CN112013605B

CN112013605B - Refrigerator with a door

Info

Publication number: CN112013605B
Application number: CN202010976726.4A
Authority: CN
Inventors: 服部圭介; 冈田福太郎; 小沼智史
Original assignee: Hitachi Global Life Solutions Inc
Current assignee: Hitachi Global Life Solutions Inc
Priority date: 2017-04-21
Filing date: 2018-03-06
Publication date: 2022-09-09
Anticipated expiration: 2038-03-06
Also published as: CN112013605A; TW201839339A; TWI678506B; CN112066620A; CN108731347A

Abstract

The invention provides a refrigerator, which improves the temperature difference between the upper part and the lower part in a storage chamber by lowering the temperature of the lower part in the storage chamber, and ensures that the storage chamber has good use convenience. The cold air duct includes a first duct for mainly cooling an upper portion of the storage room and a second cold air duct for mainly cooling a lower portion of the storage room, and when a predetermined setting is made, a ratio of a cold air supply time by the second cold air duct to a cold air supply time by the first cold air duct is increased as compared with a case where the setting is not made.

Description

Refrigerator with a door

The application is a divisional application; the parent application has the application number of 2018101828741 and the invention name of refrigerator.

Technical Field

The present invention relates to a refrigerator.

Background

A technology for providing a refrigerator with high energy saving performance by properly detecting the temperature in a storage chamber by a temperature detection mechanism to improve the storage stability and reliability of food. For example, in a refrigerator described in patent document 1, a first cold air duct and a second cold air duct are formed, and cold air is supplied to a predetermined area in a storage chamber through each duct.

Documents of the prior art

Patent document 1: japanese patent laid-open publication No. 2014-40967

In the refrigerator described in patent document 1, the supply of cold air to the two cold air ducts is appropriately switched based on the detection results of the temperature sensors provided in the upper and lower portions of the refrigerating chamber. However, the refrigerator described in patent document 1 is controlled so as to prevent excessive cooling and high temperature, and is held at the upper and lower portions of the refrigerating chamber so that the temperature difference is small.

Disclosure of Invention

In view of the above problems, it is an object of the present invention to provide a refrigerator that can improve the temperature difference between the upper and lower portions of a storage chamber by lowering the temperature of the lower portion of the storage chamber, thereby improving the usability of the storage chamber.

The refrigerator includes a storage chamber for storing a temperature zone, a cold air duct provided on a back side of the storage chamber, and an air blowing mechanism for blowing cold air to the cold air duct, wherein the cold air duct includes a first cold air duct for mainly cooling an upper portion of the storage chamber and a second cold air duct for mainly cooling a lower portion of the storage chamber, and when a predetermined setting is made, a ratio of a cold air supply time by the second cold air duct to a cold air supply time by the first cold air duct is increased as compared with a case where the setting is not made.

The effects of the present invention are as follows.

It is possible to provide a refrigerator in which the temperature difference between the upper part and the lower part of the storage chamber is increased by lowering the temperature of the lower part of the storage chamber, and even if foods having different temperature ranges suitable for storage are used, a user can select and distinguish storage places in the same storage chamber.

Drawings

Fig. 1 is a front view of a refrigerator related to an embodiment of the present invention.

Fig. 2 is a sectional view a-a in fig. 1.

Fig. 3 is a front view of the refrigerating compartment.

Fig. 4 is a sectional view taken along line B-B of fig. 3.

Fig. 5 is a front view of a cold air duct of the refrigerating compartment according to the present embodiment.

Fig. 6 is a cross-sectional view taken along line C-C of fig. 5.

Fig. 7 is a view showing the flow of cold air in the case of cooling by the first cold air duct 11 a.

Fig. 8 is a view showing the flow of cold air in the case of being cooled by the second cold air duct 11 b.

Fig. 9 is a view showing the flow of cold air in the case of cooling by both the first cold air duct 11a and the second cold air duct 11 b.

Fig. 10 is an exploded perspective view showing a cold air duct of the refrigerator compartment.

Fig. 11 is a perspective view of panel cover 30 as viewed from the back side.

Fig. 12 is a perspective view of the flow passage forming member 41 viewed from the back side.

Fig. 13 is an enlarged perspective view showing the vicinity of the discharge port 30 in a state where the flow passage forming member 41 is fitted to the panel cover 30.

Fig. 14 is an enlarged perspective view of the panel cover 30 in the vicinity of the front recess 30w1, viewed from the front side.

Fig. 15 is a flowchart showing control of automatic rapid cooling.

Fig. 16 is a timing chart of automatic rapid cooling.

Fig. 17 is a timing chart when the lower layer cooling is set to on.

Fig. 18 is a timing chart when the lower layer cooling is set to off.

Fig. 19 is a time chart of the temperature securing heater.

In the figure: 1-refrigerator, 2a, 2 b-refrigerator door, 3-ice-making chamber, 3 a-ice-making chamber door, 3 b-storage container, 4-upper freezer, 4 a-upper freezer door, 4 b-storage container, 5 lower freezer, 5 a-lower freezer door, 5 b-storage container, 6-vegetable chamber, 6 a-vegetable chamber door, 6 b-storage container, 7-cooler, 8-cooler storage chamber, 9-in-box fan, 10-heat-insulating box, 11-refrigerator cold air duct, 11 a-first cold air duct, aa 11-extending wall of first cold air duct, 11 ab-extending wall of first cold air duct, 11 b-second cold air duct, 12-upper freezer cold air duct, 13-lower freezer cold air duct, 17-freezer return port, 18-vegetable chamber return port, 18 a-vegetable chamber return port, 18 b-vegetable compartment return outlet, 20-refrigerator compartment double damper, 20 a-damper, 20 b-damper, 21-evaporator, 22-defrost heater, 23-cylinder, 24-compressor, 25-vacuum heat insulating member, 27-drain hole, 28, 29, 40-heat insulating partition wall, 30-panel cover, 30a, 30b, 30c, 30d, 30e, 30 f-outlet, 30 t-guide protrusion, 30 w-front recess, 33a, 33b, 33 c-door pocket, 34a, 34b, 34c, 34d, 34 e-shelf, 35-decompression storage compartment, 36-ice making box, 39-refrigerator compartment return outlet, 41-flow path forming member, 41 h-cutout, 41 h-rectifier, 41 s-inclined portion, 41 v-branch portion, 42-second temperature sensor, 43-first temperature sensor, 45-third temperature sensor, 46-motor driving portion, 47-back cover, 48-food detection sensor, 50-base plate cover, 51-control base plate, 52-outside-box temperature sensor, 53-door hinge cover, 55-handle, 56-reduced-pressure storage room door, 60-freezing-room damper, 61-machine room, 62-sealing part, 63-roof surface, 64-water supply pipe, 65-reduced-pressure storage room temperature guarantee heater, and 66-water supply pipe temperature guarantee heater.

Detailed Description

Embodiments of the present invention will be described with reference to the drawings.

Fig. 1 is an external appearance of a refrigerator according to the present embodiment. As shown in fig. 1, a refrigerator 1 according to the present embodiment includes a refrigerating compartment 2, an ice making compartment 3, an upper-stage freezing compartment 4, a lower-stage freezing compartment 5, and a vegetable compartment 6 from above. The refrigerating chamber 2 includes refrigerating

chamber doors

2a and 2b divided left and right, and the ice making chamber 3, the upper freezing chamber 4, the lower freezing chamber 5, and the vegetable chamber 6 include an ice making chamber door 3a, an upper freezing chamber door 4a, a lower freezing chamber door 5a, and a vegetable chamber door 6a, respectively, which are drawn out. The refrigerating

compartment doors

2a, 2b, the ice making compartment door 3a, the upper freezing compartment door 4a, the lower freezing compartment door 5a, and the vegetable compartment door 6a will hereinafter be simply referred to as

doors

2a, 2b, 3a, 4a, 5a, 6 a. Door hinges for fixing the refrigerator 1 and the

doors

2a, 2b are provided at the upper part of the refrigerator, and the door hinges are covered by door hinge covers 53.

Fig. 2 is a sectional view a-a of the refrigerator relating to the present embodiment. The refrigerator 1 is partitioned from the outside by a heat insulating box 10 filled with a foamed heat insulating material. A plurality of vacuum insulation materials 25 are installed in the insulation box 10 of the refrigerator 1. The refrigerating chamber 2, the upper-stage freezing chamber 4, and the ice making chamber 3 are partitioned by a heat insulating partition wall 28, and the lower-stage freezing chamber 5 and the vegetable chamber 6 are also partitioned by a heat insulating partition wall 29. A plurality of door pockets are arranged in the order of upper 33a, 33b, 33c on the inside of the

doors

2a, 2b, and the refrigerating chamber 2 is divided into a plurality of storage spaces from above by a plurality of shelves in the order of 34a, 34b, 34c, 34d, 34e (see fig. 3). The

shelves

34a, 34b are partly made of glass, and the

shelves

34c, 34d, 34e are made of resin.

A decompression chamber 35 for storing food under reduced pressure is provided below the lowermost shelf 34e of the refrigerating chamber 2. A decompression pump (not shown) is provided to reduce the internal pressure of the decompression chamber 35, and a door 56 of the decompression chamber can be locked by a handle 55 to maintain the internal pressure (see fig. 3). The temperature inside the reduced-pressure storage chamber 35 can be set from the outside, and the temperature is adjusted by cold air from an outlet 38 (to which an air volume adjusting device (damper) is attached) provided on the back side of the reduced-pressure storage chamber 35, based on the temperature detected by a temperature sensor 45 provided on the back side of the reduced-pressure storage chamber 35. In the present embodiment, the decompression storage chamber 35 may be formed by being partitioned by the lowermost shelf 34e, or may be a low-temperature storage chamber (fresh air chamber) that is not decompressed and has the lowermost shelf 34e as a ceiling.

A heat-insulating partition wall 40 of the freezing chamber is provided between the upper-stage freezing chamber 4 and the lower-stage freezing chamber 5. In upper-stage freezing chamber 4, lower-stage freezing chamber 5, and vegetable chamber 6,

storage containers

3b, 4b, 5b, and 6b are provided integrally with

doors

3a, 4a, 5a, and 6a disposed in front of the respective cooling chambers, and

storage containers

4b, 5b, and 6b can be pulled out by pulling out

doors

4a, 5a, and 6a toward the near side. The storage container is also provided integrally with the door 3a in the ice making chamber 3, and the storage container 3b can be pulled out by pulling out the door 3a toward the near side. The outside-box temperature sensor 52 is provided inside a door hinge cover 53 of the refrigerator 1, for example.

The cooler 7 is provided in a cooler storage chamber 8 disposed substantially at the back of the lower-stage freezer compartment 5, and the cold air having exchanged heat with the cooler 7 is sent to each of the storage compartments of the cold storage compartment 2, the upper-stage freezer compartment 4, the lower-stage freezer compartment 5, and the ice-making compartment 3 through a cold air duct 11 (first cold air duct 11a and second cold air duct 11b) of the cold storage compartment, a cold air duct 12 of the upper-stage freezer compartment, a cold air duct 13 of the lower-stage freezer compartment, and an air duct (not shown) of the ice-making compartment by an in-compartment fan 9 provided above the cooler 7.

The cold air to be sent to each storage room is controlled by opening and closing of refrigerating room double dampers 20(20a, 20b) and freezing room damper 60, which are air volume adjusting devices. The refrigerating compartment double damper 20 is a double damper type damper including two

dampers

20a and 20b, and the damper is opened and closed by a motor driving unit (see fig. 3) to adjust the air volume.

In the case of a refrigerating room cooling operation for cooling refrigerating room 2, refrigerating room double damper 20 is opened and freezing room damper 60 is closed, and cold air is sent from blow-out

ports

30a, 30b, 30c, 30d, 31a, and 31b to refrigerating room 2 through refrigerating room duct 11. After the cold air circulates in the refrigerating compartment 2, the cold air flows into refrigerating compartment return ports 39 (see fig. 3) provided on the left and right sides of the lower portion of the refrigerating compartment, and then returns to the cooler 7. There are various methods for cooling vegetable compartment 6, and for example, a method of directly supplying cold air to vegetable compartment 6 after cooling refrigerating compartment 2, and a method of directly supplying cold air generated in cooler 7 to vegetable compartment 6 using a damper dedicated to the vegetable compartment are considered. In the present embodiment, any method of supplying cold air to vegetable compartment 6 may be used. In the example shown in fig. 2, the cold air flowing into the vegetable compartment 6 flows from the vegetable compartment return opening 18a provided in front of the lower portion of the heat insulating partition wall 29, through the vegetable compartment return duct 18, and flows into the cooler 7 from the vegetable compartment return outlet opening 18 b.

In the case of a freezing compartment cooling operation that cools the freezing compartments 4, 5 (including the ice-making compartment 3), the refrigerating compartment double damper 20 is closed, the freezing compartment damper 60 is opened, and the cold air returns to the cooler 7 from the freezing compartment return port 17 after cooling the upper-tier freezing compartment 4, the lower-tier freezing compartment 5, and the ice-making compartment 3. In the case of cooling the refrigerating chamber 2 and the freezing

chambers

4 and 5 simultaneously according to the temperature inside the refrigerator, both the refrigerating chamber double dampers 20 and the freezing chamber damper 60 are opened to supply cold air to the respective storage chambers.

The opening and closing of the

dampers

20a and 20b of the double dampers 20 of the refrigerating compartment are controlled based on the temperatures detected by a first temperature sensor 43 for detecting the temperature of the region defined by the shelf 34b and the ceiling surface of the refrigerating compartment, a second temperature sensor 42 for detecting the temperature of the region defined by the shelf 34b and the lowermost shelf 34e of the refrigerating compartment, a third temperature sensor 45 for detecting the temperature of the region defined by the lowermost shelf 34e and the heat insulating partition wall 28, and the like.

A defrosting heater 22 is provided at a lower portion of the cooler 7. The condensed water generated at the time of defrosting once falls into the drum 23, and is discharged to the evaporator 21 provided at the top of the compressor 24 through the drain hole 27. A heat sink and a heat radiation fan (not shown) are disposed in the machine chamber 61 provided at the lower portion of the rear surface of the refrigerator in addition to the compressor 24.

A control board 51 on which a memory and a connection circuit are mounted is disposed on the top wall surface of the refrigerator 1, and the freezing cycle and the air blowing system are controlled in accordance with the control stored in the control board 51. The control substrate 51 is covered with a substrate cover 50.

Fig. 3 is a front view of the inside of the refrigerating compartment 2 (the

doors

2a and 2B are omitted), and fig. 4 is an enlarged B-B sectional view of the refrigerating compartment of fig. 3. The cold air duct 11 of the refrigerating compartment, which is composed of the first cold air duct 11a and the second cold air duct 11b, is connected to the

baffle plates

20a and 20b, which are composed of two openings provided in the double damper 20 of the refrigerating compartment, respectively. Specifically, the baffle 20a side of the double damper 20 of the refrigerating compartment having a large opening area is connected to the first cold air duct 11a having a large flow path cross-sectional area and extending upward. When cooled by the first cold air duct 11a, the damper 20a and the damper 20b are opened, when cooled by the second cold air duct 11b, the damper 20a and the damper 20b are closed, and when cooled by the two ducts, the

dampers

20a and 20b are opened, respectively. The cold air duct 11a is used for cooling the upper part of the refrigerating compartment, and the cold air duct 11b is used for cooling the lower part of the refrigerating compartment.

The first cold air duct 11a is provided with

discharge ports

30e, 30f, 30a, and 30b in this order from above, and mainly cools the food placed on the

shelves

34a and 34b and the door pockets 33a and 33b in the area 2A (see fig. 2 and 4) defined by the ceiling surface 63 and the second-tier shelf 34b by the cold air fed from the respective discharge ports. The second cold air duct 11 is provided with

discharge ports

30c, 30d, and the cold air delivered from the respective discharge ports mainly cools the food placed on the

shelves

34c, 34d, 34e, which are the areas 2B (see fig. 2 and 4) divided by the second shelf 34B from the top and the fourth (lowermost) shelf 34e from the top. A decompression chamber 35 and an ice-making chamber 36 are provided in a region 2C (see fig. 2 and 4) below the shelf 34e, and are cooled by cold air from both the first cold air duct 11a and the second cold air duct 11b in common, and are regions that are easily cooled by the influence of freezing temperature zones provided below the refrigerating chamber 2.

A first temperature sensor 43 is provided in the region 2A of the refrigerator compartment 2, a second temperature sensor 42 is provided in the region 2B, and a third temperature sensor 45 is provided in the region 2C. For example, in the present embodiment, the first temperature sensor 43 is provided on the ceiling surface 63 of the refrigerator compartment 2. Second temperature sensor 42 is located between

shelf boards

34d and 34e, and is provided on panel cover 30 forming cold air duct 11 in the refrigerating compartment 2 on the back side thereof. The third temperature sensor 45 is similarly provided in the panel cover 30, and detects the temperature of the region 2C (the ambient temperature of the ice making box 36 and the reduced-pressure storage compartment 35) in which the cold air sent from the

outlets

30e, 30f, 30a, and 30b of the first cold air duct 11a and the cold air sent from the outlets 30C and 30d of the second cold air duct 11b circulate in common.

Fig. 5 is an enlarged view of the cold air duct 11 (the first cold air duct 11a and the second cold air duct 11b) in the refrigerating chamber, and each is a front view. Fig. 6 is a sectional view taken along line C-C of fig. 5. As shown in fig. 5, the first cold air duct 11a is formed to a position higher than the second cold air duct 11b at least to the height of the upper end of the second cold air duct 11b, and the width dimension of the first cold air duct 11a is larger than the width dimension of the second cold air duct 11 b.

Here, when the inside of the refrigerating chamber is cooled in a general refrigerator, refrigerating chamber upper region 2A and refrigerating chamber lower region 2B are cooled at the same time. However, when food from the outside of the refrigerator is put into only one region, the food already cooled in the other region is also cooled, and there is a concern about freezing and deterioration in quality. Therefore, in the present embodiment, the first cold air duct 11a that cools the refrigerating room upper region 2A and the second cold air duct 11B that cools the refrigerating room lower region 2B are appropriately switched based on the temperatures detected by the first temperature sensor 43, the second temperature sensor 42, and the third temperature sensor 45, so that excessive cooling is suppressed and energy saving is improved.

Fig. 7 shows the flow of cold air in the refrigerator compartment 2 when cooled by the first cold air duct 11 a. When damper 20a of refrigerating compartment double damper 20 is opened (damper 20b is closed), cold air is discharged from

discharge ports

30a, 30b, 30e, and 30f provided in first cold air duct 11 a. The discharged cold air cools food in the area 2A where the

uppermost shelves

34a and 34b and the door pockets 33a and 33b are arranged, and then reaches the area 2C partitioned by the lowermost shelf 34e and the heat insulating partition wall 28, and cools the space. Food is put into the area 2A, and when the first temperature sensor 43 detects a temperature increase in the area 2A and the second temperature sensor 42 does not detect a temperature increase in the area 2B, a cooling mode using the cold air duct 11a is performed. Since only the food in the newly input area 2A is cooled, the food in the area 2B is not excessively cooled, and energy saving performance can be improved.

On the other hand, fig. 8 shows the flow of cold air in the refrigerating compartment 2 when cooled by the second cold air duct 11 b. When the damper 20b of the refrigerating compartment double damper 20 is opened (the damper 20a is closed), the cold air is discharged from the

discharge ports

30c and 30d provided in the second cold air duct 11 b. The discharged cold air cools food mainly in the region B where the

shelves

34C, 34d, and 34e are arranged, and then reaches the region 2C defined by the lowermost shelf 34e and the heat insulating partition wall 28, and cools the space. When food is put into the area 2B and the first temperature sensor 43 does not detect a temperature increase in the area 2A and the second temperature sensor 42 detects a temperature increase in the area 2B, the cooling mode by the cold air duct 11B is performed. The inside of the area 2B can be cooled efficiently compared to the cooling mode using the cold air duct 11 a.

As shown in fig. 9, if both of the

flaps

20a and 20b of the double damper 20 of the refrigerating compartment are in the open state, a cooling mode using both of the first cold air duct 11a and the second cold air duct 11b can be implemented. This cooling mode enables effective cooling even when food is simultaneously put into the

regions

2A and 2B.

In the present embodiment, the temperature of each region in the refrigerating chamber is detected by using each temperature sensor, and the air volume adjusting device is controlled based on the detection result, whereby cooling can be performed so that the temperature of each region becomes appropriate. Therefore, the already cooled region is not excessively cooled, and cooling with improved energy saving performance is performed, thereby obtaining the effect of suppressing freezing of food and deterioration of quality.

In addition, in the refrigerator according to the present embodiment, a fourth temperature sensor (food detection sensor) 48 for detecting the food put into the lower portion of the refrigerating compartment is provided in addition to the first temperature sensor 43, the second temperature sensor 42, and the third temperature sensor 45.

As shown in fig. 3, the food detection sensor 48 is located between the shelf 34e located immediately above the depressurized storage chamber 35 and the next shelf 34c as a height position, and is located closer to the refrigerating chamber return port 39 than the center of the left and right sides as a position in the left-right direction. More specifically, the left-right direction position is preferably provided between the discharge port 30d for cooling the lower portion of the refrigerating compartment and the cooling return port 39 between the shelf 34e at the lowermost layer and the shelf 34c at the upper layer. The discharge port 30d is offset to one side (right side in the present embodiment) with respect to the left-right center of the panel cover 30, and the cooling return port 39 is also formed on one side (right side with respect to the center in the present embodiment) below the lowermost shelf 34 e.

Therefore, the cooling air passage from the discharge port 30D to the cooling return port 39 is formed, and the cooling efficiency can be improved by setting at least the right side (region 2D in fig. 3) of the center between the lowermost shelf 34e and the shelf 34D above the lowermost shelf as the rapid cooling zone. In the present embodiment, by disposing the food detection sensor 48 between the discharge port 30d and the cold air return port 39, it is possible to accurately detect that warm food is placed in the rapid cooling section, and to automatically start rapid freezing. Further, if the aluminum tray is disposed in the rapid cooling section, the user can easily recognize the space for rapid cooling.

In addition, since the second cold air duct 11b is provided with the discharge port 30c immediately below the shelf 34b located in the vicinity of the middle height of the refrigerator compartment 2, the space between the shelf 34c and the shelf 34d (region 2E in fig. 3) can also be a rapid cooling zone. Here, the food detection sensor 48 is located immediately below the shelf 34c, and can detect even if food is placed on the space above the partition 34 c. Since there is no member for partitioning the left and right sides in the region 2E, a space wider than the region 2C, that is, a region immediately above the left shelf 34d can be a target of rapid cooling.

Here, the control of the automatic rapid cooling by the food detection sensor 48 will be described with reference to fig. 15 and 16. First, it is determined whether the setting of the automatic rapid cooling mode is on (step S1). When the automatic rapid cooling mode is set to the on state, if the

doors

2a and 2b are opened and closed in step S2, the operation shifts to a monitoring state for determining whether or not rapid cooling is permitted. In step S3, when food detection sensor 48 maintains the state of being equal to or higher than the rapid cooling permission determination threshold value for a predetermined time (rapid cooling start determination time) after the transition to the monitoring state, it is regarded that food is inserted into the lower portion of refrigerating room 2, and rapid cooling is started. Here, the rapid cooling permission determination threshold value is set to a value higher than the constant temperature with respect to the detection temperature of the food detection sensor 48 when the

doors

2a and 2b are closed.

When rapid cooling is started, the compressor 24 is rotated at a high speed (2000rpm to 4000rpm), the in-box fan 9 is also rotated at a high speed, and at the same time, both the flap 20a for the first cold air duct 11a and the flap 20b for the second cold air duct 11b are opened, and cold air is supplied to both the upper portion and the lower portion of the refrigerating compartment 2, thereby cooling the entire refrigerating compartment 2 first. When the temperature detected by the food detection sensor 48 is equal to or lower than a predetermined threshold value (threshold value of the damper 20 a), the damper 20a of the first cold air duct 11a is closed. At this time, cold air is supplied only from second cold air duct 11b, and second cold air duct 11b has a discharge port only in the lower portion of refrigerating room 2, and therefore, region 2D and region 2E which are the lower portion of refrigerating room 2 are intensively cooled.

Next, when the value detected by the food detection sensor 48 is equal to or less than the predetermined threshold value (the threshold value of the damper 20b) lower than the threshold value of the damper 20a, the damper 20b of the second cold air duct 11b is also in the closed state, and the rotation of the compressor 24 and the in-box fan 9 is stopped, thereby ending the rapid cooling. The timing for bringing the

dampers

20a and 20b into the closed state may be determined based on whether or not a predetermined time has elapsed after the start of rapid cooling (step S4).

In this way, in the present embodiment, when the food detection sensor 48 detects that food is put into the lower part of the refrigerating compartment after the

doors

2a and 2b are opened and closed, the whole refrigerating compartment is first cooled by supplying cold air using both the first cold air duct 11a mainly cooling the upper part and the second cold air duct 11b mainly cooling the lower part, and then the lower part of the refrigerating compartment is intensively cooled by supplying cold air using only the second cold air duct 11 b. In particular, in the present embodiment, since the total area of the opening areas of

discharge ports

30c and 30d provided in second cold air duct 11b is smaller than the total area of the opening areas of

discharge ports

30e, 30f, 30a, and 30b provided in first cold air duct 11b, the wind speed of cold air supplied to the rapid cooling section in the lower portion of refrigerating room 2 is increased, and the space can be cooled efficiently. When cooling using only second cold air duct 11b is performed immediately after

doors

2a and 2b are opened and closed, the lower food is difficult to cool due to the high temperature of the entire refrigerating compartment, and therefore, cooling using two ducts is performed first as described above.

As a result, even if a mild hot pot is put in the lower part of the refrigerating chamber, the temperature rise of food around the food in the pot positioned in the lower part of the refrigerating chamber can be restrained, and the deterioration can be prevented. In addition, the upper part of the refrigerating chamber far away from food in the pot with mild excessive cooling distance can be restrained, and the power consumption can be reduced.

Here, although the case of cooling by the second cold air duct 11b is described in the cooling mode in fig. 8, the rotation speed of the compressor 24 and the in-box fan 9 is also low in the cooling mode in fig. 8 by controlling the cooling by using the second temperature sensor 42 for detecting the in-box temperature up to the lower part of the refrigerating compartment. In contrast, in the cooling mode of automatic rapid cooling, the rotational speed of the compressor 24 and the in-box fan 9 is increased to high-speed rotation by controlling the operation using the food detection sensor 48 provided in the vicinity of the rapid cooling zone in the lower portion of the refrigerating room. Therefore, the input of the mild food can be detected with high accuracy, and the cold air can be brought into contact with the food quickly and efficiently.

Further, the lower portion of refrigerating room 2 can be rapidly cooled not only automatically when food is put in the lower portion of refrigerating room 2, but also forcibly regardless of the presence or absence of food detection in the case of selection by a control panel or the like or setting by a user.

Next, control of cooling the lower layer in which the temperature of the lower part of refrigerating room 2 is maintained to be lower by 2 ℃. The lower cooling mode can be set on/off by the control panel, and when the mode is set on, the open state of the damper 20b is made longer (the ratio of the open state time of the damper 20b to the open state time of the damper 20a is increased) than when it is not set. Specifically, unlike the case of the off setting, a time is set in which the shutter 20a is in the closed state and only the shutter 20b is in the open state. However, the rotation speed of the compressor 24 in the lower layer cooling operation is not high speed rotation as in the rapid cooling, and is maintained at low speed rotation (1000rpm to 2000 rpm).

Next, control in the case where the lower cooling mode is set to on will be described with reference to fig. 17. In the lower stage cooling operation, when a predetermined time has elapsed after the compressor 24 is stopped, or when the temperature detected by the second temperature sensor 42 is equal to or higher than a predetermined threshold value (damper threshold value), both the

dampers

20a and 20b are opened while the compressor 24 is rotated at a low speed. Then, when the temperature detected by the second temperature sensor 42 is equal to or lower than a predetermined threshold value (threshold value of the shutter 20 a), the shutter 20a is set to the closed state. When the temperature detected by the second temperature sensor 42 is equal to or lower than a predetermined threshold value (threshold value of the shutter 20b), the shutter 20b is also in the closed state.

Even in a general refrigerator, low-temperature air in the refrigerator tends to collect downward, and even in a refrigerating chamber, the lower portion tends to be lower in temperature than the upper portion. Further, since the lower part of the refrigerating chamber can be kept at a lower temperature than a general refrigerator, when the reduced-pressure storage chamber 35 for low-temperature preservation or the like is saturated with food, it can be used instead of the space in the lower part of the refrigerating chamber, and the use convenience is good. When the lower cooling mode is set to off, the control shown in fig. 8 always opens both the

dampers

20a and 20b at the same timing and closes them at the same timing. The target space in the lower cooling mode is larger than 2D +2E (fig. 3) which is the target space in the automatic rapid cooling mode, and is the entire space between the shelf 34b and the shelf 34E.

In the present embodiment, the automatic rapid cooling mode is provided in which rapid cooling is automatically performed when food is detected to be put into a predetermined section of the lower portion of the refrigerating compartment, and the lower-layer cooling mode is provided in which the lower portion of the refrigerating compartment is cooled to a lower temperature and the temperature difference with the upper portion of the refrigerating compartment is made larger than that in the off setting. That is, it cannot be set such that only the automatic cooling mode is turned on and the lower stage cooling mode is turned off, and that only the automatic rapid cooling mode is turned off and the lower stage cooling mode is turned on. Thus, the two modes can be switched simultaneously by one operation, thereby improving the convenience of users.

In addition, when the two modes are set to be on at the same time, the cooling effect is improved as compared with the case where one mode is set to be on. That is, it is assumed that the food put into the rapid cooling section can be cooled earlier only when the automatic rapid cooling mode is set to on, but other food placed in the refrigerating chamber space other than the rapid cooling section is in a relatively high temperature state. Therefore, when the temperature of other foods stored in the rapid cooling section increases immediately after the food is put into the rapid cooling section, the temperature may exceed the refrigerating temperature range. On the other hand, if only the lower cooling mode is set to on, it is necessary to cool the food put into the rapid cooling section slowly, and there is a possibility that other food already in a relatively low temperature state is excessively cooled. In this way, by setting the automatic rapid cooling mode and the lower layer cooling mode to be on at the same time, it is possible to realize a cooling operation in which the newly input food is rapidly cooled and the influence on the temperature of the already stored food is suppressed.

Further, since components such as the heat insulating partition wall 28 provided between the depressurized storage compartment 35 and the refrigerating compartment 2 and the ice making compartment 3 and the upper-stage freezing compartment 4, and the water supply duct 64 for making ice are located near the ice making compartment 3 and the upper-stage freezing compartment 4 in the freezing temperature range, the temperature tends to be low. Therefore, in order to keep these components at a non-frozen temperature, a reduced-pressure storage chamber temperature securing heater 65 is provided in the heat insulating partition wall 28 and on the bottom surface side of the reduced-pressure storage chamber 35, and a water supply pipe temperature securing heater 66 (fig. 4) is provided in the heat insulating partition wall 28 and on the bottom surface side of the water supply pipe 64.

Further, when the lower layer cooling mode and the automatic rapid cooling mode are set to be on, the temperature of the above-described members is likely to be further lowered. Therefore, when these settings are on, as shown in fig. 19, the energization time of the decompression chamber temperature securing heater 65 and the water supply pipe temperature securing heater 66 is made longer than that when the settings are off, and freezing is more reliably prevented. Further, since the purpose of these temperature-maintaining heaters is to prevent a decrease in temperature, the purpose can be achieved not only by a method of extending the energization time of the heater but also by another method of increasing the output of the heater.

Next, the structure of cold air duct 11 in the refrigerating compartment will be described in detail. As shown in fig. 10, the first cold air duct 11a and the second cold air duct 11b in the present embodiment are configured by a panel cover 30, a flow passage forming member 41, a seal member 62, a windshield cover 32, and the like.

First, panel cover 30 is made of synthetic resin and includes a base portion 30v for housing the damper for the refrigerating compartment and a vertical portion 30u extending upward in the vertical direction from base portion 30 v. Among the vertical portions 30u of the panel cover 30, on the side facing the refrigerating compartment, a plurality of front surface recessed portions 30w are formed at different height positions corresponding to the discharge ports 30a to 30 d. The panel cover 30 is located at the center in the left-right direction on the rear surface side of the refrigerating compartment 2. Two right and left

discharge ports

30e, 30f are formed at the upper end of the panel cover 30, and cool air from the top plate

side discharge ports

30e, 30f can be guided to the uppermost door pocket 33 a.

Fig. 11 is a perspective view of the panel cover 30 viewed from the back surface (inner surface) side. On the back surface side of the panel cover 30, a guide convex portion 30t is formed at a position corresponding to the front concave portion 30 w. Cold air inlets 30t0 are formed in the lower surfaces (upstream side surfaces) of these guide protrusions 30t, and cold air flowing into the guide protrusions 30t from these cold air inlets 30t0 is guided to the front side in the refrigerator compartment 2 by the upper wall surface of the front recess 30 w.

Next, the flow passage forming member 41 will be described. The flow passage forming member 41 is formed by cutting expanded polystyrene or the like, and as shown in fig. 10, includes a lower flow passage portion 41v fitted to the base portion 30v of the panel cover 30 and a main body flow passage portion 41x fitted to the vertical portion 30x of the panel cover 30. The lower flow path portion 41v is provided with the refrigerating compartment double damper 22, and constitutes a part of the first cold air duct 11a communicating with the baffle plate 22a of the refrigerating compartment double damper 22 and a part of the second cold air duct 11b communicating with the baffle plate 22b of the refrigerating compartment double damper 22.

Further, a plurality of cutout holes 41h are formed at different positions in the main body flow passage portion 41x of the flow passage forming member 41. Specifically, the cutout hole 41h1 for the first cold air duct 11a is formed at the highest position and one-step lower position, and the cutout hole 41h2 for the second cold air duct 11b is formed at the lowest position and one-step higher position. Here, the width of cutout hole 41h1 formed in the upper side is larger than that of cutout hole 41h2 formed in the lower side. This is because the width regions where the

discharge ports

30a, 30b located above the first cold air duct 11a are formed are wider than the width regions where the

discharge ports

30c, 30d of the second cold air duct 11b are formed.

As shown in fig. 12, a rectifying portion 41k, which is a projecting piece extending in the vertical direction, is provided between the plurality of cut holes 41h1 located above and adjacent to each other. The flow regulating portion 41k guides the cold air from the upstream side upward, and performs an operation of efficiently flowing the cold air from the

discharge ports

30e and 30f on the top plate side to the door pocket 33 a. The rectifying portion 41k also has an effect of reinforcing the flow passage forming member 41 at the portion sandwiched by the cutout hole 41h1, and an effect of preventing the seal member 62 from being bent.

The first groove 41ua and the second groove 41ub are formed on the rear surface (inner surface) side of the flow passage forming member 41, and the first cold air duct 11a and the second cold air duct 11b are formed between the flow passage forming member and the sealing member 62, respectively. The first groove portion 41ua has an extension wall 11aa extending in the vertical direction on one end side in the lateral direction (right side in fig. 12), an extension wall 11aa extending to a position higher than the upper end of the second groove portion 41ub on the other end side in the lateral direction (left side in fig. 12), and a widening wall 11ab extending linearly or arcuately toward the ceiling on the downstream side. Thus, the first cold air duct 11a has an upstream portion located at a height parallel to the second groove 41ub, a flow path expansion portion gradually expanding the flow path cross-sectional area, and a downstream portion having a flow path cross-sectional area larger than the upstream portion. Here, the vertical projection of the baffle 20a and the vertical projection of the discharge port 30e of the first cold air duct 11a are in a positional relationship in which at least a part of them overlap each other. Therefore, since the cold air flowing in from the baffle plate 20a located on the lower end portion one (left) side of the panel cover 30 flows toward the discharge port 30e located on the upper end portion one (left) side of the panel cover 30 without receiving a large ventilation resistance, the cold air can be efficiently sent into the refrigerating compartment 2.

A branch portion 41v that branches the cold air in the first cold air duct 11a in the left-right direction is formed on the back surface side of the downstream portion of the flow path forming member 41, and the branched cold air flows to the groove outlets 41h3, 41h4 provided at the upper end of the flow path forming member 41 in correspondence with the

discharge ports

30e, 30 f. This enables the cold air to be efficiently supplied to the uppermost door pocket 33a located in the left and

right doors

2a and 2 b.

Fig. 13 is an enlarged perspective view of the vicinity of the height of the second shelf 34b in a state where the flow passage forming member 41 is fitted to the rear surface of the panel cover 30. The cold air flowing from the upstream side to the downstream side through the space surrounded by the inner surface of the groove 41u of the flow path forming member 41 and the inner surface of the seal member 62 is guided to the cold air inlet 30t0 of the panel cover 30 by the inclined portion 41s gradually dented (deepened) toward the front side as it goes toward the downstream side. By providing the inclined portion 41s on the wall surface of the flow path forming member 41 located on the upstream side of the cold air inlet 30t0 in this manner, the height of the guide convex portion 30t can be reduced, and the influence of the air flow resistance in the duct due to the guide convex portion 30t can be suppressed. Further, since the vertical dimension of the inclined portion 41s is smaller than the vertical dimension of the cutout hole 41h, the thickness reduction of the flow path forming member 41 accompanying the formation of the inclined portion 41s can be suppressed, and the reduction of the heat insulating performance can be prevented.

Here, a plurality of cold air flow inlets 30t0 are formed in the left-right direction on the upstream side surface of the guide convex portion 30t, but since the partition wall 30t2 is provided between the adjacent cold air flow inlets 30t0, not only the discharge port having a substantially wide width is formed, but also the strength of the panel cover 30 can be secured and the intrusion of dust can be prevented. In addition to the discharge port 30b, the

discharge ports

30a, 30c, and 30d have the same configuration.

The flow passage forming member 41 has a curved shape bulging toward the front side at the center in the left-right direction. Therefore, the sectional area of the flow path of the cold air duct formed by the flow path forming member 41 and the seal member 62 can be enlarged. A panel cover 30 is also the same, and has a curved shape in horizontal section. Therefore, the cold air can be easily discharged radially from panel cover 30 into refrigerating compartment 2, and the inside of refrigerating compartment 2 can be cooled efficiently.

As shown in fig. 14, the panel cover 30 also has a curved surface on the downstream side inner wall surface (the upper wall surface of the front surface recessed portion 30w 1) 30t1 of the guide projecting portion 30 t. Therefore, the cold air flowing from the inclined portion 41s of the flow path forming member 41 into the guide projection 30t through the cold air inlet 30t0 is guided forward while suppressing the ventilation resistance, contributing to the improvement of the cooling efficiency.

In the present embodiment, the front recess 30w facing the cooling chamber side (front surface side) corresponds to the discharge ports 30a to 30d in appearance. However, since the area where cold air flow inlet 30t0 is located is the area where cold air is actually discharged, the sum of the areas of cold air flow inlets 30t0 is the sum of the opening areas of outlets 30a to 30 d.

The sealing member 62 is a plate-like member made of a synthetic resin material or the like, and is disposed so as to cover the entire first groove portion 41ua and the second groove portion 41ub of the flow path forming member 41. Further, by being connected to the inner case 47 using the seal member 62, the cold air duct can be provided on the rear surface side of the refrigerating compartment.

With the structure of the present embodiment described above, the following effects can be obtained.

First, in the first cold air duct 11a in which the flow path length increases and the ventilation resistance increases, the cross-sectional area of the flow path is made larger than that of the second cold air duct 11b, so that the ventilation resistance until the cold air reaches the downstream side can be suppressed as a whole, and as a result, the cold air can be more efficiently sent to the upper space of the refrigerating room 2, and the energy saving performance can be improved.

Next, a guide protrusion 30t extending in the horizontal direction and receiving the cold air coming from the upstream side is formed inside the wall surface forming the front surface side of the cold air duct 11, and a cold air inlet 30t0 is formed on the upstream side wall surface (lower surface) of the guide protrusion 30t, so that the cold air in the cold air duct 11 can be efficiently taken in. The cold air flowing in from cold air inlet 30t0 passes through the inside of guide projection 30t and is guided to the front side in refrigerator compartment 2 via the upper wall surface of front recess 30 w. As a result, the cooling efficiency is improved due to the increase in the amount of discharged cold air.

Further, since the discharge port is formed so as to penetrate the lower surface of the guide convex portion 30t in the vertical direction, it is difficult for a user to recognize the discharge port even when viewing the interior of the refrigerating chamber 2 from the front side, and the appearance is improved. The lower surface of the guide projection 30t is not limited to the horizontal direction, but may have an effect of making the outlet difficult to recognize and an effect of increasing the discharge air volume to some extent as long as it is closer to the horizontal direction than the vertical direction.

Further, since the horizontally long rectangular front surface concave portion 30w located at a position different in height has the same width regardless of the size of the width region of the discharge port, it is possible to maintain high appearance without giving a sense of incongruity to the user. The width of each front surface concave portion 30w is not limited to be exactly the same, and may be in the range of 90% to 110%.

In the present embodiment, the discharge port formed in the front surface side of first cold air duct 11a is larger than the discharge port formed in the front surface side of second cold air duct 11b, and therefore, cold air can be supplied to a wide range of the upper portion of refrigerating room 2, which is generally difficult to cool, and cooling efficiency can be improved. In addition, since all the

discharge ports

30a and 30b are formed in the first cold air duct 11a extending higher than the second cold air duct 11b at a position higher than the uppermost discharge port 30c of the second cold air duct 11b, cold air can be intensively supplied to the upper portion of the refrigerator compartment 2, and cooling efficiency can be improved.

On the other hand, the upper end of the second cold air duct 11b is located at a position lower than half of the height of the refrigerating compartment 2, and all the discharge ports of the second cold air duct 11b are located at a position lower than half of the height of the refrigerating compartment 2. Therefore, if the baffle 20a of the refrigerating compartment double damper 20 is closed and the baffle 20b is opened, the supply of cold air can be concentrated in the lower part of the refrigerating compartment 2, and thus rapid cooling when warm food is put in the lower part of the refrigerating compartment 2 and lower layer cooling in the lower part of the refrigerating compartment 2 can be realized at a lower temperature than the upper part. Here, the space of not more than half the height of the refrigerating compartment 2 corresponds to a position slightly higher than the heat insulating partition wall 28 near the average user waistline, and since the frequency of use is high, it is effective to subject the space to rapid cooling and lower layer cooling. Further, keeping the lower part of the refrigerating chamber 2 at 2 ℃ or lower can greatly improve the long-term keeping quality of food and the like left unused. Even if a gentle food is put into a part of the space of refrigerating room 2, the temperature rise in the other space can be suppressed by rapid cooling of the space, and as a result, the storage property of refrigerating room 2 as a whole can be improved.

Claims

1. A refrigerator is provided with:

a storage compartment for refrigerating the temperature zone;

a cold air duct provided on a back side of the storage chamber; and

an air supply mechanism for supplying cold air to the cold air pipeline,

the cold air duct has a first cold air duct for mainly cooling the upper part of the storage chamber, a second cold air duct for mainly cooling the lower part of the storage chamber, and a temperature sensor disposed at the lower part of the storage chamber,

the refrigerator is characterized in that,

the disclosed device is provided with:

a first damper capable of opening and closing the first cold air duct; and

a second baffle plate capable of opening and closing the second cold air duct,

when the detected value of the temperature sensor after detecting the opening and closing of the door of the storage room rises compared with the closing time point of the door and maintains a constant time, the first baffle and the second baffle are set to be in an opening state, and after the cold air is supplied by using both the first cold air duct and the second cold air duct, the cold air is supplied by using only the second cold air duct.

2. The refrigerator according to claim 1,

the first shutter is closed and the second shutter is kept open in response to a decrease in the detection value of the temperature sensor, and the second shutter is also closed in response to a further decrease in the detection value of the temperature sensor.

3. The refrigerator according to claim 1,

an outlet of the second cold air duct and a storage chamber return port disposed in the storage chamber,

the temperature sensor is located between the discharge port and the storage chamber return port in the left-right direction.

4. A refrigerator is provided with:

a storage compartment for refrigerating the temperature zone;

a cold air duct provided on a back side of the storage chamber; and

an air supply mechanism for supplying cold air to the cold air pipeline,

the cold air duct has outlets at the upper and lower parts of the storage chamber,

a temperature sensor disposed in the storage chamber,

the refrigerator is characterized in that,

the disclosed device is provided with:

a first shutter capable of opening and closing the discharge port at the upper part; and

a second baffle plate capable of opening and closing the lower discharge port,

when the detected value of the temperature sensor detected after the door of the storage room is opened and closed rises for a certain time compared with the closing time of the door, the first flap and the second flap are opened, and then only one side of the first flap and the second flap close to the temperature sensor is opened to supply cold air.

5. A refrigerator is provided with:

a storage compartment for refrigerating the temperature zone;

a cold air duct provided on a back side of the storage chamber; and

an air supply mechanism for supplying cold air to the cold air pipeline,

a temperature sensor disposed in the storage chamber,

the refrigerator is characterized in that,

a second baffle plate capable of opening and closing the lower discharge port,

the storage room is provided with a structure for showing or presenting the content of the space for rapid cooling air to the user,

when the user performs the setting, the first flap and the second flap are opened, and then only one side of the first flap and the second flap close to the structure is opened to supply the cold air.