CN108731347A - Refrigerator - Google Patents
Refrigerator Download PDFInfo
- Publication number
- CN108731347A CN108731347A CN201810182874.1A CN201810182874A CN108731347A CN 108731347 A CN108731347 A CN 108731347A CN 201810182874 A CN201810182874 A CN 201810182874A CN 108731347 A CN108731347 A CN 108731347A
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- Prior art keywords
- mentioned
- cold
- cold duct
- refrigerating chamber
- duct
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D11/00—Self-contained movable devices, e.g. domestic refrigerators
- F25D11/02—Self-contained movable devices, e.g. domestic refrigerators with cooling compartments at different temperatures
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D17/00—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
- F25D17/04—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection
- F25D17/06—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation
- F25D17/062—Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation in household refrigerators
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D21/00—Defrosting; Preventing frosting; Removing condensed or defrost water
- F25D21/06—Removing frost
- F25D21/08—Removing frost by electric heating
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D23/00—General constructional features
- F25D23/12—Arrangements of compartments additional to cooling compartments; Combinations of refrigerators with other equipment, e.g. stove
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D29/00—Arrangement or mounting of control or safety devices
- F25D29/005—Mounting of control devices
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2500/00—Problems to be solved
- F25D2500/06—Stock management
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2600/00—Control issues
- F25D2600/06—Controlling according to a predetermined profile
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F25—REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
- F25D—REFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
- F25D2700/00—Means for sensing or measuring; Sensors therefor
- F25D2700/12—Sensors measuring the inside temperature
- F25D2700/123—Sensors measuring the inside temperature more than one sensor measuring the inside temperature in a compartment
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- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Combustion & Propulsion (AREA)
- Physics & Mathematics (AREA)
- Mechanical Engineering (AREA)
- Thermal Sciences (AREA)
- General Engineering & Computer Science (AREA)
- Cold Air Circulating Systems And Constructional Details In Refrigerators (AREA)
Abstract
The present invention provides a kind of refrigerator, and the temperature difference for storing indoor top and lower part is improved by making storage indoor lower part low temperature, keeps the ease of use of storeroom good.Have the storeroom of refrigerating temperature zone, the cold duct for the back side for being set to the storeroom, to the wind pushing mechanism of above-mentioned cold duct transporting cold-air, above-mentioned cold duct has the first pipe on the top for mainly cooling down above-mentioned storeroom and mainly cools down the second cold duct of the lower part of above-mentioned storeroom, in the case where carrying out scheduled setting, compared with the case where not setting, the ratio relative to the cool-air feed time using above-mentioned first cold duct using the cool-air feed time of above-mentioned second cold duct is improved.
Description
Technical field
The present invention relates to refrigerators.
Background technology
It is proposed to improve by suitably detect the indoor temperature of storage with temperature testing organization the keeping quality of food with reliably
Property and the technology that the high refrigerator of energy saving is provided.For example, in the refrigerator described in following patent documents 1, the first cold air is formed
Pipeline and the second cold duct, by each pipeline to storing indoor presumptive area cool-air feed.
Existing technical literature
Patent document 1:Japanese Unexamined Patent Publication 2014-40967 bulletins
In the refrigerator described in above patent document 1, based on being set to each temperature for refrigerating indoor top and lower part
The testing result of sensor suitably switches the cool-air feed of two cold ducts.But the ice described in the patent document 1
Case to prevent sub-cooled, as high temperature in a manner of controlled, in the top of refrigerating chamber and lower part in such a way that the temperature difference is smaller
It is kept.
Invention content
Present invention point in view of the above problems, its purpose is to provide one kind by making storage indoor lower part low temperature
It improves and stores the temperature difference on indoor top and lower part, makes the good refrigerator of the usability of storeroom.
Refrigerator has the storeroom of refrigerating temperature zone, the cold duct for the back side for being set to the storeroom, to above-mentioned cold
The wind pushing mechanism of feed channel transporting cold-air, above-mentioned cold duct have first refrigerator pipe on the top for mainly cooling down above-mentioned storeroom
Road and the second pipe of lower part for mainly cooling down above-mentioned storeroom and are not set in the case where carrying out scheduled setting
Situation is compared, and is improved relative to cool-air feed time using above-mentioned first cold duct using above-mentioned second cold duct
The ratio of cool-air feed time.
The effect of the present invention is as follows.
A kind of temperature difference, i.e. for being improved by making lower part low temperature in storeroom and storing indoor top and lower part can be provided
The food for keeping the temperature band for being adapted for preserving different, user also can store place by selective discrimination in identical storeroom
Refrigerator.
Description of the drawings
Fig. 1 is the front view for the refrigerator for being related to embodiments of the present invention.
Fig. 2 is the A-A sectional views in Fig. 1.
Fig. 3 is the front view of refrigerating chamber.
Fig. 4 is the B-B sectional views in Fig. 3.
Fig. 5 is the front view of the cold duct for the refrigerating chamber for being related to present embodiment.
Fig. 6 is the C-C sectional views in Fig. 5.
Fig. 7 is the figure for indicating the flowing by the cold air in the case of the first cold duct 11a coolings.
Fig. 8 is the figure for indicating the flowing by the cold air in the case of the second cold duct 11b coolings.
Fig. 9 is the stream for indicating the cold air by both the first cold duct 11a and the second cold duct 11b in the case of cooling
Dynamic figure.
Figure 10 is the exploded perspective view for the cold duct for indicating refrigerating chamber.
Figure 11 is the stereogram of the dial hood 30 from back side.
Figure 12 is the stereogram from the back side of channel-forming member 41.
Figure 13 is the expansion near the outlet 30 in the state of indicating to be fitted into channel-forming member 41 in dial hood 30
Big stereogram.
Figure 14 is the expansion stereogram before dial hood 30 near recess portion 30w1 from face side.
Figure 15 is the flow chart for the control for indicating automatic rapid cooling.
Figure 16 is the time diagram of automatic rapid cooling.
Figure 17 be by lower layer's cooling setpoint be connect when time diagram.
Figure 18 be by lower layer's cooling setpoint be disconnect when time diagram.
Figure 19 is the time diagram that temperature ensures heater.
In figure:1-refrigerator, 2-refrigerating chambers, 2a, 2b-refrigerating-chamber door, 3-ice-making compartments, 3a-ice-making compartment door, 3b-receipts
Receive container, 4-upper layer freezing chambers, 4a-upper layer refrigerating chamber door, 4b-accommodating container, 5 lower layer's freezing chambers, 5a-lower layer's freezing chamber
Door, 5b-accommodating container, 6-vegetable compartments, 6a-vegetable compartment door, 6b-accommodating container, 7-coolers, the storage of 8-coolers
Room, 9-box fans, 10-heat insulating boxes, 11-refrigerating chamber cold ducts, the first cold ducts of 11a-, 11aa-first are cold
The extension wall of feed channel, the broadening wall of the first cold ducts of 11ab-, the second cold ducts of 11b-, 12-upper layer freezing chambers are cold
Feed channel, 13-lower layer's freezing chamber cold ducts, 17-freezing chamber return ports, 18-vegetable compartment return ducts, 18a-vegetable compartment
Return port, 18b-vegetable compartment return outlet, the double windscreens of 20-refrigerating chambers, 20a-baffle, 20b-baffle, 21-evaporators,
22-Defrost heaters, 23-cylinders, 24-compressors, 25-vacuum heat-insulation components, 27-osculums, 28,29,40-heat insulations
Dilapidated walls, 30-dial hoods, 30a, 30b, 30c, 30d, 30e, 30f-outlet, 30t-guiding protrusion, 30w-front recess portion,
33a, 33b, 33c-door pocket, 34a, 34b, 34c, 34d, 34e-shelf, 35-decompression storerooms, 36-ice making casees, 39-is cold
Tibetan room return port, 41-channel-forming members, 41h-cut hole, 41h-rectification part, 41s-rake, 41v-branch,
42-second temperature sensors, the 43-the first temperature sensor, 45-third temperature sensors, 46-motor driving parts, 47-
Back side cover, 48-food inspection sensors, 50-substrate covers, 51-control base boards, 52-box outside temperature sensors, 53-door hinges
Chain guard, 55-handles, 56-decompression door of storage room, 60-freezing chamber windscreens, 61-Machine Rooms, 62-seal members, 63-tops
Plate face, 64-feedwater pipings, 65-decompression storage compartment temperatures ensure that heater, 66-feedwater piping temperature ensure heater.
Specific implementation mode
It is illustrated using attached drawing about embodiments of the present invention.
Fig. 1 is the appearance for the refrigerator for being related to present embodiment.As shown in Figure 1, the refrigerator 1 of present embodiment from top by cold
Hide room 2, ice-making compartment 3, upper layer freezing chamber 4, lower layer's freezing chamber 5, the composition of vegetable compartment 6.Refrigerating chamber 2 has the refrigerating chamber of left and right segmentation
Door 2a, 2b, ice-making compartment 3, upper layer freezing chamber 4, lower layer's freezing chamber 5, vegetable compartment 6 have respectively drawer type ice-making compartment door 3a, on
Layer refrigerating chamber door 4a, lower layer refrigerating chamber door 5a, vegetable compartment door 6a.It is below that refrigerating-chamber door 2a, 2b, ice-making compartment door 3a, upper layer is cold
Chilling chamber door 4a, lower layer refrigerating chamber door 5a, vegetable compartment door 6a are referred to as door 2a, 2b, 3a, 4a, 5a, 6a.Fixed refrigerator 1 and door 2a,
The door hinge of 2b is set to refrigerator top, and door hinge is covered by door hinge chain guard 53.
Fig. 2 is the A-A sectional views for the refrigerator for being related to present embodiment.The case of refrigerator 1 is outer and case is interior by by filling-foam
Heat-barrier material and the heat insulating box 10 that is formed separates.Multiple vacuum heat insulation materials 25 are installed in the heat insulating box 10 of refrigerator 1.It is logical
Cross heat-insulated partition walls 28 and separate refrigerating chamber 2, upper layer freezing chamber 4 and ice-making compartment 3, in addition, again by heat-insulated partition walls 29 every
Open lower layer's freezing chamber 5 and vegetable compartment 6.With from multiple doors that are arranged in order of upper 33a, 33b, 33c on the inside of the case of door 2a, 2b
Pocket, refrigerating chamber 2 are divided into multiple storage spaces (with reference to Fig. 3) on by multiple shelves according to 34a, 34b, 34c, 34d, 34e.
In addition, shelf 34a, 34b are the shelf that a part is made of glass, 34c, 34d, 34e are made of resin.
The decompression storeroom 35 of food is stored in the lower part setting decompression of the lowest level shelf 34e of refrigerating chamber 2.In order to drop
It is low decompression storeroom 35 internal pressure and have decompression pump (not shown) depressurize storeroom to maintain internal pressure
Door 56 can use the locking of handle 55 (with reference to Fig. 3).Depressurizing temperature in storeroom 35 can be from external setting-up, with from being set to
The cold air for depressurizing the outlet 38 (being equipped with quantity regulating device for air (windscreen)) of the back side of storeroom 35 subtracts according to by being set to
The temperature that the temperature sensor 45 of the back side of storeroom 35 detects is pressed to be adjusted into trip temperature.Also, make in the present embodiment
For depressurize storeroom 35, divided and formed by lowest level shelf 34e, or using lowest level shelf 34e as top plate,
The cryopreservation room (chilled room) that do not depressurize.
The heat-insulated partition walls 40 of freezing chamber are set between upper layer freezing chamber 4 and lower layer's freezing chamber 5.On upper layer freezing chamber 4,
In lower layer's freezing chamber 5 and vegetable compartment 6, receipts are integrally respectively set with door 3a, 4a, 5a, the 6a being configured in front of respective cooling chamber
It receives container 3b, 4b, 5b, 6b, accommodating container 4b, 5b, 6b can be also pulled out by pulling out door 4a, 5a, 6a to front side.In ice-making compartment
It also is wholely set accommodating container with door 3a in 3, accommodating container 3b can be also pulled out by pulling out door 3a to front side.In addition, outside case
Temperature sensor 52 is such as set to the inside of the door hinge chain guard 53 of refrigerator 1.
Cooler 7 is set in the cooler receiving room 8 at the substantially back for being configured at lower layer's freezing chamber 5, with cooler 7 into
Gone heat exchange cold air by being set to the box fan 9 of the top of cooler 7 and (first is cold via refrigerating chamber cold duct 11
Feed channel 11a, the second cold duct 11b), upper layer freezing chamber cold duct 12, lower layer's freezing chamber air supply duct 13 and ice making
Room air supply duct (not shown) is defeated to each storeroom of refrigerating chamber 2, upper layer freezing chamber 4, lower layer's freezing chamber 5, ice-making compartment 3 respectively
It send.
Pass through quantity regulating device for air, that is, refrigerating chamber double windscreen 20 (20a, 20b), freezing chambers to the conveying of the cold air of each storeroom
The opening and closing of windscreen 60 is controlled.Refrigerating chamber pair windscreen 20 is the windscreen for the double Flapper types for having two baffles 20a, 20b, is passed through
Motor driving part makes above-mentioned baffle be opened and closed and adjust air quantity (with reference to Fig. 3).
In the case where the refrigerating chamber of cooling refrigerating chamber 2 cools down operating, opens the double windscreens 20 of refrigerating chamber, closes freezing chamber wind
Gear 60, via refrigerating chamber pipeline 11 from blow-off outlet 30a, 30b, 30c, 30d, 31a, 31b to 2 transporting cold-air of refrigerating chamber.It is refrigerating
After having recycled cold air in room 2, cold air flows into the refrigerating chamber return port 39 for the left and right side for being set to refrigerating chamber lower part (with reference to figure
3), it is then back to cooler 7.The cooling means of vegetable compartment 6 there are many method, for example, it is contemplated that cool refrigerating chamber 2 it is rear to
Vegetable compartment 6 is directly transported the method for cold air, is directly generated into the conveying cooler 7 of vegetable compartment 6 using the dedicated windscreen of vegetable compartment
Cold air method.In the present embodiment, about can be arbitrary situation to the cool-air feed method of vegetable compartment 6.In Fig. 2 institutes
In the example of record, the cold air of vegetable compartment 6 is flowed into from the vegetable compartment return port 18a in front of the lower part for being set to heat-insulated partition walls 29
By vegetable compartment return duct 18, returns to outlet 18b from vegetable compartment and flow into cooler 7.
In the case where the freezing chamber of cooling freezing chamber 4,5 (including ice-making compartment 3) cools down operating, the double windscreens of refrigerating chamber are closed
20, freezing chamber windscreen 60 is opened, cold air is after cooling upper layer freezing chamber 4, lower layer's freezing chamber 5 and ice-making compartment 3, from freezing
Room return port 17 returns to cooler 7.The operating for also having while cooling down refrigerating chamber 2 and freezing chamber 4,5 according to the temperature inside the box, in the feelings
Under condition, the double windscreens 20 of refrigerating chamber are opened with freezing chamber windscreen 60 and to each storeroom transporting cold-airs.
First temperature sensor 43 of the temperature in the region divided by shelf 34b and the top plate face of refrigerating chamber according to detection,
Detection by the second temperature sensor 42 of temperature in the region divided the shelf 34b and lowest level shelf 34e of refrigerating chamber, detection by
The temperature of the detections such as the third temperature sensor 45 of the temperature in the region that lowest level shelf 34e is divided with heat-insulated partition walls 28 controls
The opening and closing of baffle 20a, 20b of refrigerating chamber pair windscreen 20.
In the lower part of cooler 7, Defrost heater 22 is set.Generated condensed water once falls into cylinder 23 when defrosting, passes through
Osculum 27 is emitted into the evaporator 21 for being set to 24 top of compressor.In the Machine Room 61 for being set to refrigerator lower backside
The fan (not shown) of radiator and heat transmission is also configured other than compressor 24.
The control base board 51 that configuration is equipped with memory, connects circuit on the roof of refrigerator 1 is controlled according to being stored in
The control of freeze cycle and supply air system is implemented in control in substrate 51.Control base board 51 is covered by substrate cover 50.
Fig. 3 is the front view (door 2a, 2b are omitted) inside refrigerating chamber 2, and Fig. 4 is the B-B section views for amplifying the refrigerating chamber of Fig. 3
Figure.It is connected to by the first cold duct 11a and the second cold duct 11b refrigerating chamber cold ducts 11 constituted by being set to
Baffle 20a, 20b that two opening portions of refrigerating chamber pair windscreen 20 are constituted.Specifically, in refrigerating chamber pair windscreen 20, opening
The big sides baffle 20a of area are connected to flow passage cross-sectional area greatly and extend to the first cold duct 11a of top.Also, by
Baffle 20a is opened in the case of one cold duct 11a coolings, closes baffle 20b, by the situation of the second cold duct 11b coolings
Lower closing baffle 20a, baffle 20b is opened, in addition, respectively opening baffle 20a, 20b in the case of by two tube-cooleds.Into
Cold duct 11a is used when the cooling on row refrigerating chamber top, and cold duct 11b is used when cooling down refrigerating chamber lower part.
Outlet 30e, 30f, 30a, 30b are sequentially arranged from above in the first cold duct 11a, with from each outlet
The cold air of conveying is mainly cooling to be positioned over region 2A (with reference to Fig. 2,4) the i.e. shelves divided by top plate face 63, second layer shelf 34b
The food of 34a, 34b, door pocket 33a, 33b.Outlet 30c, 30d are set on the second cold duct 11, using from each discharge
The cold air of mouth conveying is mainly cooling to be positioned over by being drawn from upper several second shelf 34b with from the 4th layer of (lowest level) shelf 34e of upper number
Region 2B (with reference to figure 2,4) the i.e. food of shelf 34c, 34d, 34e divided.In the region 2C (ginsengs compared to shelf 34e by lower part
According to Fig. 2,4) middle be arranged depressurizes storeroom 35, ice making case 36, by coming from the first cold duct 11a and the second cold duct 11b
The cold air of two sides commonly cools down, in addition, the influence for the cryogenic temperature band room of the lower part due to being set to refrigerating chamber 2 is easy
Cooled region.
First temperature sensor 43 is set in the region 2A of refrigerating chamber 2, second temperature sensor is set in the 2B of region
42, third temperature sensor 45 is set in the 2C of region.For example, in the present embodiment, the first temperature sensor 43 is set to
The top plate face 63 of refrigerating chamber 2.Second temperature sensor 42 is located between shelf 34d and 34e, is set to be formed and is set to refrigerating chamber
The dial hood 30 of 2 inboard refrigerating chamber cold duct 11.Third temperature sensor 45 is similarly provided at dial hood 30, detection by
Outlet 30c, 30d conveying of outlet 30e, 30f, 30a, 30b of first cold duct 11a and the second cold duct 11b
The temperature for the region 2C (ice making case 36, the ambient temperature for depressurizing storeroom 35) that cold air commonly recycles.
Fig. 5 is by refrigerating chamber cold duct 11 (the first cold duct 11a, the second cold duct 11b) widened figure, respectively
It is front view.In addition, Fig. 6 is the C-C sectional views of Fig. 5.As shown in figure 5, the first cold duct 11a is formed to than the second refrigerator pipe
The position of road 11b high, until the as little as upper end level of the second cold duct 11b, the width dimensions of the first cold duct 11a are than second
The width dimensions of cold duct 11b are big.
Here, in the case of cooling in refrigerating chamber in general refrigerator, under refrigerating chamber upper area 2A and refrigerating chamber
Portion region 2B is cooled simultaneously.But in the case where only putting into the food outside refrigerator into a certain region, in another party
Region in the food that has cooled down it is also cooled, worry the deterioration of freezing and quality.Therefore, in the present embodiment, pass through
Based on the temperature detected by the first temperature sensor 43, second temperature sensor 42 and third temperature sensor 45, suitably
The second cold duct of the first cold duct 11a of the cooling refrigerating chamber upper area 2A of switching, cooling refrigerating chamber lower area 2B
11b inhibits excessive cooling and improves energy saving.
The flowing of the cold air by the refrigerating chamber 2 in the case of the first cold duct 11a coolings is indicated in the figure 7.If making cold
The baffle 20a for hiding room pair windscreen 20 is to open (baffle 20b is closed) state, then from the discharge for being set to the first cold duct 11a
Cold air is discharged in mouth 30a, 30b, 30e, 30f.The cold air of discharge is mainly cooling shelf 34a, 34b and door configured with top layer
After food in the region 2A of pocket 33a, 33b, the region 2C divided by undermost shelf 34e and heat-insulated partition walls 28 is reached
And carry out the cooling in the space.The input food in the 2A of region, 43 detection zone 2A of the first temperature sensor temperature rise,
And in the case that region 2B temperature rises are not detected in second temperature sensor 42, implement the cooling mould using cold duct 11a
Formula.Due to only mainly cooling down the food in new Input area 2A, food that will not be in the 2B of sub-cooled region also can be improved
Energy saving.
On the other hand, indicate in fig. 8 by the second cold duct 11b carry out it is cooling in the case of refrigerating chamber 2 cold air
Flowing.If the baffle 20b of the double windscreen of refrigerating chamber 20 is made to be to open (baffle 20a is closed) state, from being set to the second cold air
Cold air is discharged in outlet 30c, 30d of pipeline 11b.The cold air of discharge is in the area for mainly cooling configuration shelf 34c, 34d, 34e
After the food of domain B, reaches the region 2C that lowest level shelf 34e is divided with heat-insulated partition walls 28 and carry out the cold of the space
But.The input food in the 2B of region is not detected the temperature rise of region 2A in the first temperature sensor 43 and second temperature passes
In the case that sensor 42 detects the temperature rise of region 2B, implement the refrigerating mode carried out by cold duct 11b.Relative to profit
With the refrigerating mode of cold duct 11a, can be cooled effectively in the 2B of region.
Moreover, as shown in figure 9, if the baffle 20a and 20b of the double windscreen of refrigerating chamber 20 is made both to be in an open state,
It can implement the refrigerating mode using both the first cold duct 11a and the second cold duct 11b.If implementing the refrigerating mode
Then even if in region 2A, 2B simultaneously input food in the case of can be cooled effectively.
In the present embodiment, by using the temperature in each region in each temperature sensor detection refrigerating chamber, according to its inspection
Output control quantity regulating device for air is surveyed, can be cooled down in such a way that the temperature of each region becomes suitable.It therefore, will not mistake
The region cooled down is spent, can implement to improve cooling down for energy saving and the effect of the food freezing that is inhibited, quality deterioration
Fruit.
In addition, in the refrigerator of present embodiment, in addition to above-mentioned first temperature sensor 43, second temperature sensor 42,
Other than third temperature sensor 45, also set up for detecting the 4th temperature sensor (food to refrigerating chamber lower part input food
Detection sensor) 48.
As shown in figure 3, food inspection sensor 48 is putting positioned at the tight upside of decompression storeroom 35 as height and position
Between plate 34e and its next shelf 34c, it is located at as left and right directions position and leans on refrigerating chamber return port 39 compared to left and right center
The side at place.As more specific left and right directions position be preferably disposed on undermost shelf 34e and its upper layer shelf 34c it
Between the cooling of refrigerating chamber lower part outlet 30d and cooling return port 39 between.Also, outlet 30d is compared to dial hood
Side (being right side in present embodiment) is partial in 30 left and right center, and cooling return port 39 is also formed under lowest level shelf 34e
Side (in present embodiment, on the right side compared to center) in side.
Therefore, become the cold air path from outlet 30d to cooling return port 39, by least will be in lowest level shelf
Compared to center, (the region 2D in Fig. 3) is used as rapid cooling section, Neng Gouti on the right side between 34e and shelf 34d thereon
High cooling efficiency.Also, in the present embodiment, by between outlet 30d and cold air return port 39 fabricated food detect
Sensor 48 can accurately detect the case where placed warm food in the rapid cooling section, can automatically start
Rapid freezing.Also, if configuring aluminium pallet in rapid cooling section, recognizable user's energy is that rapid cooling is used
Space.
In addition, tight downsides of the second cold duct 11b due to the shelf 34b near the intermediate altitude positioned at refrigerating chamber 2
Outlet 30c is also set up, the space (the region 2E in Fig. 3) between shelf 34c and shelf 34d can be made also to become rapid cooling
Section.Here, food inspection sensor 48 is located at the tight downside of shelf 34c, even if the spatially placement food on partition board 34c
In the case of also can detect.In addition, due in the 2E of region there is no the component of partition will be controlled, also can will be compared to
The region of the tight upside of the big space of region 2C width, i.e. left side shelf 34d is as rapid cooling object.
Here, the control about the automatic rapid cooling carried out by food inspection sensor 48, uses Figure 15 and Figure 16
It illustrates.First, it is determined that whether the setting of automatic rapid cooling pattern connects (step S1).In automatic rapid cooling pattern
When being set as the state connected, in step s 2 to for determining whether in the case of the on-off action of progress door 2a, 2b
The monitored state of rapid cooling shifts.In step s3, after being shifted to monitored state, food inspection sensor 48 will be anxious
Quickly cooling but allows in the case of judging that the state of critical value or more maintains Time constant (rapid cooling starts to judge the time), is considered as
In the lower part input food of refrigerating chamber 2, start rapid cooling.Here, rapid cooling allows to judge critical value relative to closing door
The detection temperature of food inspection sensor 48 when 2a, 2b sets the high value of steady temperature.
If starting rapid cooling, make 24 high speed rotation of compressor (2000rpm~4000rpm), the also high speed of box fan 9
While rotation, both it is to beat to make the baffle 20b of the baffle 20a and the second cold duct 11b of the first cold duct 11a
Open state cools down entire refrigerating chamber 2 first to the top of refrigerating chamber 2 and lower part both sides' cool-air feed.Then, in food inspection
The temperature that sensor 48 is detected is to make the first refrigerator pipe in the case of scheduled critical value (critical value of baffle 20a) is below
The baffle 20a of road 11a is in off state.At this point, only from the second cold duct 11b cool-air feeds, the second cold duct 11b due to
Only there is outlet in the lower part of refrigerating chamber 2, so, concentrate cooling region 2D and region 2E as 2 lower part of refrigerating chamber.
Secondly, it is the scheduled critical value (gear lower than baffle 20a critical values in the value that food inspection sensor 48 is detected
The critical value of plate 20b) it is below in the case of, the baffle 20b of the second cold duct 11b is also in off state, stop compressor 24
And the rotation of box fan 9, terminate rapid cooling.In addition, making the opportunity that baffle 20a, baffle 20b are in off state can be with base
Whether judged (step S4) by the predetermined time after starting rapid cooling.
In this way, in the present embodiment, after the opening and closing of door 2a, 2b, being detected cold with food inspection sensor 48
It hides in the case that room lower part put into food, using the first cold duct 11a on main cooling top, mainly cools down the of lower part
After both two cold duct 11b cool-air feeds and entire refrigerating chamber cooling first, it is cold to only use the second cold duct 11b supplies
Gas simultaneously concentrates cooling refrigerating chamber lower part.Especially in the present embodiment, the outlet due to being set on the second cold duct 11b
The opening of outlet 30e, 30f, 30a, the 30b of the gross area of the opening area of 30c, 30d than being set to the first cold duct 11b
The gross area of area is small, therefore improves the wind speed of the cold air supplied to the rapid cooling section of 2 lower part of refrigerating chamber, can be effectively
The cooling space.Also, in the case where carrying out only using the cooling of the second cold duct 11b after door 2a, 2b opening and closing at once,
Due to the high influence of refrigerating chamber bulk temperature, the food of lower part is difficult to cool down, therefore such as above-mentioned, carries out using two pipelines first
Cooling.
As a result, can inhibit the food in the pot of refrigerating chamber lower part mild chafing dish is put into refrigerating chamber lower part
The food temperature of surrounding rises and prevents from deteriorating.In addition, sub-cooled remote refrigeration of food in mild pot can be inhibited
Room top and reduce consumption electric power.
Here, even if explanation carries out cooling situation with the second cold duct 11b if refrigerating mode in above-mentioned Fig. 8,
In refrigerating mode in Fig. 8, using detection the temperature inside the box until the second temperature sensor 42 of refrigerating chamber lower part is controlled, press
The rotary speed of contracting machine 24 and box fan 9 is also low speed rotation.For this, in the refrigerating mode of automatic rapid cooling,
Controlled using the food inspection sensor 48 being set near the rapid cooling section of refrigerating chamber lower part, make compressor 24 with
And the rotary speed of box fan 9 rises to high speed rotation.Therefore, the input of mild food and opposite can accurately be detected
Quickly and efficiently cold air is made to contact in its food.
Also, the not only automatically rapid cooling if the lower part input food in refrigerating chamber 2, also by by control panel
In the case that the selection of equal progress, user set, can not also discussing the presence or absence of food inspection, all forcibly rapid cooling is cold
Hide the lower part of room 2.
Secondly, using each temperature sensor and each cold duct, about 2 DEG C low with the temperature compared to 2 top of refrigerating chamber
The control of lower layer's cooling of the temperature of lower of above mode Keep cool room 2 illustrates.Lower layer's refrigerating mode can use control
The setting that panel is turned on/off, in the case where the pattern is set as connection, compared to making baffle the case where setting
The opening state of 20b is elongated (to improve the ratio of the opening state time of the baffle 20b of the opening state time relative to baffle 20a
Example).Specifically, different from the case where setting is disconnected, setting baffle 20a is in off state and only baffle 20b is in an open state
Time.But the rotary speed of the compressor 24 in lower layer's cooling operating such high speed rotation, dimension when not being rapid cooling
Hold low speed rotation (1000rpm~2000rpm).
Secondly, the control in the case of connecting is set as about lower layer's refrigerating mode to illustrate using Figure 17.In lower layer
In cooling operating, compressor 24 stop after pass through the predetermined time in the case of or second temperature sensor 42 detection
In the case that temperature is predetermined critical (baffle critical value) or more, make to make while 24 low speed rotation of compressor baffle 20a,
Both 20b are in an open state.Then, it is that (baffle 20a's is critical for predetermined critical in the detection temperature of second temperature sensor 42
Value) it is below in the case of so that baffle 20a is in off state.Moreover, the detection temperature in second temperature sensor 42 is predetermined faces
In the case of dividing value (critical value of baffle 20b) is below, baffle 20b is also in off state.
Even if in general refrigerator, it may have the Cryogenic air in refrigerator is easy to assemble downwards, even if in refrigerating chamber, phase
Than in top, the tendency of lower part low temperature, but according to the present embodiment, the further difference of the temperature of top and lower part can be made
Change, even the different food of temperature band suitable for preserving also may be selected to distinguish storage place.Moreover, because refrigerating chamber lower part phase
Than low temperature can be remained in general refrigerator, therefore the case where decompression storeroom 35 of Cord blood etc. is saturated because of food
Under, it can be utilized instead of the space of the refrigerating chamber lower part, ease of use is good.Also, lower layer's refrigerating mode is set as disconnected
The case where opening is control as shown in Figure 8, and baffle 20a, 20b always make the two be in an open state on identical opportunity, always in phase
Same opportunity is in off state.In addition, the object space of lower layer's refrigerating mode is than pair as above-mentioned automatic rapid cooling pattern
The 2D+2E (Fig. 3) of image space greatly, whole spaces between shelf 34b and shelf 34e.
In the present embodiment, have and carried out automatically if input food in the predetermined interval of refrigerating chamber lower part if detecting
The above-mentioned automatic rapid cooling pattern of rapid cooling makes refrigerating chamber lower part low temperature and makes and refrigerating chamber compared to the when of setting is disconnected
Above-mentioned lower layer's refrigerating mode that the temperature difference on top becomes larger, the on-off of the setting in these patterns always with one-off simultaneously
It carries out.That is, can not be set as only making above-mentioned automatic refrigerating mode be connect and make lower layer's refrigerating mode be disconnect, make it is above-mentioned automatic
Rapid cooling pattern is to disconnect and lower layer's refrigerating mode is only made to be connection.In this way, above-mentioned due to that can be switched simultaneously with once-through operation
Two patterns, therefore improve the convenience of user.
In addition, above-mentioned two pattern concurrently set for connection in the case of, compared to be set as one by one connect
Situation improves cooling effect.I.e., it is assumed that only above-mentioned automatic rapid cooling pattern is set as the case where connecting being capable of cooling throwing ahead of time
Enter the food in rapid cooling section, but it is temperature to be placed into other food in the refrigerator space other than rapid cooling section
Spend relatively high state.Therefore, in rapid cooling section shortly after input food, the temperature of other food that has been stored in
In the case of rising, there is a possibility that more than refrigerating temperature zone.On the other hand, it is assumed that only above-mentioned lower layer's refrigerating mode is set as
The case where connection, the cooling food for putting into rapid cooling section are natural slowly, compare there is also being in and
The possibility that other food of the speech lower state of temperature are cooled excessively.In this way, by by above-mentioned automatic rapid cooling pattern
It is concurrently set with above-mentioned lower layer's refrigerating mode to connect, it can be achieved that being quickly cooled down the food newly put into and inhibiting to being stored in
Food the cooling operating that influences of temperature.
In addition, being set to decompression storeroom 35, the heat-insulated partition walls between refrigerating chamber 2 and ice-making compartment 3, upper layer freezing chamber 4
28, the component of feedwater piping 64 of ice making etc. is due to attached in ice-making compartment 3, the upper layer freezing chamber 4 in cryogenic temperature band
Closely, it therefore is easy to become low temperature.Therefore, in order to which these components remain the temperature that do not freeze, in heat-insulated partition walls 28 and subtract
While pressing the bottom surface side setting decompression storage compartment temperature of storeroom 35 to ensure heater 65, and water supply interior in heat-insulated partition walls 28
The bottom surface side setting feedwater piping temperature of pipeline 64 ensures heater 66 (Fig. 4).
Moreover, if lower layer's refrigerating mode, automatic rapid cooling pattern is made to be set as connecting, above-mentioned component is easy into one
Walk low temperature.Therefore, as shown in figure 19 when these are set as connecting, when being compared to disconnection setting, make decompression storage compartment temperature
It ensures that heater 65, feedwater piping temperature ensure that the conduction time of heater 66 is long, is more reliably prevented from and freezes.Also, due to
These temperature ensure that the purpose of heater is to prevent the reduction of temperature, therefore more than make the conduction time of heater extended side
Method, even improving the other methods of the output of heater, purpose can also be reached.
Secondly, it about the structure of refrigerating chamber cold duct 11, is described in detail.The first cold air in present embodiment
Pipeline 11a and the second cold duct 11b are as shown in Figure 10, by dial hood 30, channel-forming member 41, seal member 62 and
Windshield covers 32 etc. are constituted.
First, dial hood 30 is synthetic resin system, has the base portion 30v of storage refrigerating chamber windscreen, from base portion 30v
The vertical component effect 30u extended above to vertical direction.The side towards refrigerating chamber in the vertical component effect 30u of dial hood 30 with discharge
Multiple front recess portion 30w are formed on the corresponding different height and positions of mouth 30a~30d.Also, the dial hood 30 is located at refrigerating chamber
The left and right directions center of 2 back side.In addition, forming left and right two outlets 30e, 30f in the upper end of dial hood 30, can make
Door pocket 33a of the cold air of outlet 30e, 30f from the top plate side to topmost.
Stereogram when Figure 11 is the dial hood 30 from the back side (inner face) side.In the back side of dial hood 30, with it is upper
It states the corresponding positions front recess portion 30w and forms guiding protrusion 30t.Also, below these guiding protrusion 30t (upstream side)
On be respectively formed cold air inflow entrance 30t0, flowing into the cold air being oriented in the 30t of protrusion from these cold air inflow entrances 30t0 passes through front
The upper wall of recess portion 30w is guided towards the front side in refrigerating chamber 2.
Secondly, it is illustrated about channel-forming member 41.Channel-forming member 41 adds the cuttings such as expanded polystyrene (EPS)
Work etc. and formed, as shown in Figure 10, have the lower section flow path portion 41v for the base portion 30v for being embedded in dial hood 30, be embedded in panel
The main body flow path portion 41x of the vertical component effect 30x of cover 30.Lower section flow path portion 41v installs the double windscreens 22 of refrigerating chamber, and composition and refrigerating chamber
A part of first cold duct 11a of the baffle 22a connections of double windscreens 22 is connected to the baffle 22b of refrigerating chamber pair windscreen 22
The second cold duct 11b a part.
In addition, on the main body flow path portion 41x of channel-forming member 41, multiple cut holes are formed on the different position of height
41h.Specifically, the cut hole 41h1 of the first cold duct 11a is formed on highest position and one layer of position lower than it,
In minimum position and the cut hole 41h2 for forming the second cold duct 11b on high one layer of position than its.Here, being formed in
The cut hole 41h1 of side is compared to the cut hole 41h2 for being formed in lower section, and width dimensions are big.It is located at the first cold air this is because being formed
Outlet 30c, the 30d of the width regions of outlet 30a, 30b above pipeline 11a than forming the second cold duct 11b is wide
It is wide to spend region.
Also, it is provided as vertically prolonging as shown in figure 12 between the multiple cut hole 41h1 for being located above and abutting
The rectification part 41k for the protrusion tab stretched.Rectification part 41k guides the cold air from upstream side upward, effectively into enforcement cold air
The action flowed from outlet 30e, 30f of top plate side to door pocket 33a.Reinforce by cut hole in addition, rectification part 41k also has
The effect of the channel-forming member 41 of the part of 41h1 clampings, the effect for preventing seal member 62 to be bent.
In addition, the first groove portion 41ua and the second groove portion 41ub is formed in the back side (inner face) side of channel-forming member 41,
The first cold duct 11a and the second cold duct 11b are respectively constituted between seal member 62.First groove portion 41ua is in right and left
The extension wall 11aa extended to vertical direction is formed to one end (right side in Figure 12), another side is (in Figure 12 in left and right directions
Left side), until the position higher than the second upper ends groove portion 41ub forms extension wall 11aa, formed in its downstream side linear to top plate
Or the broadening wall 11ab that extends of arc-shaped ground.It is formed as a result, positioned at arranged side by side with the second groove portion 41ub in the first cold duct 11a
Upstream portion in the height of setting, by flow path cross sectional area, slowly widened flow path expansion section, flow path cross sectional area are bigger than upstream portion
Downstream portion.Here, the vertical of the vertical projection of the baffle 20a of the first cold duct 11a, outlet 30e is projected as at least one
Divide the position relationship of overlapping.Therefore, because the cold air flowed into from the baffle 20a positioned at the lower end of dial hood 30 one (left side) side is not
By big ventilation resistance to the outlet 30e flowings positioned at dial hood 30 upper end one (left side) side, therefore can be effectively
The transporting cold-air into refrigerating chamber 2.
Moreover, being formed in the back side of the downstream portion of channel-forming member 41 in the lateral direction makes the first cold duct
The branch 41v of cold air branch in 11a, cold air after branch are formed in flow path to being arranged in correspondence with outlet 30e, 30f
Slot outlet 41h3,41h4 flowing of 41 upper end of component.Thereby, it is possible to effectively to the top layer in left and right door 2a, 2b
Door pocket 33a cool-air feeds.
Figure 13 is the height of the second layer shelf 34b in the state that back side of dial hood 30 has been fitted into channel-forming member 41
Expansion stereogram near degree.The groove portion 41u inner faces and seal member of channel-forming member 41 are downstream flowed through from upstream side
The cold air in the space that 62 inner faces are surrounded by the rake 41s that more downstream surface side is slowly recessed and (deepens) more forward, to
The cold air inflow entrance 30t0 of dial hood 30 is oriented to.In this way, by the flow path forming portion positioned at the upstream sides cold airflow entrance 30t0
Rake 41s is set on 41 wall surface of part, the height for being oriented to protrusion 30t can be reduced, can inhibit and managed caused by being oriented to protrusion 30t
The influence of ventilation resistance in road.Also, the vertical direction size by the vertical direction size ratio cut hole 41h of rake 41s is small,
It can inhibit the thickness diminution of the channel-forming member 41 generated with the formation of rake 41s, prevent the reduction of heat-proof quality.
Here, form multiple cold air inflow entrance 30t0 in left-right direction in the upstream side for being oriented to protrusion 30t, but due to
Partition walls 30t2 is set between adjacent cold air inflow entrance 30t0, therefore is not only the wide discharge of substantially formation width
Mouthful, additionally it is possible to ensure the intensity of dial hood 30 and prevents the intrusion of dust.Also, not only outlet 30b, outlet 30a,
30c, 30d are also identical structure.
In addition, channel-forming member 41 is the curved shape that central portion is roused to face side in the lateral direction.Therefore, it can incite somebody to action
Expanded by the cold duct flow path cross sectional area that channel-forming member 41 and seal member 62 are formed.One dial hood 30 is also identical,
Horizontal cross-section is curved shape.Therefore, cold air can easily radially diffusely be discharged from dial hood 30 into refrigerating chamber 2,
It can effectively cool down in refrigerating chamber 2.
Moreover, as shown in figure 14, (front recess portion 30w1's is upper for the downstream side internal face of the guiding protrusion 30t of dial hood 30
Wall surface) 30t1 also has curved surface.Therefore, it is led from the rake 41s of channel-forming member 41 by the 30t0 inflows of cold air inflow entrance
Cold air into protrusion 30t inhibits to be guided forwards while ventilation resistance, helps to improve cooling efficiency.
In the present embodiment, the rows of being equivalent in appearance of each front recess portion 30w towards the refrigerating chamber side (front side)
Export 30a~30d.But what it is due to practical discharge cold air is region where cold air inflow entrance 30t0, is mentioning each row
It refer to the area summation of each cold air inflow entrance 30t0 in the case of the opening area for exporting 30a~30d.
Seal member 62 is by the plate-shaped member of the formation such as synthetic resin material, to cover the first of channel-forming member 41
The mode of groove portion 41ua and the second groove portion 41ub entirety configures.In addition, interior case 47 is connected to by using seal member 62, it can
Cold duct is set to the back side of refrigerating chamber.
By the structure of the present embodiment described above, following effect can be obtained.
First, about the first cold duct 11a that ventilation resistance becomes larger by flow path length, by the sectional area for making flow path
It is bigger than the second cold duct 11b, cold air can be inhibited to reach the ventilation resistance before downstream as a whole, as a result, can be more
Effectively to 2 upper space transporting cold-air of refrigerating chamber, energy saving can be improved.
Secondly, it is formed on the inside of the wall surface of front side for forming cold duct 11 and extends in the horizontal direction and block from upper
The guiding protrusion 30t of cold air that trip side is come, due to forming cold air inflow (below) in the upstream side wall surface of guiding protrusion 30t
Mouth 30t0, therefore the cold air that can be effectively introduced into cold duct 11.In addition, the cold air flowed into from cold air inflow entrance 30t0
By being oriented to the inside of protrusion 30t and being guided towards the front side in refrigerating chamber 2 via the upper wall of front recess portion 30w.As
As a result, improving cooling efficiency due to increasing the air quantity of discharge cold air.
In addition, due to forming outlet in a manner of penetrating through and be oriented to below the 30t of protrusion in vertical direction, even
Situation of the user from face side in refrigerating chamber 2 is also difficult to recognize outlet, improves aesthetic appearance.Also, it is oriented to protrusion 30t
Below be not limited to level, as long as being horizontally directed compared to vertical direction, can also play outlet to a certain extent
The effect of the effect, increase draft capacity that are difficult to.
Moreover, because on the different position of height it is horizontally long it is rectangular-shaped before recess portion 30w no matter the width of outlet
The size for spending region is all identical width, therefore does not have indisposed sense for user, can maintain aesthetic appearance higher.And
And the width dimensions of each front recess portion 30w be not limited to it is stringent identical, can be in the range of 90%~110.
In addition, in the present embodiment, the outlet ratio due to being formed in the first front sides cold duct 11a is formed in
Outlet before two cold duct 11b is big, therefore can be to being generally difficult to supply in the wide range in cooling 2 top of refrigerating chamber
To cold air, cooling efficiency is improved.Also, the first cold duct 11a than the second cold duct 11b high is extended to due to than
The position of the top layer outlet 30c high of two cold duct 11b forms all outlet 30a, 30b, therefore can be to refrigeration
Cool-air feed in 2 upper-part centralized of room improves cooling efficiency.
On the other hand, the upper end of the second cold duct 11b is located at the position lower than the half in the height of refrigerating chamber 2, the
Whole outlets of two cold duct 11b are all located at the position lower than the half in the height of refrigerating chamber 2.Therefore, if closed
The baffle 20a and opening baffle 20b of refrigerating chamber pair windscreen 20 just can concentrate cool-air feed in the lower part of refrigerating chamber 2, therefore can
Realize rapid cooling when 2 lower part of refrigerating chamber puts into mild food, under cryogenically Keep cool compared with top 2 lower part of room
Layer is cooling.Here, 2 mid-height of refrigerating chamber space below is relative to the heat-insulated partition walls 28 close to average user's stringcourse
It is equivalent to slightly high position, due to the use of frequency height, therefore the object that the space is cooled down as rapid cooling, lower layer is that have
Effect.Moreover, 2 lower part of refrigerating chamber is remained 2 DEG C or less the long-term preservabilities that can greatly improve idle food etc..In addition, i.e.
A part of space in refrigerating chamber 2 is set to put into mild food, since its space rapid cooling can also inhibit other space temperature
Degree rises, and can also improve the whole keeping quality of refrigerating chamber 2 as a result.
Claims (10)
1. a kind of refrigerator, has:
The storeroom of refrigerating temperature zone;
It is set to the cold duct of the back side of the storeroom;And
To the wind pushing mechanism of above-mentioned cold duct transporting cold-air,
Above-mentioned cold duct has first cold duct on the top for mainly cooling down above-mentioned storeroom and mainly cools down above-mentioned storage
The second cold duct of the lower part of room is hidden,
The refrigerator is characterized in that,
In the case where having carried out scheduled setting, compared with the case where not setting, improves and utilize above-mentioned second cold duct
The cool-air feed time relative to using above-mentioned first cold duct the cool-air feed time ratio.
2. a kind of refrigerator, has:
The storeroom of refrigerating temperature zone;
It is set to the cold duct of the back side of the storeroom;And
To the wind pushing mechanism of above-mentioned cold duct transporting cold-air,
Above-mentioned cold duct has first cold duct on the top for mainly cooling down above-mentioned storeroom and mainly cools down above-mentioned storage
The second cold duct of the lower part of room is hidden,
The refrigerator is characterized in that,
If detecting that the lower part in above-mentioned storeroom has put into food after the door opening and closing of above-mentioned storeroom, state in use
After both first cold duct and above-mentioned second cold duct cool-air feed, it is cold to only use above-mentioned second cold duct supply
Gas.
3. refrigerator according to claim 2, which is characterized in that
Temperature sensor is configured between the outlet and the return port of above-mentioned cold air of above-mentioned second cold duct, is based on above-mentioned temperature
Degree sensor detection has put into food in the lower part of above-mentioned storeroom.
4. refrigerator according to claim 2, which is characterized in that
If detecting, the lower part in above-mentioned storeroom has put into food, compared with the case where being not detected, improves compressor
Rotary speed.
5. refrigerator according to claim 2, which is characterized in that
Compared with the summation of the opening area of the outlet of above-mentioned first cold duct, the outlet of above-mentioned second cold duct
The summation of opening area is small.
6. a kind of refrigerator, which is characterized in that
It is scheduled be set as connection in the case of, it is automatic if detecting that the predetermined interval in refrigerating chamber lower part has put into food
Rapid cooling is carried out, also, makes above-mentioned refrigerating chamber lower part low temperature, compared with when disconnecting setting, is increased and refrigerating chamber top
The temperature difference.
7. a kind of refrigerator, which is characterized in that
Have automatic rapid cooling pattern and lower layer's refrigerating mode, if the automatic rapid cooling pattern is detected in refrigerating chamber lower part
Predetermined interval put into food and then carry out rapid cooling automatically, which makes above-mentioned refrigerating chamber lower part low temperature,
Compared with when disconnecting setting, increase the temperature difference with refrigerating chamber top, above-mentioned automatic rapid cooling pattern and above-mentioned lower layer cool down mould
The scheduled on/off of formula is switched simultaneously using one-off.
8. the refrigerator described according to claim 6 or 7, which is characterized in that
Have the cold duct for the back side for being set to above-mentioned refrigerating chamber and the wind pushing mechanism to above-mentioned cold duct transporting cold-air,
Above-mentioned cold duct has the first cold duct for mainly cooling down above-mentioned refrigerating chamber top and mainly cools down above-mentioned refrigeration
Second cold duct of room lower part.
9. refrigerator according to claim 8, which is characterized in that
After the door opening and closing of above-mentioned refrigerating chamber, if detecting, the predetermined interval in above-mentioned refrigerating chamber lower part has put into food,
After stating both the first cold duct and above-mentioned second cold duct cool-air feed in use, above-mentioned second refrigerator pipe is only used
Road cool-air feed.
10. refrigerator according to claim 8, which is characterized in that
It is above-mentioned be set as connection in the case of, with disconnect set when compared with, improve cold using above-mentioned second cold duct
Ratio of the gas service time relative to the cool-air feed time using above-mentioned first cold duct.
Priority Applications (2)
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CN202010975216.5A CN112066620A (en) | 2017-04-21 | 2018-03-06 | Refrigerator with a door |
CN202010976726.4A CN112013605B (en) | 2017-04-21 | 2018-03-06 | Refrigerator with a door |
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JP2017084122A JP6800083B2 (en) | 2017-04-21 | 2017-04-21 | refrigerator |
JP2017-084122 | 2017-04-21 | ||
JP2017084120A JP2018179467A (en) | 2017-04-21 | 2017-04-21 | Refrigerator |
JP2017-084120 | 2017-04-21 | ||
JP2017179738A JP6847010B2 (en) | 2017-09-20 | 2017-09-20 | refrigerator |
JP2017-179738 | 2017-09-20 |
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CN202010976726.4A Division CN112013605B (en) | 2017-04-21 | 2018-03-06 | Refrigerator with a door |
CN202010975216.5A Division CN112066620A (en) | 2017-04-21 | 2018-03-06 | Refrigerator with a door |
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CN202010975216.5A Pending CN112066620A (en) | 2017-04-21 | 2018-03-06 | Refrigerator with a door |
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Cited By (2)
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CN110657629A (en) * | 2019-09-23 | 2020-01-07 | 广州美的华凌冰箱有限公司 | Refrigerator, control method and control device thereof, and computer-readable storage medium |
US20230309779A1 (en) * | 2022-03-23 | 2023-10-05 | Roberta Ficken | Cleaning refrigerator |
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JP3219692B2 (en) * | 1996-06-26 | 2001-10-15 | 株式会社東芝 | refrigerator |
JP3490379B2 (en) * | 2000-07-13 | 2004-01-26 | 株式会社東芝 | refrigerator |
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- 2018-03-06 CN CN201810182874.1A patent/CN108731347A/en active Pending
- 2018-03-06 CN CN202010976726.4A patent/CN112013605B/en active Active
- 2018-03-06 CN CN202010975216.5A patent/CN112066620A/en active Pending
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Patent Citations (3)
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CN1177718A (en) * | 1996-08-08 | 1998-04-01 | 三菱电机株式会社 | Refrigerated and cold store |
CN1963349A (en) * | 2005-11-10 | 2007-05-16 | Lg电子株式会社 | Cool air supply duct of refrigerator |
CN105806010A (en) * | 2016-05-17 | 2016-07-27 | 合肥美菱股份有限公司 | Air-cooled refrigerator comprising temperature-and-humidity-adjustable area and control method of air-cooled refrigerator |
Cited By (2)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN110657629A (en) * | 2019-09-23 | 2020-01-07 | 广州美的华凌冰箱有限公司 | Refrigerator, control method and control device thereof, and computer-readable storage medium |
US20230309779A1 (en) * | 2022-03-23 | 2023-10-05 | Roberta Ficken | Cleaning refrigerator |
Also Published As
Publication number | Publication date |
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CN112013605B (en) | 2022-09-09 |
TW201839339A (en) | 2018-11-01 |
CN112066620A (en) | 2020-12-11 |
CN112013605A (en) | 2020-12-01 |
TWI678506B (en) | 2019-12-01 |
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Address after: Tokyo, Japan, Japan Applicant after: Hitachi Global Living Program Co., Ltd. Address before: Tokyo, Japan, Japan Applicant before: Hitachi Household Electric Appliance Co. |
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Application publication date: 20181102 |