WO2020173354A1 - 具有带蜗壳离心风机的冰箱 - Google Patents

具有带蜗壳离心风机的冰箱 Download PDF

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Publication number
WO2020173354A1
WO2020173354A1 PCT/CN2020/075881 CN2020075881W WO2020173354A1 WO 2020173354 A1 WO2020173354 A1 WO 2020173354A1 CN 2020075881 W CN2020075881 W CN 2020075881W WO 2020173354 A1 WO2020173354 A1 WO 2020173354A1
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WO
WIPO (PCT)
Prior art keywords
volute
vertical plate
box body
section
air
Prior art date
Application number
PCT/CN2020/075881
Other languages
English (en)
French (fr)
Inventor
王晶
吴淑娟
任树飞
赵发
野田俊典
Original Assignee
青岛海尔电冰箱有限公司
海尔智家股份有限公司
Priority date (The priority date is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the date listed.)
Filing date
Publication date
Application filed by 青岛海尔电冰箱有限公司, 海尔智家股份有限公司 filed Critical 青岛海尔电冰箱有限公司
Priority to US17/434,328 priority Critical patent/US12104842B2/en
Priority to EP20763756.2A priority patent/EP3926264B1/en
Priority to AU2020228085A priority patent/AU2020228085B2/en
Publication of WO2020173354A1 publication Critical patent/WO2020173354A1/zh

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Classifications

    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D17/00Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
    • F25D17/04Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection
    • F25D17/06Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation
    • F25D17/062Arrangements 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
    • F25D17/065Arrangements 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 with compartments at different temperatures
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D11/00Self-contained movable devices, e.g. domestic refrigerators
    • F25D11/02Self-contained movable devices, e.g. domestic refrigerators with cooling compartments at different temperatures
    • F25D11/022Self-contained movable devices, e.g. domestic refrigerators with cooling compartments at different temperatures with two or more evaporators
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D17/00Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
    • F25D17/04Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection
    • F25D17/06Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation
    • F25D17/067Evaporator fan units
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D11/00Self-contained movable devices, e.g. domestic refrigerators
    • F25D11/02Self-contained movable devices, e.g. domestic refrigerators with cooling compartments at different temperatures
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D17/00Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
    • F25D17/04Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection
    • F25D17/06Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation
    • F25D17/062Arrangements 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
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D17/00Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces
    • F25D17/04Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection
    • F25D17/06Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation
    • F25D17/08Arrangements for circulating cooling fluids; Arrangements for circulating gas, e.g. air, within refrigerated spaces for circulating air, e.g. by convection by forced circulation using ducts
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D19/00Arrangement or mounting of refrigeration units with respect to devices or objects to be refrigerated, e.g. infrared detectors
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D21/00Defrosting; Preventing frosting; Removing condensed or defrost water
    • F25D21/04Preventing the formation of frost or condensate
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D23/00General constructional features
    • F25D23/003General constructional features for cooling refrigerating machinery
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D23/00General constructional features
    • F25D23/006General constructional features for mounting refrigerating machinery components
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2317/00Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
    • F25D2317/06Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
    • F25D2317/065Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the air return
    • F25D2317/0651Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the air return through the bottom
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2317/00Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
    • F25D2317/06Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
    • F25D2317/067Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by air ducts
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2317/00Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
    • F25D2317/06Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
    • F25D2317/067Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by air ducts
    • F25D2317/0671Inlet ducts
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2317/00Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
    • F25D2317/06Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
    • F25D2317/068Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the fans
    • F25D2317/0681Details thereof
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2317/00Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass
    • F25D2317/06Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation
    • F25D2317/068Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the fans
    • F25D2317/0683Details or arrangements for circulating cooling fluids; Details or arrangements for circulating gas, e.g. air, within refrigerated spaces, not provided for in other groups of this subclass with forced air circulation characterised by the fans the fans not of the axial type
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2323/00General constructional features not provided for in other groups of this subclass
    • F25D2323/002Details for cooling refrigerating machinery
    • F25D2323/0021Details for cooling refrigerating machinery using air guides
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2323/00General constructional features not provided for in other groups of this subclass
    • F25D2323/002Details for cooling refrigerating machinery
    • F25D2323/0026Details for cooling refrigerating machinery characterised by the incoming air flow
    • F25D2323/00261Details for cooling refrigerating machinery characterised by the incoming air flow through the back bottom side
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2323/00General constructional features not provided for in other groups of this subclass
    • F25D2323/002Details for cooling refrigerating machinery
    • F25D2323/0027Details for cooling refrigerating machinery characterised by the out-flowing air
    • F25D2323/00271Details for cooling refrigerating machinery characterised by the out-flowing air from the back bottom
    • FMECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
    • F25REFRIGERATION OR COOLING; COMBINED HEATING AND REFRIGERATION SYSTEMS; HEAT PUMP SYSTEMS; MANUFACTURE OR STORAGE OF ICE; LIQUEFACTION SOLIDIFICATION OF GASES
    • F25DREFRIGERATORS; COLD ROOMS; ICE-BOXES; COOLING OR FREEZING APPARATUS NOT OTHERWISE PROVIDED FOR
    • F25D2323/00General constructional features not provided for in other groups of this subclass
    • F25D2323/002Details for cooling refrigerating machinery
    • F25D2323/0028Details for cooling refrigerating machinery characterised by the fans
    • F25D2323/00282Details for cooling refrigerating machinery characterised by the fans the fans not of the axial type

Definitions

  • the present invention relates to the technical field of home appliances, in particular to a refrigerator with a centrifugal fan with a volute. Background technique
  • the freezer compartment is generally located at the lower part of the refrigerator, the evaporator is located at the rear side of the freezer compartment, and the compressor compartment is located at the rear of the freezer compartment.
  • the freezer compartment needs to make way for the compressor compartment, which makes the freezer compartment an abnormal shape and restricts the freezer compartment The depth of progress. Summary of the invention
  • an object of the present invention is to provide a refrigerator that overcomes the above problems or at least partially solves the above problems.
  • a further object of the present invention is to realize the modularization of the air supply duct and the centrifugal fan, which is convenient for disassembly and transportation.
  • the present invention provides a refrigerator, including:
  • the box body defines a cooling chamber located below and at least one storage compartment located above the cooling chamber; an evaporator, arranged in the cooling chamber, configured to cool the airflow entering the cooling chamber to form a cooling airflow; centrifugal fan, Comprising a volute and an impeller arranged in the volute, configured to promote a cooling airflow to flow into at least one storage compartment;
  • the air supply duct is detachably connected to the volute, and communicates with the air outlet of the volute, and is configured to deliver the cooling airflow to at least one storage compartment.
  • the centrifugal fan is located behind the evaporator, and the air supply duct is located inside the rear wall of the centrifugal fan;
  • the volute includes:
  • the air supply air duct includes a front cover of the air duct on the front side and a rear cover of the air duct on the rear.
  • the front cover of the air duct is detachably connected with the upper cover
  • the rear cover of the air duct is detachably connected with the lower box body. .
  • the air duct rear cover plate includes a vertically extending rear vertical plate section located at the lower part and a joint section bent and extended forward and downward from the lower end of the rear vertical plate section, and the joint section and the lower end of the air duct front cover plate define The air inlet of the air duct connected with the air outlet of the volute;
  • the rear cover plate of the air duct is detachably connected with the lower box body through the joint section.
  • the joint section includes a horizontal straight section extending forward and backward on the foremost side, a first vertical plate extending downward and vertically is formed at the front end of the horizontal straight section, and the first vertical plate extends from a lateral side of the horizontal straight section to On the other side, the front elevation of the first vertical plate is formed with at least one first buckle protruding forward;
  • the rear end of the bottom wall of the lower box body is formed with a second vertical plate extending vertically downward, and the second vertical plate extends from one lateral side to the other side of the bottom wall of the lower box body;
  • the lower end of the second vertical plate is formed with a first notch corresponding to and adapted to at least one first buckle; the first buckle is snapped into the corresponding first notch and is hooked with the front elevation of the second vertical plate to Assemble the lower box body and the rear cover of the air duct.
  • the rear end of the top wall of the upper cover body is formed with a third vertical plate extending upward, and the third vertical plate extends from one lateral side of the top wall of the upper cover body to the other side;
  • the front cover of the air duct includes a vertically extending front vertical plate section located at the lower part, the horizontal dimension of the front vertical plate section is equal to or greater than the horizontal dimension of the third vertical plate, and the front wall surface of the front vertical plate section is formed with a forward convex At least one second buckle;
  • the upper end of the third vertical plate is formed with at least one second notch corresponding to and adapted to the at least one second buckle; the second buckle is inserted into the corresponding second notch and hooks with the front elevation of the third vertical plate. Hold to assemble the upper cover body and the front cover plate of the air duct.
  • the section defined by the rear vertical plate section and the joint section is recorded as the lower plate section of the air duct rear cover;
  • a sealing part is respectively formed on the inner side of the lateral ends of the lower plate section, and both sealing parts extend forward into the volute to seal the lateral sides of the junction of the air inlet of the air duct and the air outlet of the volute.
  • the side wall of the upper cover body is located inside the side wall of the lower box body, so as to utilize the side wall of the upper cover body and the top wall of the upper cover body and the lower box body
  • the bottom wall of the body defines a volute air duct in the volute.
  • a volute air inlet is formed on the top wall of the upper cover
  • the angle between the axis of rotation of the impeller and the vertical line is 20° to 35°.
  • the horizontal distance between the front end surface of the volute and the rear end surface of the evaporator is 15 mm to 35 mm.
  • the box body includes a refrigerating liner at the bottom, and a cooling chamber is defined in the refrigerating liner;
  • the storage compartment includes a freezing compartment defined by a freezing liner and located above the cooling compartment;
  • the centrifugal fan is configured to cause the cooling air flow to flow into the freezing chamber through the air supply duct.
  • the cooling chamber is located below the box body, so that the cooling chamber occupies the lower space in the box body, and the storage compartment is above the cooling chamber, and the compressor compartment can be defined at the rear and bottom of the cooling chamber, and the storage compartment There is no need to give way to the compressor room to ensure the storage volume of the storage compartment.
  • the air supply duct and the centrifugal fan adopt a split design, which realizes modularization, facilitates disassembly and transportation, and improves product yield.
  • the front cover of the air duct cooperates with the upper cover of the volute to realize the snap-fit assembly of the two
  • the rear cover of the air duct cooperates with the lower box of the volute to realize the clamping between the two.
  • the combined assembly ensures the stability and sealing of the air supply duct and the volute assembly while achieving modularity.
  • Fig. 1 is a front view of a refrigerator according to an embodiment of the present invention
  • Figure 2 is a perspective schematic view of a refrigerator according to an embodiment of the present invention.
  • Fig. 3 is a schematic diagram of a freezing liner of a refrigerator according to an embodiment of the present invention.
  • Figure 4 is a front view of the assembly of the freezing liner, evaporator, centrifugal fan and air supply duct of a refrigerator according to an embodiment of the present invention
  • Fig. 5 is a cross-sectional view along the A-A direction of Fig. 4;
  • FIG. 8 is an exploded schematic diagram of the air supply duct and the centrifugal fan of the refrigerator according to an embodiment of the present invention;
  • FIG. 10 is a schematic diagram of assembly of the lower box and an impeller of the volute of the centrifugal fan of a refrigerator according to an embodiment of the present invention;
  • Figure 11 is a partial exploded schematic view of a refrigerator according to an embodiment of the present invention.
  • Fig. 12 is a partial schematic diagram of a refrigerator according to an embodiment of the present invention. detailed description
  • This embodiment provides a refrigerator 10, and the refrigerator 10 according to the embodiment of the present invention will be described below with reference to FIGS. 1 to 12.
  • the directions or positional relationships indicated by “front”, “rear”, “upper”, “lower”, “left”, “right”, etc. are based on the direction referenced by the refrigerator 10, "front”, “Back” refers to the direction indicated in FIGS. 5, 6, 11, and 12, and as shown in FIGS. 1 and 4, “lateral” refers to a direction parallel to the width direction of the refrigerator 10.
  • the refrigerator 10 may generally include a box body 100.
  • the box body 100 includes a shell 110 and a storage liner arranged inside the shell 110, and a space between the shell 110 and the storage liner It is filled with thermal insulation material (forms a foam layer), and the storage liner defines a storage compartment.
  • the storage liner may generally include a frozen liner 130, a refrigerated liner 120, etc., and the storage compartment includes a freezer The freezing compartment 132 defined in the tank 130 and the refrigerating compartment 121 defined in the refrigerating liner 120.
  • the front side of the storage liner is also provided with a door to open or close the storage compartment. Figures 1 and 2 all conceal the door.
  • the refrigerator 10 of this embodiment may further include an evaporator 101 and an air blower.
  • the air supply fan is a centrifugal fan 103), a compressor 104, a condenser 105, a throttling element (not shown), and so on.
  • the evaporator 101 is connected to the compressor 104, the condenser 105, and the throttling element via a refrigerant pipeline to form a refrigeration cycle.
  • the compressor 104 When the compressor 104 is started, the temperature is lowered to cool the air flowing therethrough.
  • the box body 100 defines a cooling chamber located below, and the upper part of the cooling chamber is a storage compartment.
  • the evaporator 101 is arranged in the cooling chamber to cool the airflow entering the cooling chamber, forming Cooling airflow.
  • the cooling chamber is generally located in the rear space of the box body 100, the freezer compartment 132 is generally located at the bottom of the box body, and the compressor compartment is located behind the freezer compartment 132.
  • the freezer compartment 132 inevitably becomes a compressor compartment
  • the special-shaped space that has been relegated reduces the storage volume of the freezer compartment 132 and also brings about the following problems.
  • the freezer compartment 132 is located in a relatively low position, and the user needs to bend over or squat down to pick and place items in the freezer compartment 132, which is inconvenient for the user to use, especially for the elderly; The depth of the compartment 132 is reduced.
  • the freezer compartment 132 To ensure the storage volume of the freezer compartment 132, it is necessary to increase the space in the height direction of the freezer compartment 132.
  • the user When storing items in the freezer compartment 132, the user needs to stack the items in the height direction, which is not convenient for the user to find items.
  • the items located at the bottom of the freezer compartment 132 are easily blocked, making it difficult for users to find and forget, resulting in deterioration and waste of items.
  • the freezer compartment 132 is a special shape, it is not a rectangular space, which is relatively large and difficult for some users. The divided items are inconvenient to be placed in the freezer compartment 132.
  • the cooling chamber is located below the box body 100, so that the cooling chamber occupies the lower space in the box body 100, and the storage compartment is above the cooling chamber, and the rear and lower part of the cooling chamber can define a compressor room for storage.
  • the storage room does not need to make way for the compressor room to ensure the storage volume of the storage room.
  • the cooling chamber may be defined by a freezer liner 130, which is generally located under the box 100 Part, the freezer inner container 130 defines a cooling chamber and a freezer 132 located above the cooling chamber.
  • the freezer compartment 132 is raised, the degree of bending of the user during the operation of picking and placing items in the freezer compartment 132 is reduced, and the user experience is improved.
  • the freezer compartment 132 does not need to give way to the compressor cabin, so that the freezer compartment 132 is a rectangular space, so that the items can be changed from stacked storage to flat unfolded storage, which is convenient for users to find items and saves users time and energy; At the same time, it is also convenient to place large objects that are not easily divided, and solves the pain point of not being able to place large objects in the freezer compartment 132.
  • the refrigerator 10 further includes another storage liner located above the freezing liner 130, and the storage liner may be a variable temperature liner 131 or a refrigerating liner 120.
  • the temperature-variable inner liner 131 is located above the freezing inner liner 130
  • the refrigerating liner 120 is located above the temperature-variable inner liner 131.
  • the temperature-variable inner tank 131 defines a temperature-variable greenhouse 1311, as shown in Figs. 1 and 2, there are two temperature-variable inner tanks 131, two temperature-variable inner tanks 131 are distributed horizontally, and each temperature-variable inner tank 131 defines one temperature-variable greenhouse 1311.
  • the temperature in the refrigerator compartment 121 is generally between 2 ° C and 10 ° C, preferably between 4 ° C and 7 ° C.
  • the temperature range in the freezer compartment 132 is generally -22 ° C to -14 ° C.
  • the greenhouse 1311 can be adjusted to -18 ° C to 8°C at will.
  • the optimal storage temperature for different types of items is different, and the suitable storage locations are also different. For example, fruit and vegetable foods are suitable for storage in the refrigerating compartment 121, and meat foods are suitable for storage in the freezing compartment 132.
  • a refrigerating air duct may be defined in the refrigerating liner 120, and a refrigerating evaporator (not shown) and a refrigerating fan (not shown) are provided in the refrigerating air duct to independently supply air to the refrigerating chamber 121.
  • the cooling airflow is delivered to at least one storage room above the cooling room through the air supply duct 141.
  • the cooling air flow is delivered to the freezing compartment 132 through the air supply duct 141.
  • the air supply duct 141 is located inside the rear wall of the freezer liner 130, and the air supply duct 141 is formed with a freezer compartment air inlet 141a communicating with the freezer compartment 132 to convey at least part of the cooling air flow to the freezer compartment 132 within.
  • the rear wall of the refrigerating liner 130 is formed with a recess that is recessed backward to match the air duct 141, and the air duct 141 is embedded in the recess.
  • each variable temperature liner 131 may be provided with a variable greenhouse air duct (not shown), and the rear wall of the variable temperature liner 131 is formed with a variable greenhouse air inlet 131a connected to the air outlet of the variable greenhouse air duct.
  • the greenhouse air duct is configured to be controllably connected with the air supply air duct 141 so as to convey part of the cooling air flow of the air supply air duct 141 to the variable temperature greenhouse 1311.
  • At least one first top opening 141g is formed at the top of the air supply duct 141, and the first top opening 141g corresponds to the air inlet of the variable greenhouse air duct one-to-one.
  • the top wall of the freezing liner 130 is formed with at least One first top opening 141g—corresponding to at least one second top opening 130d, so as to communicate the first top opening 141g with the air inlet of the greenhouse air duct through the second top opening 130d.
  • a damper may be provided at the first top opening 141g of the air supply duct 141 to controlly open or close the first top opening 141g.
  • there are two variable-temperature inner tanks 131 there are two variable-temperature inner tanks 131, and correspondingly, there are two variable-temperature greenhouse air ducts, and both the first top opening 141g and the second top opening 130d are two.
  • the regions corresponding to the two lateral side walls of the freezing liner 130 and the cooling chamber respectively protrude in the direction of the cooling chamber to respectively form a second limiting boss 130b .
  • the refrigerator 10 further includes a cover plate, the cover plate constitutes the top wall and the front wall of the cooling chamber, and is located on the corresponding second limit boss 130b with the two second limit bosses 130b and the side walls of the two freezer liners 130
  • the front section, the bottom wall of the freezing liner 130 and the back wall of the freezing liner 130 jointly define a cooling chamber.
  • the evaporator 101 can be placed horizontally in the cooling chamber in a flat cube shape, that is, the long and wide surfaces of the evaporator 101 are parallel to the horizontal plane, the thickness surface is perpendicular to the horizontal plane, and the thickness dimension is significantly smaller than the length dimension of the evaporator 101.
  • the cover plate includes a top cover 1021 and at least one front cover group 102, the top cover 1021 is located above the evaporator 101, and at least one front return air inlet is formed on the front side of each front cover group 102 to make freezing
  • the return air flow of the chamber 132 enters the cooling chamber through the at least one front return air inlet and is cooled by the evaporator 101, thereby forming an air flow circulation between the cooling chamber and the freezing chamber 132.
  • each front cover group 102 there are two front cover groups 102, the two front cover groups 102 are distributed along the lateral direction, and the front side of each front cover group 102 is formed with two front return air inlets, which are respectively The first front return air inlet 102a and the second front return air inlet 102b.
  • a side return air inlet (not shown) is formed on the side wall of the refrigerating inner liner 130, and the side return air inlet is connected to the variable temperature inner liner 131 through the side return air passage (not shown), so as to use the side return air passage to change the greenhouse 1311
  • the return air flow from the temperature is conveyed to the cooling chamber for cooling, thereby forming an air circulation between the variable temperature chamber 1311 and the cooling chamber.
  • the side return air inlet is formed in a section of the side wall of the freezing liner 130 in front of the corresponding second limiting boss 130b, so that the side return air inlet is further forward, so that the return air flow of the warming room 1311 is removed from
  • the evaporator 101 flows from the front to the back to extend the heat exchange path between the return air flow of the warming room 1311 and the evaporator 101, and to improve the heat exchange efficiency.
  • the rear section of the bottom wall of the freezing liner 130 is formed with at least one first limiting boss 130a protruding upward, and each first limiting boss 130a forms a limiting groove 130al ; the lower part of the air supply duct 141
  • the segment is formed with a matching portion 141f that cooperates with the limiting groove 130a1, and the matching portion 141f cooperates with the limiting groove 130a1 to prevent the air supply duct 141 from moving downward.
  • first limiting bosses 130a there are two first limiting bosses 130a, and the two first limiting bosses 130a are spaced apart in the lateral direction.
  • mating parts 141f there are two mating parts 141f, and the two mating parts 141f are in the lateral direction. Interval distribution.
  • the lower section of the air duct 141 located in the freezing liner 130 is inevitably connected to the freezing liner 130.
  • a gap is formed between the bottom walls of 130.
  • the refrigerator 10 When the refrigerator 10 is transported, it is easy to cause the air supply duct 141 to fall when it is impacted, so that the first top opening 141g at the top of the air supply duct 141 and the second top opening 130d corresponding to the top wall of the freezing liner 130 There is a gap between.
  • the airflow in the temperature-changing room 1311 enters the freezer compartment 132 through the gap, and since the temperature of the airflow in the temperature-changing room 1311 is generally higher than that of the freezer compartment 132, the air flow near the top of the air duct 141 is formed. Frost affects the temperature of the freezing compartment 132 and the cooling air flow.
  • a third limiting boss 130c protruding upward is formed on both lateral sides of the bottom wall of the freezing liner 130 near the rear end.
  • the two third limiting bosses 130c and the bottom wall of the freezing liner 130 are located
  • the section behind the fan 101 defines a space where the centrifugal fan 103 is arranged.
  • Each third limiting boss 130c may be formed with a first mounting hole (not labeled).
  • the volute of the centrifugal fan 103 is formed with second mounting holes 103cl corresponding to the two first mounting holes one-to-one, so that the centrifugal fan can be centrifuged by a mounting member (for example, a screw) passing through the second mounting hole 103cl and the first mounting hole in sequence
  • the volute of the fan 103 is installed on the bottom wall of the freezing liner 130.
  • FIG. 8 FIG. 10
  • lateral sides of the side walls of the lower case 1032 are respectively formed with a mounting plate 103c
  • 103c is formed with a second mounting plate mounted to the first mounting hole corresponding to the hole corresponding 103cl o
  • centrifugal fan 103 The following is a detailed description of the centrifugal fan 103 and the air supply duct 141:
  • the centrifugal fan 103 is located behind the evaporator 101, and includes a volute and an impeller 1031 arranged in the volute.
  • the air duct 141 is detachably connected to the volute, and the air inlet of the air supply air duct is connected with the air outlet of the volute, so that the airflow in the volute enters the air duct 141.
  • the air duct and the volute of the fan are mostly integrated, which is inconvenient to transport and cannot be modularized.
  • the air supply duct 141 and the volute of the centrifugal fan 103 adopt a split design. , Realize modularization, facilitate disassembly and transportation, and improve product yield.
  • the volute includes a lower box body 1032 and an upper cover body 1033 arranged on the lower box body 1032.
  • the lower box body 1032 and the upper cover body 1033 can be buckled and connected to facilitate the disassembly and assembly of the volute.
  • the rear end and the lower part of the upper cover body 1033 are both open, that is, the upper cover body 1033 includes a top wall 103a and a first side wall 103d extending downward from the top wall 103a; correspondingly, the rear end of the lower box body 1032
  • the upper part and the upper part are both open, and the lower box body 1032 includes a bottom wall 103b and a second side wall extending upward from the bottom wall 103b.
  • the top wall 103a of the upper cover body 1033 is formed with a volute air inlet 1033a, and the rear end of the upper cover body 1033 and the rear end of the lower box body 1032 define the volute air outlet.
  • the first side wall 103d of the upper cover body 1033 is located inside the second side wall of the lower box body 1032, that is, the first side wall of the upper cover body 1033 103d, the top wall 103a of the upper cover body 1033 and the bottom wall 103b of the lower box body 1032 define the air supply duct in the volute.
  • the first side wall 103d of the upper cover 1033 has a volute line and is configured as a volute air duct to better guide the airflow to the volute air outlet and reduce noise.
  • a volute groove 103a3 is formed on the inner surface of the top wall 103a of the upper cover body 1033, and the volute groove 103a3 cooperates with the first side wall 103d of the upper cover body 1033 to better guide the air flow.
  • the inner surface of the seventh straight section inclined top wall 103a of the cover member 1033 is formed with a worm-shaped groove 103a3 103a3 o cochlear grooves formed in the volute inlet 1033a, a worm wheel 1031 disposed in the lower box-shaped groove 103a3 Body 1032 within the area defined.
  • the angle 0 between the axis of the rotating shaft of the impeller 1031 and the vertical line can be 20° to 35°, for example, 0 is 20°, 25°, 33. , 35. Wait.
  • the horizontal distance a between the front end surface of the volute of the centrifugal fan 103 and the rear end surface of the evaporator 101 can be 15 mm to 35 mm, for example, a is 15 mm, 20 mm, 25 mm, 30 mm, 35 mm.
  • the distance between the fan 103 and the evaporator 101 is too small, causing the centrifugal fan 103 to frost.
  • the bottom wall 103b of the lower box body 1032 may be formed with at least one drainage hole 103b3. As shown in FIG. 10, there are two drainage holes 103b3 to facilitate the drainage of the condensed water that may be formed.
  • the air supply duct 141 is located behind the centrifugal fan 103 and includes a front air duct cover 1411 on the front side and a rear air duct cover 1412 on the rear side.
  • the air duct front cover 1411 and the air duct rear cover 1412 can be buckled together assembly.
  • the air duct front cover 1411 and the upper cover body 1033 are detachably connected, and the air duct rear cover plate 1412 and the lower box body 1032 are detachably connected, so that the air outlet of the volute is connected to the air inlet of the air duct 141.
  • the air duct rear cover 1412 may include a vertically extending rear vertical plate section 1412e located at the lower part and a joint section extending forward and downward from the lower end of the rear vertical plate section 1412e, and the joint section is located in the air duct. Below the front cover plate 1411, the front end of the joint section and the lower end of the air duct front cover plate 1411 define the air duct air inlet.
  • the air duct rear cover 1412 is detachably connected to the lower box body 1032 through a joint section, and the aforementioned matching portion 141f is formed on the joint section.
  • the air duct rear cover 1412 is designed to have a joint section bent forward and downward from the lower end of the rear vertical plate section 1412e to facilitate connection with the volute of the front centrifugal fan 103 and promote airflow in the volute Gently enter the air supply duct 141 to reduce noise.
  • the joint section forms a matching portion 141f that matches with the limiting groove 130al on the bottom wall of the freezing liner 130, so that the air duct rear cover 1412 can actively cooperate with the volute of the freezing liner 130 and the centrifugal fan 103, and the overall layout More compact and reasonable. As shown in FIG.
  • the joint section of the air duct rear cover plate 1412 includes a transitional curved section 1412a curved and extended forward and downward from the rear vertical plate section 1412e, and a first inclined straight section 1412b extending obliquely forward and downward from the transition curved section 1412a. And a horizontal straight section 1412c extending forward and backward from the first inclined straight section 1412b.
  • the front end of the horizontal straight section 1412c is formed with a first vertical plate 1412d extending downward and vertically.
  • the first vertical plate 1412d extends from one lateral side to the other side of the horizontal straight section 1412c, and the front elevation of the first vertical plate 1412d is formed there are at least a forwardly projecting first locking 141c, the first riser façade 1412d may be formed at the rear end of the bottom wall 103b has a rearwardly projecting mating portion 141f o the cartridge body 1032 formed
  • the second vertical plate 103bl extends vertically downward.
  • the second vertical plate 103bl extends from one lateral side of the bottom wall 103b of the lower box body 1032 to the other side, and the lower end of the second vertical plate 103bl is formed with at least one first Buckle 141c—corresponding and adapted to the first notch 103bl l, the first buckle 141c is snapped into the corresponding first notch 103bl l and hooked with the front elevation of the second vertical plate 103bl to buckle the lower box body 1032 Close to the rear cover 1412 of the air duct.
  • first buckles 141c There are two first buckles 141c, and the three first buckles 141c are laterally spaced apart. Correspondingly, there are three first notches 103b1, and the three first notches 103b1 are distributed horizontally apart.
  • the air duct front cover 1411 includes a vertically extending front vertical plate section 1411a at the lower part, and at least one second buckle 141b protruding forward is formed on the front wall of the front vertical plate section 1411a.
  • the rear end of the top wall 103a of the upper cover 1033 is formed with a third vertical plate 103al extending upward, and the third vertical plate 103al extends from one lateral side to the other side of the top wall 103a of the upper cover 1033.
  • the upper end of 103al is formed with at least one second notch 103al l corresponding to and adapted to at least one second buckle 141b -, and the second buckle 141b is locked into the corresponding second notch 103al l and is connected to the front of the third vertical plate 103al
  • the elevation is hooked to buckle the upper cover 1033 on the front cover 1411 of the air duct.
  • the horizontal dimension of the front vertical plate section 1411a should be equal to or greater than the horizontal dimension of the third vertical plate 103al. As shown in FIG. 8, the horizontal dimension of the front vertical plate section 1411a is approximately the same as the horizontal dimension of the third vertical plate 103al, so that the upper the cover 1033 and the air passage front plate 1411 snap engaged, the front vertical plate section 1411a timeliness can be completely blocked after the third riser 103al o cover member 1033 and the air passage front plate 1411 buckle, the front section 1411a of the vertical plate
  • the vertical surface is close to the front vertical surface of the third vertical plate 103al, and there is a small gap between the two. Sponge strips can be inserted into the gap to avoid air leakage.
  • the rear wall of the front vertical plate section 1411a may be formed with a plurality of reinforcing ribs 141e protruding rearward to enhance the strength of the front vertical plate section 1411a.
  • the front elevation of the third vertical plate 103al is formed with a plurality of reinforcing ribs 103a2 distributed along the lateral interval, and the third vertical plate 103al is also formed with a mounting portion 141h protruding above the third vertical plate 103al, for example, the mounting portion 141h is formed At the transverse middle position of the third vertical plate 103al, the mounting portion 141h is formed with a first screw hole, and the area corresponding to the mounting portion 141h of the front vertical plate section 1411a is formed with a second screw hole corresponding to the first screw hole for use
  • the upper cover body 1033 and the air duct front cover plate 1411 are assembled by the screws passing through the first screw hole and the second screw hole.
  • a sealing portion 141d extending forward is respectively formed on both lateral sides of the air duct rear cover 1412,
  • the section defined by the rear vertical plate section 1412e of the air duct rear cover plate 1412 and the joint section is recorded as wind
  • a sealing portion 141d extending forward is formed on the inner lateral ends of the lower plate section, and each sealing portion 141d extends into the volute of the centrifugal fan 103 for sealing and sending
  • the transverse sides of the junction of the air duct 141 and the volute of the centrifugal fan 103 are used to seal the junction of the air duct rear cover 1412 and the lower box body 1032 when they are buckled, and for sealing
  • a compressor compartment is defined at the bottom of the box body 100, and the compressor compartment is located behind the cooling chamber.
  • the freezer compartment 132 does not need to make way for the compressor compartment, which ensures the depth of the freezer compartment 132 and is convenient Place large items that are difficult to divide.
  • the refrigerator 10 further includes a heat dissipation fan 106.
  • the heat dissipation fan 106 may be an axial flow fan.
  • the compressor 104, the heat dissipation fan 106, and the condenser 105 are arranged in the compressor cabin at intervals along the transverse direction.
  • the section 1162 of the rear wall of the compressor cabin corresponding to the compressor 104 is formed with at least one rear air outlet 1162a.
  • the applicant of the present invention creatively realized that the heat exchange area of the condenser 105 and the ventilation area of the compressor cabin are not as large as possible.
  • the conventional design scheme of increasing the heat exchange area of the condenser 105 and the ventilation area of the compressor cabin it will bring The problem of uneven heat dissipation of the condenser 105 has an adverse effect on the refrigeration system of the refrigerator 10.
  • the applicant of the present invention jumped out of the conventional design ideas and creatively proposed a new solution different from the conventional design.
  • the bottom wall of the box defines a horizontally arranged adjacent condenser 105
  • the bottom air inlet 110a and the bottom air outlet 110b adjacent to the compressor 104 complete the circulation of the heat dissipation airflow at the bottom of the refrigerator 10, making full use of the space between the refrigerator 10 and the supporting surface, without increasing the rear wall of the refrigerator 10
  • the distance to the cabinet reduces the space occupied by the refrigerator 10 while ensuring good heat dissipation in the compressor cabin, which fundamentally solves the pain point of the inability to balance the heat dissipation of the compressor cabin and the space occupation of the embedded refrigerator 10. This is particularly important Meaning.
  • the heat dissipation fan 106 is configured to cause the ambient air around the bottom air inlet 110a to enter the compressor cabin from the bottom air inlet 110a, pass through the condenser 105, the compressor 104, and then flow from the bottom air outlet 110b to the external environment, so as to prevent the compressor 104 and condenser 105 dissipate heat.
  • the surface temperature of the condenser 105 is generally lower than the surface temperature of the compressor 104. Therefore, in the above process, the outside air is used to cool the condenser 105 and then the compressor 104.
  • the plate section 1161 of the back plate 116 facing the condenser 105 is a continuous plate surface, that is, the plate of the back plate 116 facing the condenser 105 There are no heat dissipation holes on section 1161.
  • the applicant of the present invention creatively realized that even without increasing the heat exchange area of the condenser 105, reducing the ventilation area of the compressor cabin in an abnormal state can form a better heat dissipation airflow path, and still achieve better heat dissipation. effect.
  • the applicant broke through the conventional design ideas and combined the back wall (back plate 116) of the compressor cabin with the condensation
  • the plate section 1161 corresponding to the condenser 105 is designed as a continuous plate surface, which seals the heat dissipation airflow entering the compressor cabin at the condenser 105, so that the ambient air entering from the bottom air inlet 110a is more concentrated at the condenser 105, ensuring
  • the heat exchange uniformity of each condensation section of the condenser 105 is beneficial to form a better heat dissipation airflow path, and also can achieve a better heat dissipation effect.
  • the plate section 1161 of the back plate 116 facing the condenser 105 is a continuous plate surface and does not have air inlet holes, it is avoided that the air outlet and inlet air in the conventional design are concentrated at the rear of the compressor room and cause the blow out from the compressor room.
  • the hot air enters the compressor cabin again without being cooled by the ambient air in time, which adversely affects the heat exchange of the condenser 105, thereby ensuring the heat exchange efficiency of the condenser 105.
  • both lateral side walls of the compressor compartment are formed with a side vent hole 119a
  • the side vent hole 119a may be covered with a vent cover 108
  • the vent cover 108 is formed with grille-type ventilation holes; refrigerator 10
  • the outer shell includes two lateral box side plates 111, the two box side plates 111 extend vertically to form two side walls of the refrigerator 10, and the two box side plates 111 respectively form a corresponding side vent hole 119a communicates with the side opening 111a, so that the heat dissipation airflow flows to the outside of the refrigerator 10. Therefore, the heat dissipation path is further increased to ensure the heat dissipation effect of the compressor cabin.
  • the condenser 105 includes a horizontally extending first straight section 1051, a second straight section 1052 extending back and forth, and a transition curve (not numbered) connecting the first straight section 1051 and the second straight section 1052, thereby An L-shaped condenser 105 with an appropriate heat exchange area is formed.
  • the plate section 1161 of the back wall (back plate 116) of the aforementioned compressor cabin corresponding to the condenser 105 is also the plate section 1161 of the back plate 116 facing the first straight section 1051.
  • the ambient air entering from the side vent 119a directly exchanges heat with the second straight section 1052, and the ambient air entering from the bottom air inlet 110a directly exchanges heat with the first straight section 1051, thereby further entering the environment in the compressor cabin More air is concentrated at the condenser 105 to ensure the uniformity of heat dissipation of the entire condenser 105.
  • the casing of the box body 100 includes a bottom plate, a supporting plate 112, two side plates 119 and a vertically extending back plate 116.
  • the supporting plate 112 constitutes the bottom wall of the compressor cabin and is used to carry the compressor 104 and the heat dissipation fan.
  • 106 and the condenser 105, the two side plates respectively constitute the two lateral side walls of the compressor cabin, and the vertically extending back plate 116 constitutes the rear wall of the compressor cabin.
  • the bottom plate includes a bottom horizontal section 113 located at the front side of the bottom and a bending section bent and extended from the rear end of the bottom horizontal section 113 backward and upward, and the bending section extends above the pallet 112,
  • the compressor 104, the radiating fan 106 and the condenser 105 are arranged on the supporting plate 112 at intervals along the transverse direction, and are located in the space defined by the supporting plate 112, the two side plates, the back plate 116 and the bending section.
  • the supporting plate 112 and the bottom horizontal section 113 together constitute the bottom wall of the box body 100, and the supporting plate 112 and the bottom horizontal section 113 are spaced apart, so that the rear end of the bottom horizontal section 113 and the front end of the supporting plate 112 define the bottom wall.
  • the two side plates extend upward from the lateral sides of the pallet 112 to the lateral sides of the bending section respectively to close the lateral sides of the press cabin; the back plate 116 extends upward from the rear end of the pallet 112 To the rear end of the bending section.
  • the bending section may include a vertical section 1131, the aforementioned inclined section 114, and a top horizontal section 115.
  • the vertical section 1131 extends upward from the rear end of the bottom horizontal section 113, and the inclined section 114 is formed by The upper end of the vertical section 1131 extends backward and upward to above the pallet 112, and the top horizontal section 115 extends from the rear end of the inclined section 114 to the back plate to cover the compressor 104, the heat dissipation fan 106 and the condenser 105 above.
  • the box 100 further includes a partition 117, which is arranged behind the bending section, the front part of which is connected to the rear end of the bottom horizontal section 113, and the rear part thereof is connected to the front end of the pallet 112, and is arranged to connect the bottom
  • the opening is divided into a bottom air inlet 110a and a bottom air outlet 110b arranged horizontally.
  • the bottom air inlet 110a and the bottom air outlet 110b of this embodiment are defined by the partition 117, the supporting plate 112, and the bottom horizontal section 113, thereby forming a groove-shaped bottom air inlet with a larger opening size 110a and the bottom air outlet 110b increase the air inlet and outlet areas, reduce the air inlet resistance, and make the air flow smoother, and the manufacturing process is simpler, so that the overall stability of the compressor cabin is stronger.
  • the slope structure of the inclined section 114 can guide and rectify the airflow of the inlet air, so that the airflow entering from the bottom air inlet 110a flows to the condenser 105 more concentratedly, avoiding the excessive dispersion of the airflow
  • the condenser 105 cannot pass more, thereby further ensuring the heat dissipation effect of the condenser 105;
  • the slope of the inclined section 114 guides the airflow from the bottom air outlet 110b to the front side of the ground air outlet, so that the The air flow flows out of the compressor cabin more smoothly, thereby further improving the smoothness of air flow.
  • the angle between the inclined section 114 and the horizontal plane is less than 45°.
  • the inclined section 114 has a better guiding and rectifying effect on the airflow.
  • the inventor of the present application creatively realized that the slope of the inclined section 114 has a better suppression effect on airflow noise.
  • the compressor cabin with the aforementioned specially designed inclined section 114 The noise can be reduced by more than 0.65 decibels.
  • the bottom of the box body 100 generally has a carrying plate with a substantially flat structure, and the compressor
  • the vibration generated during operation of the compressor 104 has a greater impact on the bottom of the box 100.
  • the bottom of the box body 100 is constructed as a three-dimensional structure with a special structure of the bottom plate and the supporting plate 112, which provides an independent three-dimensional space for the arrangement of the compressor 104, and the supporting plate 112 is used to carry the compressor 104. , To reduce the impact of the vibration of the compressor 104 on other components at the bottom of the box 100.
  • the bottom of the refrigerator 10 has a compact structure and a reasonable layout, which reduces the overall volume of the refrigerator 10, and at the same time makes full use of the space at the bottom of the refrigerator 10 to ensure the compressor 104 And the heat dissipation efficiency of the condenser 105.
  • the upper end of the condenser 105 is provided with a windshield 1056, and the windshield 1056 may be a windshield sponge, which fills the space between the upper end of the condenser 105 and the bending section, that is, the windshield 1056 covers the upper end of the first straight section 1051, the second straight section 1052 and the transitional curved section, and the upper end of the windshield 1056 should abut the bending section to seal the upper end of the condenser 105 so as not to enter the compressor room
  • the air passes through the space between the upper end of the condenser 105 and the bending section without passing through the condenser 105, so that the air entering the compressor cabin passes through the condenser 105 for heat exchange as much as possible, and further improves the heat dissipation of the condenser 105 effect.
  • the refrigerator 10 also includes a windshield 107 extending forwards and backwards.
  • the windshield 107 is located between the bottom air inlet and the bottom air outlet, and extends from the lower surface of the bottom horizontal section 113 to the lower surface of the support plate 112, and is connected to the lower end of the partition.
  • the refrigerator when using the weather strip 107 to the partition member and the bottom end of the air inlet and outlet are completely isolated, so that the refrigerator is placed in a support surface 10, transverse partition wall and the space between the bottom surface of the support housing 100 to allow
  • the outside air enters the compressor cabin through the bottom air inlet on the lateral side of the windshield 107 under the action of the heat dissipation fan 106, and flows through the condenser 105, the compressor 104 in turn, and finally from the other side of the windshield 107.
  • the bottom air outlet of the air outlet flows out, thereby completely isolating the bottom air inlet and the bottom air outlet, ensuring that the outside air entering the condenser 105 and the heat dissipating air discharged from the compressor 104 will not flow together, and further ensuring the heat dissipation efficiency.

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Abstract

一种具有带蜗壳离心风机的冰箱,包括箱体、蒸发器、离心风机和送风风道,箱体其内限定有位于下方的冷却室和位于冷却室上方的至少一个储物间室,蒸发器设置于冷却室内,配置为冷却进入冷却室内的气流,以形成冷却气流,离心风机包括蜗壳和设置于蜗壳内的叶轮,送风风道与蜗壳可拆卸连接,并与蜗壳出风口连通,设置为将冷却气流输送至至少一个储物间室内。本发明的冰箱,冷却室处于箱体的下方,使得冷却室占用箱体内的下部空间,而储物间室处于冷却室的上方,可在冷却室的后方限定出压机舱,储物间室无需再为压机舱让位,保证储物间室的存储容积。另外,送风风道与离心风机采用分体式设计,实现模块化,方便拆装和运输,提高良品率。

Description

具有带蜗壳离心风机的冰箱
技术领域
本发明涉及家电技术领域, 特别是涉及一种具有带蜗壳离心风机的冰箱。 背景技术
现有冰箱中, 冷冻室一般位于冰箱下部, 蒸发器位于冷冻室外侧的后部, 压机舱位 于冷冻室的后部, 冷冻室需要为压机舱让位, 使得冷冻室存在异形, 限制了冷冻室的进 深。 发明内容
鉴于上述问题, 本发明的一个目的是要提供一种克服上述问题或者至少部分地解决 上述问题的冰箱。
本发明一个进一步的目的是实现送风风道与离心风机的模块化, 便于拆装和运输。 本发明提供了一种冰箱, 包括:
箱体, 其内限定有位于下方的冷却室和位于冷却室上方的至少一个储物间室; 蒸发器, 设置于冷却室内, 配置为冷却进入冷却室内的气流, 以形成冷却气流; 离心风机, 包括蜗壳和设置于蜗壳内的叶轮, 配置为促使冷却气流向至少一个储物 间室内流动;
送风风道, 与蜗壳可拆卸连接, 并与蜗壳出风口连通, 设置为将冷却气流输送至至 少一个储物间室内。
可选地, 离心风机位于蒸发器的后方, 送风风道位于离心风机的后方壁内侧; 蜗壳包括:
上部和后端均敞开的下盒体和扣合在下盒体上的下部和后端均敞开的上盖体, 上盖 体的后端与下盒体的后端限定出蜗壳出风口;
送风风道包括位于前侧的风道前盖板和位于后侧的风道后盖板, 风道前盖板与上盖 体可拆卸连接, 风道后盖板与下盒体可拆卸连接。
可选地, 风道后盖板包括位于下部的竖向延伸的后竖板段和由后竖板段的下端向前 下方弯折延伸的接合段, 接合段与风道前盖板的下端限定出与蜗壳出风口连通的风道进 风口;
风道后盖板通过接合段与下盒体可拆卸连接。
可选地, 接合段包括位于最前侧的前后延伸的水平直段, 水平直段的前端形成有向 下竖向延伸的第一立板, 第一立板由水平直段的横向一侧延伸至另一侧, 第一立板的前 立面形成有向前凸出的至少一个第一卡扣;
下盒体的底壁的后端形成有向下竖向延伸的第二立板, 第二立板由下盒体的底壁的 横向一侧延伸至另一侧;
第二立板的下端形成有与至少一个第一卡扣 -对应并适配的第一缺口; 第一卡扣卡入对应的第一缺口并与第二立板的前立面勾持, 以将下盒体与风道后盖 板装配。 可选地, 上盖体的顶壁的后端形成有向上延伸的第三立板, 第三立板由上盖体的顶 壁的横向一侧延伸至另一侧;
风道前盖板包括位于下部的竖向延伸的前竖板段, 前竖板段的横向尺寸等于或大于 第三立板的横向尺寸, 前竖板段的前壁面形成有向前凸出的至少一个第二卡扣;
第三立板的上端形成有与至少一个第二卡扣一一对应并适配的至少一个第二缺口; 第二卡扣卡入对应的第二缺口并与第三立板的前立面勾持, 以将上盖体与风道前盖 板装配。
可选地, 后竖板段和接合段限定的区段记为风道后盖板的下板段;
下板段的横向两端内侧分别形成有一个密封部, 两个密封部均向前延伸至蜗壳内, 以密封风道进风口和蜗壳出风口的交接处的横向两侧。
可选地, 上盖体与下盒体扣合连接时, 上盖体的侧壁位于下盒体的侧壁的内侧, 以 利用上盖体的侧壁与上盖体的顶壁以及下盒体的底壁限定出蜗壳内的蜗壳风道。
可选地, 上盖体的顶壁形成有蜗壳进风口;
叶轮的旋转轴线与竖直线的夹角为 20° 至 35 ° 。
可选地, 蜗壳的前端面与蒸发器的后端面之间的水平距离为 15毫米至 35毫米。 可选地, 箱体包括位于最下方的冷冻内胆, 冷冻内胆内限定有冷却室;
储物间室包括由冷冻内胆限定且位于冷却室上方的冷冻室;
离心风机配置为促使冷却气流经送风风道流动至冷冻室内。
本发明的冰箱, 冷却室处于箱体的下方, 使得冷却室占用箱体内的下部空间, 而储 物间室处于冷却室的上方, 可在冷却室的后下方限定出压机舱, 储物间室无需再为压机 舱让位, 保证储物间室的存储容积。 另外, 送风风道与离心风机采用分体式设计, 实现 模块化, 方便拆装和运输, 提 良品率。
进一步地, 本发明的冰箱中, 风道前盖板与蜗壳的上盖体配合, 实现两者的卡合装 配, 风道后盖板与蜗壳的下盒体配合, 实现两者的卡合装配, 实现模块化的同时, 保证 了送风风道与蜗壳装配的稳固性和密封性。
根据下文结合附图对本发明具体实施例的详细描述, 本领域技术人员将会更加明了 本发明的上述以及其他目的、 优点和特征。 附图说明
后文将参照附图以示例性而非限制性的方式详细描述本发明的一些具体实施例。 附 图中相同的附图标记标示了相同或类似的部件或部分。 本领域技术人员应该理解, 这些 附图未必是按比例绘制的。 附图中:
图 1是根据本发明一个实施例的冰箱的前视图;
图 2是根据本发明一个实施例的冰箱的立体示意图;
图 3是根据本发明一个实施例的冰箱的冷冻内胆的示意图;
图 4是根据本发明一个实施例的冰箱的冷冻内胆、 蒸发器、 离心风机及送风风道装 配的前视图;
图 5是图 4的 A-A方向的剖面图;
图 6是图 5中区域 A的放大图; 图 7是根据本发明一个实施例的冰箱的送风风道和离心风机装配的示意图; 图 8是根据本发明一个实施例的冰箱的送风风道和离心风机的分解示意图; 图 9是根据本发明一个实施例的冰箱的离心风机的蜗壳的上盖体的示意图; 图 10是根据本发明一个实施例的冰箱的离心风机的蜗壳的下盒体和叶轮装配的示意 图;
图 11是根据本发明一个实施例的冰箱的局部分解示意图; 以及
图 12是根据本发明一个实施例的冰箱的局部示意图。 具体实施方式
本实施例提供了一种冰箱 10,下面参照图 1至图 12来描述本发明实施例的冰箱 10。 在下文描述中, “前” 、 “后” 、 “上” 、 “下” 、 “左” 、 “右” 、 等指示的方位或 位置关系为基于冰箱 10本身为参考的方位, “前” 、 “后”为如图 5、 图 6、 图 11和图 12所指示的方向, 如图 1和图 4所示, “横向”是指与冰箱 10宽度方向平行的方向。
如图 1和图 2所示, 冰箱 10—般性地可包括箱体 100, 箱体 100包括外壳 110和设 置在外壳 110内侧的储物内胆, 外壳 110与储物内胆之间的空间中填充有保温材料 (形 成发泡层), 储物内胆中限定有储物间室, 储物内胆一般可包括冷冻内胆 130、冷藏内胆 120等,储物间室包括由冷冻内胆 130内限定的冷冻室 132和由冷藏内胆 120内限定的冷 藏室 121。 储物内胆的前侧还设置有门体, 以打开或关闭储物间室, 图 1、 图 2均隐去了 门体。
如本领域技术人员可意识到的, 本实施例的冰箱 10还可包括蒸发器 101、 送风风机
(本实施例中, 送风风机为离心风机 103) 、 压缩机 104、 冷凝器 105以及节流元件 (未 示出)等。 蒸发器 101经由制冷剂管路与压缩机 104、 冷凝器 105、 节流元件连接, 构成 制冷循环回路, 在压缩机 104启动时降温, 以对流经其的空气进行冷却。
特别地, 本实施例中, 箱体 100内限定有位于下方的冷却室, 而冷却室的上方为储 物间室, 蒸发器 101设置于冷却室中, 以冷却进入冷却室中的气流, 形成冷却气流。
传统冰箱 10中, 冷却室一般处于箱体 100的后部空间中, 冷冻室 132—般处于箱体 的最下方, 压机舱处于冷冻室 132的后方, 冷冻室 132不可避免的要做成为压机舱让位 的异形空间, 减小了冷冻室 132的存储容积, 并且还带来了以下多个方面的问题。 一方 面, 冷冻室 132所处位置较低, 用户需要大幅度弯腰或蹲下才能对冷冻室 132进行取放 物品的操作, 不便于用户使用, 尤其不方便老人使用; 另一方面, 由于冷冻室 132进深 深度减小, 为保证冷冻室 132的存储容积, 需要增加冷冻室 132高度方向的空间, 用户 在向冷冻室 132存放物品时需要将物品在高度方向上层叠堆放, 不方便用户查找物品, 而且位于冷冻室 132底部的物品容易被遮挡, 使得用户不容易发现而造成遗忘, 导致物 品变质、 浪费; 再者, 由于冷冻室 132为异形, 不是一个矩形空间, 对于一些体积较大 且不易分割的物品, 不便放置于冷冻室 132中。
而本实施例中, 冷却室处于箱体 100的下方, 使得冷却室占用箱体 100内的下部空 间, 而储物间室处于冷却室的上方, 冷却室的后下方可限定出压机舱, 储物间室无需再 为压机舱让位, 保证储物间室的存储容积。
具体地, 冷却室可由冷冻内胆 130进行限定, 冷冻内胆 130—般位于箱体 100的下 部, 冷冻内胆 130 内限定出冷却室和位于冷却室上方的冷冻室 132。 由此抬高了冷冻室 132, 降低用户对冷冻室 132进行取放物品操作时的弯腰程度, 提升用户的使用体验。 同 时, 冷冻室 132无需再为压机舱让位, 使得冷冻室 132为一个矩形空间, 从而可将物品 由叠式存放变为平铺展开式存放, 便于用户查找物品, 节省用户的时间和精力; 同时, 也便于放置体积较大不易分割的物品, 解决无法在冷冻室 132放置较大物品的痛点。
一般地, 冰箱 10还包括位于冷冻内胆 130上方的其他储物内胆, 该储物内胆可为变 温内胆 131或冷藏内胆 120。本实施例中, 变温内胆 131位于冷冻内胆 130的上方, 冷藏 内胆 120位于变温内胆 131的上方。 变温内胆 131 内限定有变温室 1311, 如图 1、 图 2 所示, 变温内胆 131为两个, 两个变温内胆 131横向分布, 每个变温内胆 131限定有一 个变温室 1311。
如本领域技术人员所熟知的, 冷藏室 121 内的温度一般处于 2°C至 10°C之间, 优先 为 4°C至 7°C。冷冻室 132内的温度范围一般处于 -22°C至 -14°C。变温室 1311可随意调到 -18°C至 8°C。 不同种类的物品的最佳存储温度并不相同, 适宜存放的位置也并不相同, 例如果蔬类食物适宜存放于冷藏室 121, 而肉类食物适宜存放于冷冻室 132。
冷藏内胆 120内可限定有冷藏风道 (未示出) , 冷藏风道中设置有冷藏蒸发器 (未 示出) 和冷藏风机 (未示出) , 以对冷藏室 121进行独立送风。
在离心风机 103的驱动下, 冷却气流经送风风道 141输送至冷却室上方的至少一个 储物间室内。本实施例中, 冷却气流经送风风道 141输送至冷冻室 132。 如图 1所示, 送 风风道 141位于冷冻内胆 130的后壁内侧, 送风风道 141形成有与冷冻室 132连通的冷 冻室进风口 141a, 以将至少部分冷却气流输送至冷冻室 132内。 一般地, 冷冻内胆 130 的后壁形成有向后凹陷与送风风道 141匹配的凹部, 送风风道 141嵌入该凹部内。
每个变温内胆 131的后壁后侧可设置有变温室风道 (未示出) , 变温内胆 131的后 壁形成有与变温室风道的出风口连通的变温室进风口 131a, 变温室风道配置为可受控地 连通送风风道 141, 以将送风风道 141的部分冷却气流输送至变温室 1311中。
如图 7所示, 送风风道 141顶端形成有至少一个第一顶开口 141g, 第一顶开口 141g 与变温室风道的进风口一一对应, 冷冻内胆 130 的顶壁形成有与至少一个第一顶开口 141g—对应的至少一个第二顶开口 130d, 以通过第二顶开口 130d将第一顶开口 141g 与变温室风道的进风口连通。送风风道 141的第一顶开口 141g处可设置有风门, 以受控 打开或关闭第一顶开口 141g。 如图 1所示, 变温内胆 131为两个, 相应地, 变温室风道 为两个, 第一顶开口 141g、 第二顶开口 130d均为两个。
以下对冷冻内胆 130和冷却室进行具体说明:
如图 3和图 4所示, 在一些实施例中, 冷冻内胆 130的横向两个侧壁与冷却室对应 的区域分别向冷却室方向凸出, 以分别形成一个第二限位凸台 130b。
冰箱 10还包括罩板, 罩板构成冷却室的顶壁和前壁, 并与两个第二限位凸台 130b、 两个冷冻内胆 130的侧壁位于对应的第二限位凸台 130b前方的区段、冷冻内胆 130的底 壁及冷冻内胆 130的后壁共同限定出冷却室。
蒸发器 101整体可呈扁平立方体状横置于冷却室中, 也即蒸发器 101的长、 宽面平 行于水平面, 厚度面垂直于水平面放置, 而且厚度尺寸明显小于蒸发器 101的长度尺寸。 通过将蒸发器 101横置于冷却室中, 避免蒸发器 101 占用更多的空间, 保证冷却室上部 的冷冻室 132的存储容积。
如图 2所示, 罩板包括顶盖 1021和至少一个前盖组 102, 顶盖 1021位于蒸发器 101 的上方, 每个前盖组 102的前侧形成有至少一个前回风入口, 以使得冷冻室 132的回风 气流通过该至少一个前回风入口进入冷却室中由蒸发器 101进行冷却, 从而在冷却室和 冷冻室 132之间形成气流循环。
在一些实施例中, 如图 1所示, 前盖组 102为两个, 两个前盖组 102沿横向分布, 每个前盖组 102的前侧形成有两个前回风入口, 分别为为第一前回风入口 102a和第二前 回风入口 102b。
冷冻内胆 130的侧壁形成有侧回风入口(未示出), 侧回风入口通过侧回风通道(未 示出)与变温内胆 131连通, 以利用侧回风通道将变温室 1311的回风气流输送至冷却室 中进行冷却, 从而在变温室 1311与冷却室之间形成气流循环。
优选地,侧回风入口形成于冷冻内胆 130的侧壁位于对应的第二限位凸台 130b前方 的区段,使得侧回风入口更加靠前, 以使得变温室 1311的回风气流从蒸发器 101 的前方 向后流动, 延长变温室 1311的回风气流与蒸发器 101的换热路径, 提升换热效率。
冷冻内胆 130的底壁的后部区段形成有向上凸出的至少一个第一限位凸台 130a, 每 个第一限位凸台 130a形成有限位槽 130al ; 送风风道 141 的下部区段形成有与限位槽 130al配合的配合部 141f, 配合部 141f与限位槽 130al配合, 可防止送风风道 141下移。
如图 3所示, 第一限位凸台 130a为两个, 两个第一限位凸台 130a在横向上间隔分 布, 相应地, 配合部 141f为两个, 两个配合部 141f在横向上间隔分布。
一般地, 位于冷冻内胆 130中的送风风道 141的下部区段不可避免地要与冷冻内胆
130的底壁之间形成间隔空隙, 冰箱 10装配完成后, 正常情况下, 送风风道 141的顶端 的第一顶开口 141g应与冷冻内胆 130的顶壁对应的第二顶开口 130d密封配合。
而冰箱 10在运输过程中,当受到碰撞时易导致送风风道 141下坠,使得送风风道 141 的顶端的第一顶开口 141g与冷冻内胆 130的顶壁对应的第二顶开口 130d之间出现缝隙。 冰箱 10运行过程中, 变温室 1311中的气流会通过缝隙进入到冷冻室 132中, 而由于变 温室 1311的气流温度一般高于冷冻室 132的气流温度, 导致送风风道 141的顶端附近结 霜, 对冷冻室 132的温度和冷却气流的输送产生影响。本实施例中, 通过对冷冻内胆 130 的底壁和送风风道 141的下部区段进行如上特别的设计,可避免冰箱 10运输过程中受到 碰撞而导致送风风道 141下坠, 保证冰箱 10运行过程中的制冷效果。
冷冻内胆 130的底壁的横向两侧临近后端的位置分别形成有向上凸出的一个第三限 位凸台 130c,两个第三限位凸台 130c与冷冻内胆 130的底壁位于蒸发器 101后方的区段 限定出布置离心风机 103的空间。
每个第三限位凸台 130c可形成有第一安装孔(未标号) 。 离心风机 103的蜗壳形成 有与两个第一安装孔一一对应的第二安装孔 103cl ,以通过依次穿过第二安装孔 103cl和 第一安装孔的安装件 (例如, 螺钉) 将离心风机 103的蜗壳安装于冷冻内胆 130的底壁 上。 例如, 如图 8、 图 10所示, 下盒体 1032的侧壁的横向两侧分别形成有一个安装板 103c, 安装板 103c形成有与对应的第一安装孔对应的第二安装孔 103cl o
以下对离心风机 103和送风风道 141进行具体说明:
离心风机 103位于蒸发器 101的后方, 包括蜗壳和设置于蜗壳内的叶轮 1031, 送风 风道 141与蜗壳可拆卸连接, 并使得送风风道的风道进风口与蜗壳的蜗壳出风口连通, 以使得蜗壳内的气流进入送风风道 141中。
现有冰箱 10中,风道与风机的蜗壳多是一体式结构,不方便运输,无法进行模块化, 而本实施例中, 送风风道 141与离心风机 103的蜗壳采用分体式设计, 实现模块化, 方 便拆装和运输, 提 良品率。
蜗壳包括下盒体 1032和设置在下盒体 1032上的上盖体 1033 ,下盒体 1032与上盖体 1033可扣合连接,方便蜗壳的拆卸和装配。上盖体 1033的后端和下部均敞开,也即是说, 上盖体 1033包括顶壁 103a和由顶壁 103a向下延伸的第一侧壁 103d; 相应地, 下盒体 1032的后端和上部均敞开,下盒体 1032包括底壁 103b和由底壁 103b向上延伸的第二侧 壁。上盖体 1033的顶壁 103a形成有蜗壳进风口 1033a,上盖体 1033的后端与下盒体 1032 的后端限定出蜗壳出风口。
上盖体 1033与下盒体 1032扣合后, 上盖体 1033的第一侧壁 103d位于下盒体 1032 的第二侧壁的内侧,也即是说,上盖体 1033的第一侧壁 103d与上盖体 1033的顶壁 103a 以及下盒体 1032的底壁 103b限定出蜗壳内的送风风道。
参见图 9, 上盖体 1033的第一侧壁 103d具有蜗型线, 构造成蜗壳风道, 更好地引导 气流向蜗壳出风口流动,降低噪音。上盖体 1033的顶壁 103a的内面形成有蜗型槽 103a3 , 蜗型槽 103a3与上盖体 1033的第一侧壁 103d进行配合, 更好地引导气流流动。 例如, 上盖体 1033的顶壁 103a的第七倾斜直段的内面形成有蜗型槽 103a3 o蜗型槽 103a3形成 有前述的蜗壳进风口 1033a,叶轮 1031设置于蜗型槽 103a3与下盒体 1032限定的区域内。
叶轮 1031的转轴轴线与竖直线的夹角 0可为 20° 至 35 ° , 例如, 0为 20° 、 25 ° 、 33。 、 35。 等。
离心风机 103的蜗壳的前端面与蒸发器 101的后端面之间的水平距离 a可为 15mm 至 35mm, 例如, a为 15 mm、 20 mm、 25 mm、 30 mm、 35 mm, 避免因离心风机 103 与蒸发器 101距离过小而造成离心风机 103结霜。
下盒体 1032的底壁 103b可形成有至少一个排水孔 103b3 ,如图 10所示,排水孔 103b3 为两个, 以便于排出可能形成的冷凝水。
送风风道 141位于离心风机 103的后方,包括位于前侧的风道前盖板 1411和位于后 侧的风道后盖板 1412,风道前盖板 1411和风道后盖板 1412可扣合装配。风道前盖板 1411 与上盖体 1033可拆卸连接, 风道后盖板 1412与下盒体 1032可拆卸连接, 使得蜗壳出风 口与送风风道 141的风道进风口连通。
如图 6所示, 风道后盖板 1412可包括位于下部的竖向延伸的后竖板段 1412e和由后 竖板段 1412e的下端向前下方弯折延伸的接合段, 接合段位于风道前盖板 1411的下方, 接合段的前端与风道前盖板 1411的下端限定出风道进风口。 风道后盖板 1412通过接合 段与下盒体 1032可拆卸连接, 前述的配合部 141f则形成于该接合段上。
本实施例中, 风道后盖板 1412被设计为具有由后竖板段 1412e下端向前下方弯折延 伸的接合段, 便于与前方的离心风机 103 的蜗壳连接, 促使蜗壳内的气流平缓地进入送 风风道 141内, 降低噪音。 同时, 接合段形成与冷冻内胆 130底壁的限位槽 130al相配 合的配合部 141f,使得风道后盖板 1412与冷冻内胆 130和离心风机 103的蜗壳均能积极 配合, 整体布局更加紧凑、 合理。 如图 6所示, 风道后盖板 1412的接合段包括由后竖板段 1412e向前下方弯曲延伸的 过渡曲段 1412a、由过渡曲段 1412a向前下方倾斜延伸的第一倾斜直段 1412b和由第一倾 斜直段 1412b向前前后延伸的水平直段 1412c。
水平直段 1412c的前端形成有向下竖向延伸的第一立板 1412d,第一立板 1412d由水 平直段 1412c的横向一侧延伸至另一侧, 第一立板 1412d的前立面形成有向前凸出的至 少一个第一卡扣 141c,第一立板 1412d的后立面可形成有向后凸出的前述的配合部 141fo 下盒体 1032的底壁 103b的后端形成有向下竖向延伸的第二立板 103bl, 第二立板 103bl由下盒体 1032的底壁 103b的横向一侧延伸至另一侧,第二立板 103bl的下端形成 有与至少一个第一卡扣 141c—对应并适配的第一缺口 103bl l , 第一卡扣 141c卡入对 应的第一缺口 103bl l并与第二立板 103bl的前立面勾持, 以将下盒体 1032扣合在风道 后盖板 1412上。
第一卡扣 141c为两个,三个第一卡扣 141c横向间隔分布,相应地,第一缺口 103bl l 为三个, 三个第一缺口 103bl l横向间隔分布。
下盒体 1032与风道后盖板 1412扣合时,第一立板 1412d的前立面与第二立板 103bl 的后立面接近贴合, 两者之间存在较小的间隔缝隙, 该间隔缝隙中可塞入海绵条, 避免 漏风。
如图 6所示, 风道前盖板 1411包括位于下部的竖向延伸的前竖板段 1411a, 前竖板 段 1411a的前壁面形成有向前凸出的至少一个第二卡扣 141b。
上盖体 1033的顶壁 103a的后端形成有向上延伸的第三立板 103al, 第三立板 103al 由上盖体 1033的顶壁 103a的横向一侧延伸至另一侧, 第三立板 103al的上端形成有与 至少一个第二卡扣 141b -对应并适配的至少一个第二缺口 103al l, 第二卡扣 141b卡 入对应的第二缺口 103al l并与第三立板 103al的前立面勾持, 以将上盖体 1033扣合在 风道前盖板 1411上。
第二卡扣 141b为两个,两个第二卡扣 141b横向间隔分布,相应地,第二缺口 103al l 为两个, 两个第二缺口 103al l横向间隔分布。
前竖板段 1411a的横向尺寸应等于或大于第三立板 103al的横向尺寸, 如图 8所示, 前竖板段 1411a的横向尺寸与第三立板的 103al横向尺寸大致相同, 以使得上盖体 1033 与风道前盖板 1411扣合时, 前竖板段 1411a能够完全遮挡第三立板 103al o 上盖体 1033 与风道前盖板 1411扣合时, 前竖板段 1411a的后立面与第三立板 103al的前立面接近贴 合, 两者之间存在较小的间隔缝隙, 该间隔缝隙中可塞入海绵条, 避免漏风。
前竖板段 1411a的后壁可形成有向后凸出的多个加强筋 141e, 增强前竖板段 1411a 的强度。
第三立板 103al 的前立面形成有沿横向间隔分布的多个加强筋 103a2, 第三立板 103al还形成有凸出于第三立板 103al上方的安装部 141h, 例如, 安装部 141h形成于第 三立板 103al的横向中部位置, 安装部 141h形成有第一螺钉孔, 前竖板段 1411a与安装 部 141h对应的区域形成有与第一螺钉孔对应的第二螺钉孔, 以利用穿过第一螺钉孔和第 二螺钉孔的螺钉将上盖体 1033与风道前盖板 1411装配。
风道后盖板 1412的横向两侧还分别形成有向前延伸的一个密封部 141d,
如图 6和图 8所示, 风道后盖板 1412的后竖板段 1412e和接合段限定的区段记为风 道后盖板 1412 的下板段, 下板段的横向两端内侧分别形成有向前延伸的一个密封部 141d, 每个密封部 141d均延伸至离心风机 103的蜗壳内, 用于密封送风风道 141与离心 风机 103的蜗壳交接处的横向两侧, 也即是用于密封风道后盖板 1412与下盒体 1032扣 合时的横向两侧的交接处, 以及用于密封风道前盖板 1411与上盖体 1033扣合时的横向 两侧的交接处,以避免漏风, 也即是密封风道进风口和蜗壳出风口的交接处的横向两侧。
本实施例的冰箱 10中,箱体 100底部限定有压机舱,且压机舱位于冷却室的后下方, 如前, 冷冻室 132不用再为压机舱让位, 保证了冷冻室 132的进深, 便于放置体积较大 不易分割的物品。
如图 11所示, 冰箱 10还包括散热风机 106, 散热风机 106可为轴流风机, 压缩机 104、 散热风机 106和冷凝器 105沿横向依次间隔布置在压机舱内。
在一些实施例中,压机舱的后壁与压缩机 104对应的区段 1162形成有至少一个后出 风孔 1162a。
实际上, 在本发明之前, 本领域技术人员通常的设计思路都是在压机舱的后壁开设 面向冷凝器 105的后进风孔和开设面向压缩机 104的后出风孔 1162a,在压机舱的后部完 成散热气流的循环; 或者在压机舱的前壁、 后壁分别形成通风孔, 形成前后方向的散热 循环风路。 在面对提升压机舱散热效果的问题时, 本领域技术人员通常是增加压机舱后 壁的后进风孔、 后出风孔 1162a的数量扩大通风面积, 或者增加冷凝器 105的换热面积, 例如采用换热面积更大的 U型冷凝器。
而本发明申请人创造性地认识到冷凝器 105 的换热面积和压机舱的通风面积并不是 越大越好, 在增加冷凝器 105换热面积和压机舱通风面积的常规设计方案中, 会带来冷 凝器 105散热不均匀的问题, 对冰箱 10的制冷系统产生不利的影响。 为此, 本发明申请 人跳出常规设计思路, 创造性地提出一种不同于常规设计的新方案, 如图 11和图 12所 示, 在箱体的底壁限定有横向排布的临近冷凝器 105的底进风口 110a和临近压缩机 104 的底出风口 110b, 在冰箱 10的底部完成散热气流的循环, 充分利用了冰箱 10与支撑面 之间的这一空间, 无需加大冰箱 10的后壁与橱柜的距离, 减小了冰箱 10所占空间的同 时, 保证压机舱良好的散热, 从根本上解决了嵌入式冰箱 10的压机舱散热和空间占用之 间无法得到平衡的痛点, 具有尤其重要的意义。
散热风机 106配置为促使底进风口 110a周围的环境空气从底进风口 110a进入压机 舱, 并依次经过冷凝器 105、 压缩机 104, 之后从底出风口 110b流动至外部环境中, 以 对压缩机 104和冷凝器 105进行散热。
在蒸气压缩制冷循环中, 冷凝器 105的表面温度一般低于压缩机 104的表面温度, 故上述过程中, 使外部空气先冷却冷凝器 105再冷却压缩机 104。
进一步特别地, 在本发明的优选实施例中, (压机舱的后壁) 背板 116面向冷凝器 105的板段 1161为连续的板面,也即是说背板 116面向冷凝器 105的板段 1161上没有散 热孔。
本发明申请人创造性地认识到即使在不增加冷凝器 105换热面积的前提下, 反常态 的减小压机舱的通风面积, 能够形成更加良好的散热气流路径, 而且仍然可达到较好的 散热效果。
本发明优选方案中, 申请人突破常规设计思路, 将压机舱的后壁(背板 116)与冷凝 器 105对应的板段 1161设计为连续板面, 将进入压机舱内的散热气流封闭在冷凝器 105 处,使得由底进风口 110a进入的环境空气更多地集中在冷凝器 105处,保证了冷凝器 105 各个冷凝段的换热均匀性, 并且有利于形成更加良好的散热气流路径, 同样可达到较好 的散热效果。
并且, 由于背板 116面向冷凝器 105的板段 1161为连续板面, 不具有进风孔, 避免 了常规设计中出风和进风都集中在压机舱的后部而导致从压机舱吹出的热风未及时经环 境空气冷却而再次进入到压机舱中, 对冷凝器 105 的换热产生不利影响, 由此保证了冷 凝器 105的换热效率。
在一些实施例中,压机舱的横向两个侧壁均形成有一个侧通风孔 119a,侧通风孔 119a 可覆盖有通风盖板 108, 通风盖板 108形成有格栅式通风小孔; 冰箱 10的外壳包括横向 上的两个箱体侧板 111, 两个箱体侧板 111竖向延伸, 构成冰箱 10的两个侧壁, 两个箱 体侧板 111分别形成一个与对应的侧通风孔 119a连通的侧开口 111a,以使得散热气流流 动至冰箱 10的外部。 由此进一步增加散热路径, 保证压机舱的散热效果。
进一步特别地,冷凝器 105包括横向延伸的第一直段 1051、前后延伸的第二直段 1052 以及将第一直段 1051和第二直段 1052连接的过渡曲段 (未标号) , 由此形成换热面积 适当的 L型冷凝器 105。 前述压机舱的后壁 (背板 116) 与冷凝器 105对应的板段 1161 也即是背板 116面向第一直段 1051的板段 1161。
由侧通风孔 119a进入的环境气流直接与第二直段 1052进行换热, 由底进风口 110a 进入的环境空气直接与第一直段 1051进行换热, 由此进一步将进入压机舱内的环境空气 更多地集中在冷凝器 105处, 保证冷凝器 105整体散热的均匀性。
进一步特别地, 箱体 100的壳体包括底板、托板 112、两个侧板 119和竖向延伸的背 板 116, 托板 112构成压机舱的底壁, 用于承载压缩机 104、散热风机 106和冷凝器 105, 两个侧板分别构成压机舱的横向两个侧壁, 竖向延伸的背板 116构成压机舱的后壁。
进一步特别地, 底板包括位于底部前侧的底部水平区段 113和从底部水平区段 113 的后端向后上方弯折延伸的弯折区段, 弯折区段延伸至托板 112的上方, 压缩机 104、散 热风机 106及冷凝器 105沿横向依次间隔布置于托板 112上,并位于托板 112、两个侧板、 背板 116及弯折区段限定的空间中。
托板 112与底部水平区段 113共同构成箱体 100的底壁, 且托板 112与底部水平区 段 113间隔分布, 以利用底部水平区段 113的后端与托板 112的前端限定出底开口, 其 中,弯折区段具有位于底进风口 110a和底出风口 110b上方的倾斜区段 114。两个侧板由 托板 112的横向上的两侧分别向上延伸至弯折区段的横向上的两侧, 以封闭压机舱的横 向两侧; 背板 116由托板 112的后端向上延伸至弯折区段的后端。
具体地, 弯折区段可包括竖直区段 1131、 前述的倾斜区段 114和顶部水平区段 115, 竖直区段 1131由底部水平区段 113的后端向上延伸, 倾斜区段 114由竖直区段 1131的 上端向后上方延伸至托板 112的上方, 顶部水平区段 115由倾斜区段 114的后端向后方 延伸至背板, 以遮蔽压缩机 104、 散热风机 106及冷凝器 105的上方。
箱体 100还包括分隔件 117,分隔件 117设置于弯折区段的后方,其前部与底部水平 区段 113的后端连接, 其后部与托板 112的前端连接, 设置为将底开口分隔为横向排布 的底进风口 110a和底出风口 110b。 由前述可知, 本实施例的底进风口 110a和底出风口 110b由分隔件 117、 托板 112、 底部水平区段 113限定而成, 由此形成了开口尺寸较大的槽形的底进风口 110a和底出风 口 110b, 增大了进风、 出风面积, 减小了进风阻力, 使得气流流通更加顺畅, 而且制造 工艺更加简单, 使得压机舱的整体稳定性更强。
特别地, 本发明申请人创造性认识到, 倾斜区段 114的斜坡结构能够对进风气流进 行引导、 整流, 使得由底进风口 110a进入的气流更加集中地流向冷凝器 105, 避免了气 流过于分散而无法更多地通过冷凝器 105, 由此进一步保证了冷凝器 105的散热效果; 同 时, 倾斜区段 114的斜坡将底出风口 110b的出风气流向地出风口的前侧进行引导, 使得 出风气流更加顺畅地流出压机舱外部, 由此进一步提升了气流流通的顺畅性。
进一步特别地, 在优选的实施例中, 倾斜区段 114与水平面的夹角小于 45 ° , 在该 实施例中, 倾斜区段 114对气流的导向、 整流效果更好。
并且, 令人意想不到的是, 本申请发明人创造性地认识到倾斜区段 114的斜坡对气 流噪音起到了较好的抑制效果, 在样机试验中, 具有前述特别设计的倾斜区段 114的压 机舱的噪音可减小 0.65分贝以上。
另外, 传统冰箱 10中, 箱体 100的底部一般具有大致平板型结构的承载板, 压缩机
104设置于承载板内侧,压缩机 104运行中产生的振动对箱体 100底部影响较大。而本实 施例中, 如前所述, 箱体 100的底部由特殊结构的底板和托板 112构造为一个立体结构, 为压缩机 104布置提供独立的立体空间, 利用托板 112承载压缩机 104, 减小压缩机 104 振动对箱体 100底部的其他部件的影响。 另外, 通过将箱体 100设计为如上巧妙的特殊 结构, 使得冰箱 10底部的结构紧凑、 布局合理, 减小了冰箱 10的整体体积, 同时充分 利用了冰箱 10底部的空间, 保证了压缩机 104和冷凝器 105的散热效率。
进一步特别地, 冷凝器 105的上端设置有挡风件 1056, 挡风件 1056可为挡风海绵, 填充冷凝器 105 的上端与弯折区段之间的空间, 也即是说, 挡风件 1056覆盖第一直段 1051、 第二直段 1052及过渡曲段的上端, 且挡风件 1056的上端应与弯折区段抵接, 以 密封冷凝器 105的上端, 以免进入压机舱的部分空气从冷凝器 105的上端与弯折区段之 间的空间通过而不经过冷凝器 105 , 从而使得进入压机舱的空气尽可能多的通过冷凝器 105进行换热, 进一步提升冷凝器 105的散热效果。
冰箱 10还包括前后延伸的挡风条 107, 挡风条 107位于底进风口和底出风口之间, 由底部水平区段 113下表面延伸至托板 112下表面, 并连接分隔件的下端, 以利用挡风 条 107和分隔件将底进风口和底出风口完全隔离, 从而在冰箱 10置于一支撑面时, 横向 分隔箱体 100的底壁与支撑面之间的空间, 以允许外部空气在散热风机 106的作用下经 位于挡风条 107横向一侧的底进风口进入压机舱内,并依次流经冷凝器 105、压缩机 104, 最后从位于挡风条 107横向另一侧的底出风口流出, 从而将底进风口和底出风口完全隔 离, 保证进入冷凝器 105处的外部空气与从压缩机 104处排出的散热空气不会串流, 进 一步保证了散热效率。
至此, 本领域技术人员应认识到, 虽然本文已详尽示出和描述了本发明的多个示例 性实施例, 但是, 在不脱离本发明精神和范围的情况下, 仍可根据本发明公开的内容直 接确定或推导出符合本发明原理的许多其他变型或修改。 因此, 本发明的范围应被理解 和认定为覆盖了所有这些其他变型或修改。

Claims

权 利 要 求
1. 一种冰箱, 包括:
箱体, 其内限定有位于下方的冷却室和位于所述冷却室上方的至少一个储物间室; 蒸发器, 设置于所述冷却室内, 配置为冷却进入所述冷却室内的气流, 以形成冷却 气流;
离心风机, 包括蜗壳和设置于所述蜗壳内的叶轮, 配置为促使所述冷却气流向至少 一个所述储物间室内流动;
送风风道, 与所述蜗壳可拆卸连接, 并与蜗壳出风口连通, 设置为将所述冷却气流 输送至至少一个所述储物间室内。
2. 根据权利要求 1所述的冰箱, 其中
所述离心风机位于所述蒸发器的后方, 所述送风风道位于所述离心风机的后方; 所述蜗壳包括:
上部和后端均敞开的下盒体, 和扣合在所述下盒体上的、 下部和后端均敞开的上盖 体, 所述上盖体的后端与所述下盒体的后端限定出所述蜗壳出风口;
所述送风风道包括位于前侧的风道前盖板和位于后侧的风道后盖板, 所述风道前盖 板与所述上盖体可拆卸连接, 所述风道后盖板与所述下盒体可拆卸连接。
3. 根据权利要求 2所述的冰箱, 其中
所述风道后盖板包括位于下部的竖向延伸的后竖板段和由所述后竖板段的下端向前 下方弯折延伸的接合段, 所述接合段与所述风道前盖板的下端限定出与所述蜗壳出风口 连通的风道进风口;
所述风道后盖板通过所述接合段与所述下盒体可拆卸连接。
4. 根据权利要求 3所述的冰箱, 其中
所述接合段包括位于最前侧的前后延伸的水平直段, 所述水平直段的前端形成有向 下竖向延伸的第一立板, 所述第一立板由所述水平直段的横向一侧延伸至另一侧, 所述 第一立板的前立面形成有向前凸出的至少一个第一卡扣;
所述下盒体的底壁的后端形成有向下竖向延伸的第二立板, 所述第二立板由所述下 盒体的底壁的横向一侧延伸至另一侧;
所述第二立板的下端形成有与所述至少一个第一卡扣一一对应并适配的第一缺口; 所述第一卡扣卡入对应的所述第一缺口并与所述第二立板的前立面勾持, 以将所述 下盒体与所述风道后盖板装配。
5. 根据权利要求 3所述的冰箱, 其中
所述上盖体的顶壁的后端形成有向上延伸的第三立板, 所述第三立板由所述上盖体 的顶壁的横向一侧延伸至另一侧;
所述风道前盖板包括位于下部的竖向延伸的前竖板段, 所述前竖板段的横向尺寸等 于或大于所述第三立板的横向尺寸, 所述前竖板段的前壁面形成有向前凸出的至少一个 第二卡扣;
所述第三立板的上端形成有与所述至少一个第二卡扣一一对应并适配的至少一个第 二缺口; 所述第二卡扣卡入对应的所述第二缺口并与所述第三立板的前立面勾持, 以将所述 上盖体与所述风道前盖板装配。
6. 根据权利要求 3所述的冰箱, 其中
所述后竖板段和所述接合段限定的区段记为所述风道后盖板的下板段;
所述下板段的横向两端内侧分别形成有一个密封部, 两个所述密封部均向前延伸至 所述蜗壳内, 以密封所述风道进风口和所述蜗壳出风口的交接处的横向两侧。
7. 根据权利要求 2所述的冰箱, 其中
所述上盖体与所述下盒体扣合连接时, 所述上盖体的侧壁位于所述下盒体的侧壁的 内侧, 以利用所述上盖体的侧壁与所述上盖体的顶壁以及所述下盒体的底壁限定出所述 蜗壳内的蜗壳风道。
8. 根据权利要求 2所述的冰箱, 其中
所述上盖体的顶壁形成有蜗壳进风口;
所述叶轮的旋转轴线与竖直线的夹角为 20° 至 35 ° 。
9. 根据权利要求 2所述的冰箱, 其中
所述蜗壳的前端面与所述蒸发器的后端面之间的水平距离为 15毫米至 35毫米。
10. 根据权利要求 1所述的冰箱, 其中
所述箱体包括位于最下方的冷冻内胆, 所述冷冻内胆内限定有所述冷却室; 所述储物间室包括由所述冷冻内胆限定且位于所述冷却室上方的冷冻室; 所述离心风机配置为促使所述冷却气流经所述送风风道流动至所述冷冻室内。
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