Tr1. If it is higher, the process of step S4 is repeated. If it is lower, the control unit 25 proceeds to step S5 and starts freezing and cold storage operations. In freezing and cold storage operations, the compressor 10 and cooling fan 15 are operated, and the refrigeration damper 19 is closed. At the same time, the cold storage damper 22 is opened on the cooler 11 side, and the control unit 25 proceeds to step S6.

During freezing and cold storage operation, the cold air generated by the cooler 11 flows through the freezing duct 8 by the cooling fan 15 and is blown into the freezing chamber 5 from the freezing outlet 16, cooling the inside of the freezing chamber 5, and is sucked into the cooling chamber 9 through the freezing inlet 17.

At this time, the inlet pipe 14 is also cooled, so the cold storage and release means 12 is cooled and stores cold, but the cold storage and release means 12 is surrounded and insulated by the insulated box body 3, the cold storage damper 22, and the insulated partition 13, and no air flows through it, so it does not release cold.

In step S6, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is lower than the upper limit Tr2, and if it is higher, the control unit 25 proceeds to step S3 and starts the refrigeration operation and cold storage operation, and if it is lower, the control unit 25 proceeds to step S7.

In step S7, the control unit 25 uses the freezing sensor 24 to compare whether the temperature in the freezing chamber 5 is lower than the lower limit Tf1. If it is higher, the process of steps S6 and S7 is repeated. If it is lower, the control unit 25 proceeds to step S8, stops the compressor 10 and the cooling fan 15, closes the refrigeration damper 19, and opens the cold storage damper 22 on the cooler 11 side, thereby terminating the cold storage operation.

Next, the cold discharge operation will be described with reference to Figures 2 and 4. When the cold discharge operation is started, first in step S9, the control unit 25 uses the freezing sensor 24 to compare whether the temperature in the freezing chamber 5 is higher than the upper limit Tf2, and if it is lower, the process of step S9 is repeated, and if it is higher, the process proceeds to step S10. In step S10, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigeration chamber 4 is higher than the lower limit Tr1, and if it is lower, the process proceeds to step S13 and starts the freezing operation and cold discharge operation, and if it is higher, the process proceeds to step S11 and starts the refrigeration operation and cold discharge operation.

In the refrigeration operation and cold release operation, the compressor 10 is stopped, the cooling fan 15 is operated, and the refrigeration damper 19 is opened. At the same time, the cold storage damper 22 is opened on the cold storage/cold release means 12 side, and the process proceeds to step S12.

Here, the cold storage and release means 12 stores cold and is solidified at a temperature Tc that is lower than the temperature of the freezer compartment 5, and exchanges heat with the air through the cooling fan 15 to generate cold air.

The generated cold air is then blown by the cooling fan 15 through the freezer duct 8 and out of the freezer outlet 16 into the freezer chamber 5, cooling the inside of the freezer chamber 5, before being sucked into the cooling chamber 9 through the freezer inlet 17.

At the same time, the cold air that has flowed through the refrigerator exhaust air duct 18 flows from the refrigerator damper 19 to the refrigerator duct 21, is blown out from the refrigerator exhaust port 20 into the refrigerator compartment 4, cools the refrigerator compartment 4, and is sucked into the cooling compartment 9 through the refrigerator intake air duct (not shown).

In step S12, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature of the refrigerator compartment 4 is lower than the lower limit Tr1. If it is higher, the process of step S12 is repeated. If it is lower, the process proceeds to step S13, where the freezing operation and the cold discharge operation are started. In the freezing operation and the cold discharge operation, the compressor 10 is stopped, the cooling fan 15 is operated, and the refrigeration damper 19 is closed. At the same time, the cold storage damper 22 is opened on the cold storage/cold discharge means 12 side, and the process proceeds to step S14.

During freezing and cooling operation, the cold air generated by the cold storage and cooling means 12 flows through the freezing duct 8 by the cooling fan 15, is blown into the freezing chamber 5 from the freezing outlet 16, cools the inside of the freezing chamber 5, and is sucked into the cooling chamber 9 through the freezing inlet 17.

In step S14, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is lower than the upper limit Tr2, and if it is higher, the control unit 25 proceeds to step 11 and starts the refrigeration operation and the cooling operation, and if it is lower, the control unit 25 proceeds to step S15.

In step S15, the control unit 25 uses the freezing sensor 24 to compare whether the temperature in the freezing chamber 5 is lower than the lower limit Tf1. If it is higher, the process of steps S14 and S15 is repeated. If it is lower, the control unit 25 proceeds to step S16, where it stops the compressor 10 and the cooling fan 15, closes the refrigeration damper 19, and opens the cold storage damper 22 on the cooler 11 side, thereby terminating the cold discharge operation.

The operation of the compressor 10, cooling fan 15, refrigeration damper 19, and cold storage damper 22, and an example of the temperature changes of the refrigeration sensor 23, freezing sensor 24, and cold storage and cold release means 12 during the cold storage operation and cold release operation described above will be explained with reference to Figure 5.

Here, the temperatures of the refrigeration sensor 23 and the freezing sensor 24 can be considered to be approximately equal to the temperatures of the refrigerator compartment 4 and the freezer compartment 5.

First, we will explain the cold storage operation based on the temperature change from time t1 to t3.

At time t1, when it is detected that the temperature of the freezing sensor 24 has reached the upper limit value Tf2 (S1 is YES) and the temperature of the refrigeration sensor 23 is higher than the lower limit value Tr1 (S2 is YES), the control unit 25 operates the compressor 10 and the cooling fan 15, opens the refrigeration damper 19, and sets the cool storage damper 22 to a state in which the cooler 11 side is open (S3).

As a result, cold air is supplied to the refrigerator compartment 4 and the freezer compartment 5, lowering the temperature of the refrigerator compartment 4. At this time, the relatively high-temperature air that cooled the refrigerator compartment 4 returns from the refrigerator intake air duct (not shown), and the temperature of the cooler 11 also rises accordingly, suppressing the temperature rise in the freezer compartment 5, but does not result in a drop in the temperature.

Next, at time t2, the refrigeration sensor 23 detects that the temperature has reached the lower limit Tr1 (YES in S4), and the control unit 25 closes the refrigeration damper 19 (S5). This causes cold air to be supplied to the freezer compartment 5, lowering the temperature of the freezer compartment 5.

Then, at time t3, the temperature of the refrigeration sensor 23 is lower than the upper limit Tr2 (S6 is YES), and it is detected that the temperature of the freezing sensor 24 has reached the lower limit Tf1 (S7 is YES), and the control unit 25 stops the operation of the compressor 10 and the cooling fan 15 (S8).

The above period from t1 to t3 is the cold storage operation. During the cold storage operation, the cold storage and release means 12 exchanges heat with the inlet pipe 14, which has approximately the same temperature as the cooler 11. The temperature drops over time and passes through a supercooled region that is temporarily lower than the freezing point Tc. When the supercooling is released, the temperature rises and remains approximately constant at the freezing point Tc as the phase changes from liquid to solid. Then, when it is completely solidified and the phase change ends, it reaches the temperature of the inlet pipe 14.

Next, we will explain the cooling operation based on the temperature change from time t4 to t6.

At time t4, when it is detected that the temperature of the freezing sensor 24 has reached the upper limit Tf2 (S9 is YES) and the temperature of the refrigeration sensor 23 is higher than the lower limit Tr1 (S10 is YES), the control unit 25 stops the compressor 10, operates the cooling fan 15, opens the refrigeration damper 19, and sets the cold storage damper 22 to a state in which the side of the cold storage/releasing means 12 is open (S11).

As a result, cold air is supplied to the refrigerator compartment 4 and the freezer compartment 5, and the temperature of the refrigerator compartment 4 drops. At this time, the temperature of the cold storage and release means 12 rises once, but since it becomes constant at the freezing point Tc, the temperature of the freezer compartment 5 also drops, unlike when refrigerating and cooling during cold storage operation.

Next, at time t5, the refrigeration sensor 23 detects that the temperature has reached the lower limit Tr1 (YES in S12), and the control unit 25 closes the refrigeration damper 19 (S13). This causes cold air to be supplied to the freezer compartment 5, lowering the temperature of the freezer compartment 5.

Then, at time t6, the temperature of the refrigeration sensor 23 is lower than the upper limit Tr2 (S14 is YES), and it is detected that the temperature of the freezing sensor 24 has reached the lower limit Tf1 (S15 is YES), and the control unit 25 stops the cooling fan 15 and sets the cold storage damper 22 to a state in which the cooler 11 side is open (S16).

The above period from t4 to t6 is the cold discharge operation. During the cold discharge operation, the cold storage and cold discharge means 12 exchanges heat with the air drawn in from the refrigerator compartment 4 and the freezer compartment 5, generating cold air and increasing in temperature, and as the phase changes from solid to liquid, the temperature remains almost constant at the freezing point (melting point) Tc. Then, when it is completely melted and the phase change ends, it reaches the temperature of the inlet pipe 14.

[1-3. Effects, etc.]
As described above, in this embodiment, the refrigerator 1 includes a cooler 11, a cold storage and release means 12 (cold storage material), a cooling chamber 9, an insulating partition 13 (insulating member), a cooling fan 15, a cold storage damper 22 (air path switching means), and a control unit 25.

The cooler 11 is part of the cooling cycle. The cold storage and release means 12 is in thermal contact with the inlet pipe 14 of the cooler 11. The cooling chamber 9 houses the cooler 11 and the cold storage and release means 12 and is separated from the inside of the storage by a refrigeration duct 8 (insulating member). The insulating partition 13 insulates the cooler 11 and the cold storage and release means 12 within the cooling chamber 9. The cooling fan 15 circulates the cold air generated by the cooler 11 or the cold storage and release means 12 within the storage. The cold storage damper 22 selectively flows the wind generated by the cooling fan 15 to the cooler 11 and the cold storage and release means 12. The control unit 25 controls the cooling cycle, the cooling fan 15, and the cold storage damper 22.

By closing the cold storage damper 22 on the cold storage/discharge means 12 side, it is possible to prevent the cold storage/discharge means 12 from discharging cold due to a sudden rise in the surrounding temperature. Therefore, by discharging cold at any time, it is possible to provide a refrigerator with high energy-saving performance.

As in this embodiment, the refrigerator 1 may be provided with a latent heat storage material whose freezing point is higher than the temperature of the cooler 11 and lower than the temperature in the refrigerator compartment 4, and preferably lower than the temperature in the freezer compartment 5.

As a result, the cold storage and release means 12 can reliably store cold through the inlet pipe 14, and can reliably cool the inside of the freezer chamber 5 by the latent heat of fusion when releasing the cold. This improves the efficiency of cold storage and release of cold by the cold storage and release means 12.

In addition, in this embodiment, an example has been described in which the cold storage operation is followed immediately by the cold release operation. However, in the configuration of this embodiment, when neither cold storage nor cold release is being performed, the cold storage damper 22 is always in a state in which the cooler 11 side is open, so that the cold storage and cold release means 12 can be maintained without releasing cold, and cold release operation can be freely performed at any time when cold release is desired.

(Embodiment 2)
The second embodiment will be described below with reference to FIGS.

[2-1. Configuration]
As shown in FIG. 6 , the refrigerator 1 according to the second embodiment is configured such that, in the refrigerator 1 according to the first embodiment, the control unit 25 switches the cold storage damper 22 to a cooler 11 side open state in which the air from the cooling fan 15 flows only through the cooler 11, a cold storage and cold release means 12 side open state in which the air flows only through the cold storage and cold release means 12, or a both-open state in which the air flows through both the cooler 11 and the cold storage and cold release means 12.

That is, the refrigerator 1 in this embodiment has a first cooling mode in which air flows only through the cooler 11, a second cooling mode in which air flows only through the cold storage and release means 12, and a third cooling mode in which air flows through both the cooler 11 and the cold storage and release means 12.

[2-2. Operation]
An example of the operation and function of the refrigerator 1 according to the present embodiment configured as above will now be described.

The operation of high-load operation will be explained based on Figures 6 to 8. The cold storage operation and cold release operation are the same as those in embodiment 1, so detailed explanations will be omitted.

First, in step S17, the control unit 25 uses the freezing sensor 24 to compare whether the temperature in the freezing chamber 5 is higher than the upper limit Tf2, and if it is lower, the process of step S17 is repeated, and if it is higher, the process proceeds to step S18.

In step S18, the control unit 25 uses the freezing sensor 24 to compare whether the temperature of the freezing chamber 5 is lower than Tf3, which is the temperature during high load, and if it is higher, it determines that the load of the freezing chamber 5 is high and proceeds to step S22, and if it is lower, it proceeds to step S19.

In step S19, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is higher than Tr3, which is the temperature during high load. If it is lower, it determines that the load is not high and ends high-load operation. If it is higher, it determines that the load in the refrigerator compartment 4 is high, and proceeds to step S20 to start refrigeration operation and high-load operation.

During refrigeration operation and high load operation, the compressor 10 and cooling fan 15 are operated, and the refrigeration damper 19 is opened. At the same time, both cold storage dampers 22 are opened, and the process proceeds to step S21.

During refrigeration operation and high-load operation, the cold storage damper 22 is controlled so that the cooling fan 15 blows air to both the cooler 11 and the cold storage and release means 12. This causes both the cooler 11 and the cold storage and release means 12 to generate cold air.

The generated cold air is then blown by the cooling fan 15 through the freezer duct 8 and out of the freezer outlet 16 into the freezer chamber 5, cooling the inside of the freezer chamber 5, before being sucked into the cooling chamber 9 through the freezer inlet 17.

At the same time, the cold air that has flowed through the refrigerator exhaust air duct 18 flows from the refrigerator damper 19 to the refrigerator duct 21, is blown out from the refrigerator exhaust port 20 into the refrigerator compartment 4, cools the refrigerator compartment 4, and is sucked into the cooling compartment 9 through the refrigerator intake air duct (not shown).

Then, in step S21, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is lower than the lower limit Tr1, and if it is higher, the process of step S21 is repeated, and if it is lower, the process proceeds to step S22 and starts freezing operation and high load operation.

During freezing and high-load operation, the compressor 10 and cooling fan 15 are operated, and the refrigeration damper 19 is closed. At the same time, both cold storage dampers 22 are opened, and the process proceeds to step S23.

During freezing and high-load operation, the cold air generated by the cooler 11 and the cold storage and release means 12 flows through the freezing duct 8 by the cooling fan 15, is blown into the freezing chamber 5 from the freezing outlet 16, cools the inside of the freezing chamber 5, and is sucked into the cooling chamber 9 through the freezing inlet 17.

In step S23, the control unit 25 uses the refrigeration sensor 23 to compare whether the temperature in the refrigerator compartment 4 is lower than the upper limit Tr2, and if it is higher, the control unit 25 proceeds to step S20 and starts refrigeration operation and high-load operation, and if it is lower, the control unit 25 proceeds to step S24.

In step S24, the control unit 25 uses the freezing sensor 24 to compare whether the temperature in the freezing chamber 5 is lower than the lower limit Tf1. If it is higher, the process of steps S23 and S24 is repeated. If it is lower, the control unit 25 proceeds to step S25, stops the compressor 10 and the cooling fan 15, closes the refrigeration damper 19, and opens the cold storage damper 22 on the cooler 11 side, thereby terminating high-load operation.

An example of the operation of the compressor 10, cooling fan 15, refrigeration damper 19, and cold storage damper 22 during high load operation and the temperature changes of the refrigeration sensor 23, freezing sensor 24, and cold storage/discharge means 12 in the above description will be described with reference to FIG. 8.

Here, the temperatures of the refrigeration sensor 23 and the freezing sensor 24 can be considered to be approximately equal to the temperatures of the refrigerator compartment 4 and the freezer compartment 5.

First, at time t3, when cooling of the refrigerator 1 is stopped, if food or the like is put into the refrigerator compartment 4 due to shopping or the like, the temperature of the refrigerator compartment 4 will rise. Then, at time t7, the temperature of the freezing sensor 24 reaches the upper limit Tf2 (YES in S17) and detects that it is lower than the temperature Tf3 under high load (YES in S18), and detects that the temperature of the refrigeration sensor 23 is higher than the temperature Tr3 under high load (YES in S19), the control unit 25 operates the compressor 10 and the cooling fan 15, opens the refrigeration damper 19, and opens both the cold storage dampers 22 (S20).

At this time, the wind from the cooling fan 15 flows through both the cooler 11 and the cold storage and release means 12, so that the cooler 11 and the cold storage and release means 12 simultaneously generate cold air. This causes cold air to be supplied to the refrigerator compartment 4 and the freezer compartment 5, lowering the temperatures of the refrigerator compartment 4 and the freezer compartment 5.

Next, at time t8, the refrigeration sensor 23 detects that the temperature has reached the lower limit Tr1 (YES in S21), and the control unit 25 closes the refrigeration damper 19 (S22). This causes cold air to be supplied to the freezer compartment 5, lowering the temperature of the freezer compartment 5.

Then, at time t9, the temperature of the refrigeration sensor 23 is lower than the upper limit Tr2 (YES in S23), and it is detected that the temperature of the freezing sensor 24 has reached the lower limit Tf1 (YES in S24), and the control unit 25 stops the compressor 10 and the cooling fan 15 (S25).

The period from t7 to t9 above is high load operation. During high load operation, the cold storage and release means 12 exchanges heat with the air sucked in from the refrigerator compartment 4 and the freezer compartment 5, generating cold air and increasing in temperature, and as the phase changes from solid to liquid, the temperature remains almost constant at the freezing point (melting point) Tc. At the same time, it is cooled by the inlet pipe 14, so the part exchanging heat with the air liquefies, and the area near the inlet pipe 14 becomes solidified.

[2-3. Effects, etc.]
As described above, in the present embodiment, the control unit 25 of the refrigerator 1 controls the cold storage damper 22 to switch among a first cooling mode in which air is caused to flow only through the cooler 11, a second cooling mode in which air is caused to flow only through the cold storage and cold release means 12, and a third cooling mode in which air is caused to flow through both the cooler 11 and the cold storage and cold release means 12.

As a result, during high-load operation, the cold air generated by both the cooler 11 and the cold storage and release means 12 can be used. This allows for a higher cooling capacity than cooling using only the cooler 11 (cold storage operation) or only the cold storage and release means 12 (cold release operation), and the temperature inside the refrigerator compartment 4 can be lowered quickly.

In addition, in this embodiment, the refrigerator 1 may be configured so that the control unit 25 automatically switches the cooling mode depending on time or load fluctuations.

This allows the refrigerator 1 to automatically switch to high-load operation when the load on the refrigerator 1 increases. This allows the refrigerator 1 to respond immediately to load fluctuations.

In addition, in this embodiment, the refrigerator 1 may be configured so that the control unit 25 switches the cooling modes in response to an external command.

This allows the user to decide whether to operate the refrigerator in a cool, passive mode when they want to keep power consumption low, or in a high-load mode when it is predicted that the load will be high. This allows the user to reduce power consumption at any time and reduce the temperature inside the refrigerator more quickly when the load is high.

In addition, in this embodiment, for the sake of simplicity, the freezing operation after it is determined that the load on the refrigerator compartment 4 is high is set to high load operation, and both cold storage dampers 22 are set to the open state. However, if the load on the freezing compartment 5 is not high, the freezing operation and cold storage operation (S5) or the freezing operation and cold release operation (S13) can be performed, thereby cooling the freezing compartment 5 without wasting cold energy.

Other Embodiments
As described above, the first and second embodiments have been described as examples of the technology disclosed in the present application. However, the technology in the present disclosure is not limited to these, and can be applied to embodiments in which modifications, substitutions, additions, omissions, etc. are made.

Therefore, other embodiments are given below as examples.

In the first and second embodiments, there is no means for detecting the temperature of the cold storage and release means 12, so it is unclear whether the cold storage and release means 12 has completely solidified during the cold storage operation or completely released during the cold release operation.

In response to this, for example, by detecting the temperature of the part of the cold storage and release means 12 where the temperature change is the slowest, the state of the cold storage and release means 12 can be grasped, and by performing cold release operation after completely storing cold in the cold storage operation, the cooling efficiency of the cold release operation can be further improved. Also, when further cooling is required after the cold storage and release means 12 has completely released cold in the cold release operation, the compressor 10 can be operated and cooling can be performed without loss by cooling in the cooling cycle.

In addition, in the above-mentioned first and second embodiments, the high load state was judged based on whether the refrigeration sensor 23 and the freezing sensor 24 reached or exceeded the high load temperature. However, more precise control can be achieved by judging based on the rate at which the temperature of each sensor drops during cooling, and the rate at which the temperature rises while cooling is stopped.

In addition, in the first and second embodiments, the cooling capacity is improved by simply opening both cold storage dampers 22 during high-load operation. However, by making the capacity of the cooling fan 15 variable and opening both cold storage dampers 22 during high-load operation while simultaneously increasing the capacity of the cooling fan 15, the temperature in the storage compartment can be lowered more quickly.

In addition, in the above-mentioned first and second embodiments, no mention is made of the shape of the cold storage and release means 12, but by providing fin-shaped protrusions (not shown) or making the surface uneven, the contact area with the air can be increased, thereby making it possible to use the cold more efficiently.

The present disclosure can store cold energy using a cold storage and release means that exchanges heat with an inlet pipe and can be used at any time, making it applicable to refrigerators of various types and sizes, including those for home and commercial use, and refrigeration and freezing equipment.

REFERENCE SIGNS LIST 1 Refrigerator 2 Partition 3 Insulated box 4 Refrigerating compartment 5 Freezing compartment 6 Insulated door 7 Insulated door 8 Freezing duct 9 Cooling compartment 10 Compressor 11 Cooler 12 Cold storage and release means (cold storage material)
13. Insulation partition (insulation member)
14 Inlet pipe 15 Cooling fan 16 Refrigerator outlet 17 Refrigerator suction port 18 Refrigerator outlet air duct 19 Refrigerator damper 20 Refrigerator outlet 21 Refrigerator duct 22 Cold storage damper (air duct switching means)
23 Refrigeration sensor 24 Freezing sensor 25 Control unit

Claims (3)

a cooler and a compressor which are part of a cooling cycle; a cold storage material in thermal contact with an inlet pipe of the cooler; a cooling chamber which houses the cooler and the cold storage material and is separated from the inside of the storage unit; a heat insulating member which insulates the cooler and the cold storage material within the cooling chamber; a cooling fan which circulates cold air generated by at least one of the cooler and the cold storage material into the storage unit; and an air path switching means which selectively flows the air generated by the cooling fan to the cooler and the cold storage material.
The refrigerator includes a control unit that controls the cooling cycle, the cooling fan, and the air path switching means, and an interior sensor that detects the temperature inside the refrigerator, and the control unit controls switching of the air path switching means so that, when the interior sensor reaches or exceeds a predetermined temperature, the interior is cooled in a first cooling mode in which the compressor is operated to blow air only through the cooler, and, when the interior sensor next time reaches or exceeds the same predetermined temperature as the previous time, the control unit controls switching of the air path switching means to cool the interior in a second cooling mode in which the compressor is stopped and air is blown only through the cold storage material . 2. The refrigerator according to claim 1, wherein the control unit controls switching of the air path switching means so that, when the interior sensor reaches or exceeds a predetermined temperature, the interior is cooled in a first cooling mode in which the compressor is operated to blow air only through the cooler, and, when the interior sensor next time reaches or exceeds a high load temperature that is higher than the previous time, the controller controls switching of the air path switching means to cool the interior in a third cooling mode in which the compressor is operated to blow air through both the cooler and the cold storage material . 3. The refrigerator according to claim 1, wherein the cold storage material is a latent heat storage material having a freezing point higher than a temperature of the cooler and lower than a temperature inside the refrigerator.

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