WO2023123939A1 - 制冷设备 - Google Patents
制冷设备 Download PDFInfo
- Publication number
- WO2023123939A1 WO2023123939A1 PCT/CN2022/101929 CN2022101929W WO2023123939A1 WO 2023123939 A1 WO2023123939 A1 WO 2023123939A1 CN 2022101929 W CN2022101929 W CN 2022101929W WO 2023123939 A1 WO2023123939 A1 WO 2023123939A1
- Authority
- WO
- WIPO (PCT)
- Prior art keywords
- drainage
- air
- air inlet
- evaporator
- cavity
- Prior art date
Links
- 238000005057 refrigeration Methods 0.000 title claims abstract description 77
- 238000005192 partition Methods 0.000 claims abstract description 140
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims description 434
- 238000001816 cooling Methods 0.000 claims description 57
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Images
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
-
- 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
-
- 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
- F25D17/065—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 with compartments at different temperatures
-
- 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
- F25D17/067—Evaporator fan units
-
- 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
- F25D17/08—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 using ducts
-
- 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
- F25D21/04—Preventing the formation of frost or condensate
-
- 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
-
- 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
- F25D21/14—Collecting or removing condensed and defrost water; Drip trays
-
- 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
-
- 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
- F25D23/006—General constructional features for mounting refrigerating machinery components
-
- 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
- F25D2317/00—Details 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
- F25D2317/06—Details 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
- F25D2317/067—Details 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
-
- 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
- F25D2317/00—Details 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
- F25D2317/06—Details 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
- F25D2317/068—Details 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
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02B—CLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO BUILDINGS, e.g. HOUSING, HOUSE APPLIANCES OR RELATED END-USER APPLICATIONS
- Y02B40/00—Technologies aiming at improving the efficiency of home appliances, e.g. induction cooking or efficient technologies for refrigerators, freezers or dish washers
Definitions
- the present disclosure relates to the technical field of refrigeration equipment, in particular to refrigeration equipment.
- the components of the refrigeration system need to occupy a part of the volume of the cabinet, and the installation positions of the components of the refrigeration system in the cabinet will affect the volume of the cabinet and the size of the storage space limited by the cabinet.
- the evaporator in the refrigeration system is arranged at the rear side of the refrigeration compartment of the refrigerator, the thickness of the cabinet is relatively large, the storage space in the depth direction of the cabinet is insufficient, and the user experience is not good.
- the present disclosure aims to solve at least one of the technical problems existing in the related art.
- the present disclosure proposes a refrigeration device.
- the air duct assembly is placed horizontally in the cabinet, the height and volume of the air duct assembly are reduced, the space of the refrigeration equipment is enlarged, and the capacity of the refrigeration equipment is increased.
- a refrigeration device comprising:
- the air duct assembly is located in the cabinet and separates the first room and the second room, including a partition part, an air duct part, an evaporator and a drain plate, and the partition part and the air duct part limit the The first cavity, the first air inlet, the second air inlet, the first air outlet and the second air outlet, the first air inlet, the first cavity, the first air outlet and the first room
- the chamber is suitable for communication
- the second air inlet, the first cavity, the second air outlet and the second chamber are suitable for communication;
- the first cavity is provided with the evaporator and the
- the drainage board, the air duct component supports the drainage board, the angle between the evaporator and the horizontal plane is less than or equal to a preset angle, or, the evaporator is parallel to the horizontal plane.
- the refrigeration equipment includes a cabinet body and an air duct assembly arranged in the cabinet body, the air duct assembly is placed horizontally in the cabinet body to separate two compartments, the air duct assembly includes a partition part and an air duct part, An evaporator is arranged between the partition part and the air duct part, and the evaporator is placed horizontally in the air duct assembly, and the angle formed between the evaporator and the horizontal plane is within a preset angle, or the evaporator is parallel to the horizontal plane, and the evaporation The angle between the evaporator and the horizontal plane is limited within the preset angle, which can limit the height of the evaporator. If the height of the evaporator is reduced, the space in the cabinet occupied by the air duct assembly will be reduced, and the capacity of the cabinet can be expanded to increase The capacity of large refrigeration equipment.
- the drainage board is configured with a water guiding part that is sunken downward relative to the top surface of the drainage board, and the extending direction of the water guiding part forms a second Four corners.
- the wind in the air duct assembly can flow along the extension direction of the water guide part, delaying the flow of the wind along the air outlet direction, prolonging the heat exchange time of the wind in the air duct assembly, and optimizing the heat exchange effect.
- the drain plate is configured with a drain portion that is recessed downward relative to the top surface of the drain plate, the drain portion is configured with an outlet, and the drain portion communicates with the water guide portion.
- the extension direction of the drainage part is not limited, and the water received by the drainage board can be discharged along the outlet to ensure heat exchange and drainage effects.
- the bottom of the water guiding part is inclined along a first direction, and the first direction forms a sixth angle with the top surface of the drainage board, so that The depth of the water guiding portion being recessed towards the drain portion gradually increases. So that the water in the water guide part flows into the drainage part, the drainage efficiency is improved, and the drainage effect is ensured.
- the bottom of the drainage part is inclined along a second direction, and the second direction forms a seventh angle with the top surface of the drainage plate, so that the The depth of the depression of the drainage portion gradually increases toward the outlet. In order to drain the water in the drain part out of the drain plate.
- the air channel part is provided with a water guide, one side of the water guide is facing the outlet and communicated with the outlet, and the other side of the water guide is configured to drain water In the direction away from the outlet, the water guide is inclined downward so that the water guide can guide the water out.
- the water guiding part extends to the end of the drainage plate and forms an opening
- a first drainage component is arranged on the side where the opening is located, and the opening of the water guiding part can play a role of draining water.
- a fan is further included, and the rotation axis of the fan forms a first included angle with the vertical direction.
- the fan is arranged horizontally to reduce the height space occupied by the fan and the space occupied by the air duct assembly.
- the present disclosure further includes a fan and a fan cover, the fan is arranged on one side of the evaporator, the fan cover is located between the fan and the evaporator, and the fan cover is located between the fan and the evaporator.
- the inlet communicates with the first cavity through the air vent of the fan cover plate, and the fan cover plate is configured with the first air exhaust port and the second air exhaust port.
- the installation method of the fan is not limited, and it can be installed horizontally or vertically.
- the cabinet body includes a tank body, the tank body is configured with a first channel, a cavity is formed inside the partition part, and the side of the partition part is provided with The second channel, the second channel, the cavity communicates with the first channel to form a foaming space.
- the air duct component and the tank body are foamed together, which can solve the problem of installation gap between the air duct component and the tank body, and ensure the independence of the first room and the second room.
- the partition member includes:
- the second plate body is arranged below the first plate body, the second plate body and the first plate body surround the cavity, and the edge of the second plate body is recessed downward to form a
- the cavity communicates with the concave part, and the concave part communicates with the second channel, which can optimize the foaming process and improve production efficiency.
- At least one of the baffle part and the air duct part is provided with a partition, and the orthographic projection of the partition at the first air inlet covers the first air inlet. local area, the orthographic projection is located at one end of the first air inlet close to the second air inlet, the partition is separated from the first air inlet by a preset distance, and the part of the first air inlet
- the air intake is diverted to reduce the cross-contact air volume of the two air inlets, reduce the amount of frosting at the cross-contact position of the air intake, prolong the defrosting interval, and reduce the energy consumption of defrosting.
- the second air inlet is arranged on the front side of the air duct part, and the front side of the partition part is provided with a mounting part covering the second air inlet, so as to ensure the second In the case of the ventilation effect of the air inlet, the second air inlet is hidden to prevent debris from entering the second air inlet, and also to ensure the integrity of the front-end structure of the air duct assembly.
- the first air inlet is located on the left side and the right side of the air duct assembly and is close to the front side of the air duct assembly.
- the first compartment is located above the second compartment, the first compartment is a refrigerating compartment, and the second compartment is a freezing compartment.
- Fig. 1 is a schematic structural diagram of a refrigeration device provided by an embodiment of the present disclosure, and the door body is not shown in the figure;
- Fig. 2 is a schematic diagram of a partial structure of a refrigeration device provided by an embodiment of the present disclosure, and the partial structure and tank of the cabinet are not shown in the figure;
- Fig. 3 is a partial enlarged structural schematic diagram of A in Fig. 2;
- Fig. 4 is a partial structural schematic diagram of an air duct assembly provided by an embodiment of the present disclosure.
- Fig. 5 is a schematic diagram of an exploded state of a partial structure of an air duct assembly provided by an embodiment of the present disclosure
- Fig. 6 is a schematic structural diagram of an exploded state of an air duct assembly provided by an embodiment of the present disclosure
- Fig. 7 is a schematic partial top view of an air duct assembly provided by an embodiment of the present disclosure, and the parts above the drainage board are not shown in the figure;
- Fig. 8 is a schematic diagram of the cross-sectional structure of B-B in Fig. 7;
- Fig. 9 is a schematic side view of a partial structure of an air duct assembly provided by an embodiment of the present disclosure.
- Fig. 10 is a partial structural schematic diagram of another refrigeration device provided by an embodiment of the present disclosure.
- the main difference from Fig. 2 is that the structure of the drainage plate is different, and the door body is not shown in the figure;
- Fig. 11 is a schematic diagram of a partially enlarged structure of part C in Fig. 10;
- Fig. 12 is a partial structural schematic diagram of another air duct assembly provided by an embodiment of the present disclosure, and the components above the drainage board are not shown in the figure;
- Fig. 13 is a schematic diagram of a partially decomposed structure of another air duct assembly provided by an embodiment of the present disclosure
- Fig. 14 is a schematic longitudinal sectional structural diagram of a third air duct assembly provided by an embodiment of the present disclosure, showing the position of the fan;
- Fig. 15 is a partial structural schematic diagram of a third air duct assembly provided by an embodiment of the present disclosure, and the components above the drainage board are not shown in the figure;
- Fig. 16 is a schematic diagram of a partial structural decomposition state of a third air duct assembly provided by an embodiment of the present disclosure
- Fig. 17 is a schematic structural diagram of a third type of refrigeration equipment provided by an embodiment of the present disclosure, and the door body is not shown in the figure;
- Fig. 18 is a schematic longitudinal sectional structural diagram of a third refrigeration device provided by an embodiment of the present disclosure.
- Fig. 19 is a schematic diagram of a partially enlarged structure of part D in Fig. 18;
- Fig. 20 is a schematic structural diagram of a fourth air duct assembly provided in an embodiment of the disclosure in an exploded state
- Fig. 21 is a schematic bottom view of a fourth air duct assembly provided by an embodiment of the present disclosure.
- Fig. 22 is a schematic diagram of a three-dimensional structure of a drainage board provided by an embodiment of the present disclosure.
- Fig. 23 is a schematic top view of a drainage board provided by an embodiment of the present disclosure.
- Fig. 24 is a schematic diagram of the E-E sectional structure in Fig. 23;
- Fig. 25 is a schematic diagram of the cross-sectional structure of F-F in Fig. 23;
- Fig. 26 is a schematic structural view of the second plate body and its installation state in the partition part of the air duct assembly provided by the embodiment of the present disclosure
- Fig. 27 is a structural schematic diagram of another second plate and its installation state in the partition part of the air duct assembly provided by the embodiment of the present disclosure
- Fig. 28 is a structural schematic diagram of the first inner recess and the second inner recess of the second plate in the partition part of the air duct assembly provided by an embodiment of the present disclosure
- Fig. 29 is a schematic structural view of the third inner recess of the second plate in the partition part of the air duct assembly provided by an embodiment of the present disclosure
- Fig. 30 is a schematic perspective view of the installation state of the evaporator and the drainage plate provided by the embodiment of the present disclosure
- Fig. 31 is a side view structural diagram of the installation state of the evaporator and the drainage plate provided by the embodiment of the present disclosure
- Fig. 32 is one of the schematic diagrams of the disassembled state of the evaporator, the drainage board and the heating element provided by the embodiment of the present disclosure
- Fig. 33 is the second schematic diagram of the disassembled state of the evaporator, the drainage board and the heating element provided by the embodiment of the present disclosure
- Fig. 34 is a schematic diagram of the installation state of the evaporator, the drainage plate and the second heater provided by the embodiment of the present disclosure
- Fig. 35 is a schematic diagram of an exploded state of the evaporator, the drainage plate and the second heater provided by the embodiment of the present disclosure
- Fig. 36 is a schematic diagram of the installation state of the evaporator, the drainage plate and the air duct components provided by the embodiment of the present disclosure
- Fig. 37 is a schematic structural view of the first support part in the air duct component provided by the embodiment of the present disclosure.
- Fig. 38 is a schematic diagram of a partially enlarged structure of part H in Fig. 37;
- Fig. 39 is a schematic top view of a partition member provided by an embodiment of the present disclosure.
- Fig. 40 is a schematic cross-sectional structure diagram of A-A in Fig. 39;
- Fig. 41 is a schematic structural view of the disassembled state of the tank provided by the embodiment of the present disclosure.
- Air duct assembly 201. First air inlet; 202. Second air inlet; 203. First air outlet; 204. Second air outlet;
- 210 partition member; 211, first plate body; 212, second plate body; 2121, first inner concave portion; 2122, first guide surface; 2123, first top surface; 2124, second inner concave portion; 2125, 2126, the second top surface; 2127, the third inner recess; 2128, the third top surface; 2129, the third guide surface; 213, the first insulation layer; 214, the third board; 215, the first Three wall panels; 216, cavity; 217, recess; 218, second channel;
- 220 air duct component; 221, second insulation layer; 222, first support part; 2221, partition part; 2222, guide surface; 22221, curved surface part; Support slope; 2225, second support groove; 223, water guide; 2231, third drain pipe; 224, third insulation layer; 225, second support part; 226, heating component;
- fan cover 241, first cover body; 2411, diversion surface; 242, second cover body; 2421, first water guide channel; 2422, barrier part; Air guide part; 2425, second air guide part; 2426, second installation column; 2427, partition plate; 2428, water collection part; 243, fan cover plate; 2431, third air guide part; 2432, fourth guide Air department; 244, air vent;
- the first drainage component 262, the first drainage port; 263, the first drainage pipe; 264, the first wall plate; 265, the second wall plate;
- tank body 312, first channel; 311, card slot; 313, positioning slot;
- the cabinet body 410, the first room; 420, the second room; 430, the return air component;
- connection and “connected” should be understood in a broad sense, for example, it can be a fixed connection or a detachable connection, Or integrated connection; it can be mechanical connection or electrical connection; it can be direct connection or indirect connection through an intermediary.
- connection should be understood in a broad sense, for example, it can be a fixed connection or a detachable connection, Or integrated connection; it can be mechanical connection or electrical connection; it can be direct connection or indirect connection through an intermediary.
- the first feature may be in direct contact with the first feature or the first feature and the second feature pass through the middle of the second feature.
- Media indirect contact Moreover, “above”, “above” and “above” the first feature on the second feature may mean that the first feature is directly above or obliquely above the second feature, or simply means that the first feature is higher in level than the second feature.
- “Below”, “beneath” and “beneath” the first feature may mean that the first feature is directly below or obliquely below the second feature, or simply means that the first feature is less horizontally than the second feature.
- the embodiment of the present disclosure provides a refrigeration device, which includes a cabinet body 400, and the cabinet body 400 includes a tank.
- the refrigerating equipment can be a variety of equipment such as refrigerators, freezers, display cabinets, vending cabinets or wine cabinets, and the refrigerating equipment can be used for refrigeration or freezing.
- orientations of front, rear, left, right, up, and down are in one-to-one correspondence with the orientations of the refrigeration equipment.
- the embodiment of the present disclosure provides a tank.
- the tank includes a tank body 300 and an air duct assembly 200.
- the space in the tank body 300 is divided into a first compartment 410 and a second compartment independent of each other by the air duct assembly 200. Room 420.
- the air duct assembly 200 can function to separate compartments, and can also function to circulate air. It should be noted that, in order to ensure the independence of the first compartment 410 and the second compartment 420, the installation of the air duct assembly 200 and the tank body 300 needs to be sealed to avoid the first compartment 410 and the second compartment 420 Between the wind.
- the embodiment of the present disclosure provides an air duct assembly 200, the air duct assembly 200 can divide the entire space in the tank body 300 into two parts, the first compartment 410 and the second compartment 420, or the air duct assembly 200 can The local space in the tank body 300 is divided into two parts, the first compartment 410 and the second compartment 420 .
- the air duct assembly 200 supplies air to the first compartment 410 and the second compartment 420 independently, and the functions of the first compartment 410 and the second compartment 420 may be the same or different.
- the first room 410 and the second room 420 are different, that is, the ambient temperatures in the first room 410 and the second room 420 are different
- the first room 410 can be a refrigerator
- the second room 420 It can be a freezing room
- the air duct assembly 200 supplies air to the freezing room at a lower frequency than the air supplying to the freezing room.
- the functions of the first room 410 and the second room 420 are the same, such as both are refrigerator rooms, the ambient temperature of the two refrigerator rooms may be the same or different.
- compartments separated by the air duct assembly 200 are not limited to refrigerating and freezing, and can also be temperature-changing compartments or other functional compartments, which can be specifically set according to needs.
- the cabinet body 400 When the cabinet body 400 is connected with the door body, and the door body is at the position of closing the cabinet body 400, then the first room 410 and the second room room 420 are two airtight and independent spaces; the door body is at the position of opening the cabinet body 400, then Items can be accessed from at least one of the first compartment 410 and the second compartment 420 .
- the number of air duct assemblies 200 installed in the refrigeration equipment can be set as required.
- the plate part 210 is located above the air channel part 220, and the partition part 210 and the air channel part 220 construct a first cavity 282, an air inlet suitable for communicating with the first cavity 282, and an air inlet suitable for communicating with the first cavity 282.
- the evaporator 230 and the drain plate 100 are arranged in the first cavity 282 , and the drain plate 100 is located below the evaporator 230 .
- the baffle part 210 and the air duct part 220 jointly define a connected air inlet, the first cavity 282 and an air exhaust port, so that the air entering the air duct assembly 200 can be discharged after heat exchange.
- the partition part 210 is connected to the tank body 300, and the junction of the partition part 210 and the tank body 300 is sealed, so that the space in the tank body 300 is separated from each other.
- the first cavity 282 between the partition member 210 and the air duct member 220 is used to install the evaporator 230, the drain plate 100, the heating structure for defrosting and other components, so as to meet the needs of the first compartment 410 and the second compartment. 420 heat exchange requirements.
- the air inlet of the air duct assembly 200 is divided into a first air inlet 201 and a second air inlet 202, the air outlet of the air duct assembly 200 is divided into a first air outlet 203 and a second air outlet 204, and the first air inlet 201 , the first cavity 282, the first air outlet 203 communicate with the first chamber 410 to form a first circulation path, the second air inlet 202, the first cavity 282, the second air outlet 204 and the second chamber 420
- the communication forms a second circulation path, and the first circulation path communicates with at least one of the second circulation paths to supply air to the first compartment 410 and the second compartment 420 .
- the number and positions of the first air inlet 201 , the second air inlet 202 , the first air outlet 203 and the second air outlet 204 are not limited.
- the first compartment 410 is located above the air duct assembly 200, the first compartment 410 is set as a refrigerator, the second compartment 420 is located below the air duct assembly 200, and the second compartment 420 is set as a freezer, that is, the first compartment 410 is located above the second compartment 420, and the air duct assembly 200 is provided with a first air outlet 203 facing upward and a second air outlet 204 facing downward; and A first air door 250 is provided at the first air outlet 203 for opening and closing adjustment; a second air door is provided at the second air outlet 204 for opening and closing adjustment.
- the air duct assembly 200 is provided with a first air inlet 201 and a second air inlet 202 near the front end.
- the first air inlet 201 communicates with the return air duct of the refrigerator compartment.
- the second air inlet 202 communicates with the freezer compartment, and the second air inlet 202 is arranged on the front side or the lower side of the air duct assembly 200 .
- first air inlet 201 and the second air inlet 202 are close to the same end of the air duct assembly 200
- the first air exhaust port 203 and the second air exhaust port 204 are also close to the same end of the air duct assembly 200
- the air outlet and the air outlet are generally at opposite ends.
- the above-mentioned air inlet is close to the front end, and the air outlet is close to the rear end, but the aforementioned position is not limited.
- the air inlet can also be close to the left end or the right end.
- the location is flexible and can be selected according to needs.
- the first air inlet 201 is located on the first side of the first cavity 282
- the second air inlet 202 is located on the second side of the first cavity 282
- the first side is adjacent to the second side, that is, the first The air inlet 201 and the second air inlet 202 are arranged on different sides of the air duct assembly 200.
- the air inlet of the first air inlet 201 and the air inlet of the second air inlet 202 will meet in the first cavity 282, when The first air inlet 201 and the second air inlet 202 have different air inlet temperatures (that is, the ambient temperature of the first compartment 410 is different from that of the second compartment 420), and the air intake of the first air inlet 201 is different from that of the second air inlet.
- the air inlet intersection of 202 is easy to frost due to contact heat exchange.
- the first air inlet 201 and the second air inlet 202 are located on different sides of the air duct assembly 200 , and it can also be understood that the first air inlet 201 and the second air inlet 202 form an included angle.
- the above-mentioned first side is at least one of the left side and the right side, and the second side is the front side.
- an embodiment of the drainage board 100 is provided, and the structure of the drainage board 100 is described by taking the installation of the drainage board 100 in the above-mentioned air duct assembly 200 as an example.
- the drainage board 100 is not limited to be installed in the above-mentioned air duct assembly 200 , other structures suitable for installing the drainage board 100 in the following embodiments may also be installed with the following drainage board 100 .
- the embodiment of the present disclosure provides a drainage board 100.
- the drainage board 100 is configured with a water guide part that is sunken downward relative to the top surface of the drainage board 100.
- the water guide part is directed towards the preset surface. Both sides extend to the edge of the drainage board 100, so that the edge of the drainage board 100 forms an opening 170, and the opening 170 faces the side where the first air inlet 201 is located, so that part of the air intake of the first air inlet 201 is suitable for passing through the opening 170 and along the The extending direction of the water guiding part flows into the first cavity 282 .
- the function of the first air inlet 201 here is not limited, it can be connected with the refrigerator compartment, and the water guiding part guides the cooling wind; or, the water guiding part communicates with the freezing compartment, and can also guide the freezing wind.
- the water guide part and designing the drainage board as an inverted V-shaped structure, part of the refrigerated return air enters the evaporator 230 through the V-shaped structure space, so as to solve the problem of condensation of the return air of the refrigerator and reduce the contact between the refrigerated return air and the freezing return air , reduce the condensation mixed with the refrigerated return air, make the frost more evenly distributed in the evaporator, and reduce the blockage of the refrigerated return air by frost.
- Part of the air intake from the first air inlet 201 passes through the opening 170 and is introduced into the first cavity 282 along the extending direction of the water guiding part, so that a part of the air intake from the first air inlet 201 can be shunted to reduce the interaction with the second air inlet 202
- the water guiding part is recessed downwards relative to the top surface of the drainage board 100, so that the drainage board 100 forms a groove, and a part of the air entering the first air inlet 201 can flow into the first cavity 282 along the groove, and the water guiding part can It acts as a guide for the wind inside.
- the preset surface forms an included angle with the extension direction of the water guiding part, and the preset surface extends along the direction from the air inlet to the air outlet, such as the air inlet is located at the front end of the air duct assembly 200, and the air outlet is located at the side of the air duct assembly 200
- the rear end, the preset surface extends from the front to the rear.
- the extension trend of the preset surface can be from front to back, the preset surface can extend obliquely, and the position of the preset surface can be selected according to needs.
- the predetermined surface may be a symmetrical surface of the drainage board 100 , and water guiding parts are arranged symmetrically on both sides of the predetermined surface, so that the drainage board 100 has a symmetrical structure, and the structural stability of the drainage board 100 is better.
- the predetermined surface is not limited to being a symmetrical surface, and the opening 170 may be disposed on one side or both sides of the drainage plate 100 .
- the preset surface can be a side of the drain plate 100, which is located on the opposite side of the first air inlet 201; when the opening 170 is set on both sides of the drain plate 100, the preset The face can be any face extending from front to back.
- the opening 170 of the above-mentioned drainage board 100 can play the role of guiding part of the air entering the first air inlet 201 , and the opening 170 of the drainage board 100 can also play the role of draining water.
- the depth of the water guide part's depression relative to the top surface of the drainage board 100 is not limited.
- the depth of the depression of the water guiding part gradually increases, and the water guiding part with such a structure may be referred to as the second water guiding part 130 . That is, the end of the second water guiding portion 130 facing the opening 170 has a greater depth, which is helpful for guiding the wind to flow therein.
- the depth of the second water guide 130 gradually increases, which can also increase the distance between the evaporator 230 and the drainage board 100, and appropriately expand the flow space of the wind; it also helps The defrosting water received by the drain plate 100 is drained from the opening 170 .
- the depth of the second water guiding portion 130 gradually increases toward one end of the opening 170 , and may increase continuously or in steps.
- the bottom of the second water guiding portion 130 is inclined along a first preset direction, and the first preset direction forms a first preset included angle with the top surface of the drainage board 100 . That is, the bottom surface of the second water guiding portion 130 is an inclined surface extending downward along the first preset direction, which is helpful for wind to flow into the first cavity 282 and also facilitates drainage.
- the first preset direction is a direction that forms a first preset angle with the top surface and slopes obliquely downward along the preset surface toward the opening 170 .
- the size of the first preset angle can be selected according to needs.
- the first preset angle can be an angle less than or equal to 7°, the drainage effect and the wind guiding effect can meet the requirements, and the height direction of the air duct assembly 200 can also be reduced Reduce the space in the height direction of the cabinet body 400 occupied by the air duct assembly 200, which helps to increase the compartment space in the cabinet body 400, so as to provide large-capacity refrigeration equipment.
- the first preset included angle is set to 3°. 3° can meet the drainage requirements of the drainage board 100 and can sufficiently reduce the height of the drainage board 100 to realize drainage at a small angle.
- the first preset included angle can also be set to 1°, 2°, 4°, 5°, 6° or 7°.
- the depth of the depression of the second water guiding part can also be kept constant (not shown in the figure), and the depth of the depression of the second water guiding part remains the same, which can also play the role of guiding wind and draining water.
- the water guiding part includes a flow guiding surface arranged along the extending direction of the water guiding part, and the direction from the top surface to the bottom surface of the drainage board 100, the flow guiding surface is close to its opposite side. That is to say, the second water guide part 130 is provided with a third guide surface 131 along its extending direction. From the top surface of the drainage plate 100 to the bottom surface, the third guide surface 131 approaches the opposite side, and the third guide surface 131 It is a slope inclined to its opposite side.
- the defrosting water received by the top surface of the drainage board 100 and the third defrosting surface 131 can fall into the bottom of the water guiding part along the guiding direction of the third deflecting surface 131, so that the defrosting water gathers in the water guiding part, so that The water in the water guide is discharged.
- the opposite side of the third flow guiding surface 131 can be a vertical surface, or also a flow guiding surface, which can be selected according to needs. As shown in FIG. 5 and FIG. 6 , the two opposite sides of the second water guide part 130 are third guide surfaces 131 .
- a plurality of second water guides 130 are arranged on each side of the preset surface of the drainage board 100, and the plurality of second water guides 130 are arranged side by side, forming A plurality of openings 170 , so that part of the air from the first air inlet 201 can enter the first cavity 282 along the plurality of openings 170 .
- the width of the second water guiding part 130 gradually decreases toward the direction of the opening 170 , so that the water received in the second water guiding part 130 can collect toward the direction of the opening 170 .
- the drainage plate 100 having the above-mentioned second water guiding portion 130 may not be provided with the drainage portion 110 .
- the embodiment of the present disclosure provides another drainage board 100 .
- the drainage board 100 is configured with a water guide part that is concave relative to the top surface of the drainage board 100 .
- the water guide part The extension direction of the drain board 100 forms a fourth included angle with the wind outlet direction above the drain plate 100.
- the wind enters the first cavity 282 from the air inlet of the air duct assembly 200 and flows toward the direction of the air outlet.
- the wind in a cavity 282 will flow in the space between the drainage plate 100 and the evaporator 230 and the space inside the evaporator 230 .
- the water guide part forms a fourth angle with the air outlet direction, which can prevent the wind from directly flowing from the water guide part to the air outlet, so as to prolong the wind flow in the first cavity 282.
- the residence time is so that the wind can fully contact with the evaporator 230 and perform heat exchange, and the heat-exchanged wind is then discharged from the air outlet, which helps to improve the heat exchange efficiency.
- the air outlet direction is the direction from the air inlet to the air outlet.
- there is only one air inlet and the air outlet which is a one-to-one correspondence relationship, forming an air outlet direction; in some cases, the air inlet or the exhaust outlet
- At least one of the tuyeres is provided in multiples to form multiple air outlet directions.
- the extension direction of the water guide part forms an included angle with at least one air outlet direction, which can ensure the heat exchange efficiency of the wind in one direction; of course, the extension direction of the water guide part forms an included angle with all the air outlet directions, then it can It is ensured that the wind in multiple flow paths can exchange heat effectively, and the heat exchange efficiency can be guaranteed.
- the air inlet is generally arranged at the front end of the air duct assembly 200
- the air exhaust outlet is generally arranged at the rear end of the air duct assembly 200, so the air outlet direction can be from front to back.
- the second air inlet 202 is arranged in front of the air duct assembly 200, the air outlet is arranged in the rear of the air duct assembly 200, the second air inlet 202 and the exhaust
- the communication path of the air outlet forms the first air outlet direction, and the second air inlet 202 corresponds to the lower position of the evaporator 230, so the air flows in the direction from bottom to top and from front to back.
- the extending direction of the water guiding part forms an included angle with the first air outlet direction, that is, the extending direction of the water guiding part forms an included angle with the front-rear direction.
- the first air inlet 201 can be arranged on at least one of the left and right sides of the air duct assembly 200, the communication path between the first air inlet 201 and the air outlet forms the second air outlet direction, and the extension direction of the water guide part is in line with the second outlet.
- the wind direction also forms an included angle.
- the angle formed by the extension direction of the water guide part and the first air outlet direction, and the angle formed by the extension direction of the water guide part and the second air outlet direction, can be understood as the fourth included angle, but the specific angle values can be the same or different.
- the extending direction of the water guiding part can be a straight path or a curved path.
- the extension path of the water guide part is a straight line path
- the path from one end of the water guide part away from the drain part 110 to the other end of the water guide part connected to the drain part 110 is an extension path;
- the extension path of the water guide part is a curved path
- the curved path The water guide part can have a plurality of ends communicating with the drainage part 110, and the curved path can be a broken line path formed by connecting multiple straight paths, or the curved path can be a curve with one or more radii of curvature, and the shape of the curved path can be Set as desired.
- the extension direction of a water guiding part may form one or more included angles with the wind outlet direction, that is, the fourth included angle may be one or more angle values, which can be specifically set according to needs.
- the embodiment of the present disclosure provides another drainage board 100.
- the drainage board 100 is configured with a drainage part 110 and a water guide part.
- the drainage part 110 is configured with an outlet 114.
- the drainage part 110 is relatively
- the top surface of 100 is concave; the water guiding part communicates with the drainage part 110, the water guiding part is concave relative to the top surface of the drainage plate 100, and the extending direction of the water guiding part forms a fifth included angle ⁇ 1 with the air outlet direction above the drainage plate 100.
- the drain board 100 is arranged under the evaporator 230 to receive the defrosting water generated when the frost on the surface of the evaporator 230 is heated.
- Part of the water falls into the water guide part and is introduced into the drainage part 110 along the extending direction of the water guide part.
- there are multiple water guide parts and the water received by each water guide part is collected into the drain part 110 and discharged through the outlet 114 of the drain part 110. .
- Another part of the water directly falls into the drain part 110 and is discharged through the drain part 110 .
- the difference between the fifth included angle and the fourth included angle is that, in a drainage plate provided with a water guiding part and a draining part at the same time, the angle formed by the extending direction of the water guiding part and the wind outlet direction is the fifth included angle; In the drainage plate provided with the water guiding part, the included angle formed by the extending direction of the water guiding part and the air outlet direction is the fourth included angle.
- Angle values of the fifth included angle and the fourth included angle can be selected according to needs, and are not limited here.
- the solid line arrow above the drainage board 100 indicates the extension direction of the water guiding part
- the dotted line arrow indicates the air outlet direction
- the fifth included angle ⁇ 1 The figure shows the situation where the fifth included angle is 90°.
- both the water guiding part and the drainage part 110 are recessed based on the top surface of the drainage board 100, the top surface can be a plane or a curved surface, and the top surface can be a surface defined by a plurality of lines, or a surface defined by a plurality of surfaces .
- the bottom of the water guide part and the bottom of the drainage part 110 form the bottom surface of the drainage board 100, which can also be a plane or a curved surface, and the bottom surface can be a surface defined by a plurality of lines, or a surface defined by a plurality of surfaces .
- the upper surface of the drainage board 100 is the entire surface of the drainage board 100 facing upward, and the top surface is a part of the upper surface; the lower surface of the drainage board 100 is the entire surface of the drainage board 100 facing downward, and the bottom surface is a part of the lower surface.
- the water guide part cooperates with the drain part 110 to discharge the received water and solve the problem of drainage in the air duct assembly 200.
- the air outlet direction forms an included angle, which can prolong the stay time of the wind in the air duct assembly 200, that is, prolong the heat exchange time, so as to improve the heat exchange efficiency and meet the cooling demand of the refrigeration equipment; and the structure of the drain plate 100 is simple.
- the drainage board 100 when the depth of the water guiding part is sunken downward relative to the top surface of the drainage board 100 , and the drainage board 100 is configured with a drainage part 110 that is sunken relative to the top surface of the drainage board 100 , then
- the water guide part can be referred to as the third water guide part 140, as shown in Figure 11 to Figure 13, the drain part 110 is configured with an outlet 114, the third water guide part 140 communicates with the drain part 110, and the third water guide part 140 undertakes
- the defrosted water can be discharged from the opening 170 at the end of the drainage plate 100, and can also be discharged from the outlet 114 of the drainage part 110, realizing multi-directional drainage, simple structure and good drainage effect.
- the evaporator 230 and the drain plate 100 can be placed horizontally, so that the defrosting water can be discharged and the height of the air duct assembly 200 can be reduced. If the evaporator 230 and the drain board 100 are both arranged obliquely downward for drainage, the downward slope angle between the evaporator 230 and the drain board 100 can be reduced (the downward slope angle between the evaporator 230 and the drain board 100 can be less than or equal to 7° ), and then reduce the size of the air duct assembly 200 in the height direction, which can play a role in expanding the internal capacity of the refrigeration equipment.
- the outlet 114 of the drainage part 110 and the air outlet are located on the same side of the first cavity 282 , and the drainage part and the exhaust part are located on the same side of the first cavity 282 , which facilitates the integration of the drainage structure and the exhaust structure.
- the fan 270 and the air outlet are located on the same side, that is, the outlet 114, the air outlet and the fan 270 are all located on the same side, and the defrosting water of the fan 270 can follow the defrosting of the drain plate 100. Frost water is discharged together.
- a plurality of third water guiding parts 140 are arranged side by side on both sides of the drainage part 110, and the plurality of third water guiding parts 140 are distributed below the evaporator 230, so that the plurality of water guiding parts 140 below the evaporator 230 One position accepts defrosting water, which helps to drain water quickly.
- Multiple drains 110 can also be provided, and multiple drains 110 can be parallel or form an included angle. Under the condition that the area of the drainage board 100 is constant, the more the number of drainage parts 110 is, the shorter the length of the third water guiding part 140 is, which helps the water received by the third water guiding part 140 to collect in the drainage part 110, In order to shorten the defrost drainage time.
- the third water guide part 140 near the edge of the drain plate has an opening, and the other third water guide parts 140 communicate with the drain part 110 .
- the bottom of the drainage portion 110 is inclined along the second direction, and the second direction forms a seventh angle ⁇ 3 with the top surface of the drainage plate 100 . That is, the bottom of the drainage part 110 is inclined, and the water in the drainage part 110 gathers to the outlet 114 along the inclined path (second direction) and is discharged.
- the drainage effect is good, and the problem of local water accumulation can be avoided; and the water can flow smoothly.
- the second direction forms a seventh angle ⁇ 3 with the horizontal plane.
- the drain portion 110 is gradually recessed downwards.
- the seventh included angle ⁇ 3 is the included angle between the bottom of the drainage part 110 and the horizontal plane, and the second direction is an obliquely downward direction.
- the bottom of the drainage part 110 can be a slanted line or a slope.
- the bottom of the drainage part 110 is a slope, and the slope can be a plane or a curved surface, which can be selected according to needs.
- the bottom of the drainage part 110 does not form a continuous slope or slope, such as a stepped shape, which can still meet the drainage requirements.
- the seventh included angle ⁇ 3 can be less than or equal to 7°, and the seventh included angle ⁇ 3 is small, which helps to reduce the distance between the top surface and the bottom surface of the drainage board 100, and can realize small-angle drainage, thereby reducing
- the size of the air duct assembly 200 in the height direction reduces the space occupied by the air duct assembly 200, which helps to increase the storage space of the refrigeration equipment and provides a large-capacity refrigeration equipment.
- the seventh included angle ⁇ 3 can also be greater than 7°. Since the area of the drainage board 100 occupied by the drainage part 110 is small, the angle at which the drainage part 110 inclines downward is slightly larger, which has little effect on the overall volume of the drainage board 100. Therefore, the angle of the seventh included angle ⁇ 3 is not strictly limited.
- the depth of the drainage portion 110 remains the same.
- the drainage portion can be called the third drainage portion 115 , and the drainage plate 100 is inclined toward the outlet 114 to facilitate drainage. If the outlet 114 is located at the rear end of the air duct assembly 200 , the drain plate 100 is inclined downward from front to rear, so that the water in the drain portion 110 flows backward and is discharged.
- the third water guiding part 140 includes a fourth guide surface 141 arranged along the extending direction of the third water guiding part 140. From the top of the drainage board 100 to the bottom surface, the fourth guide surface 141 approaches to its opposite side. The fourth defrosting surface 141 can guide the defrosting water received by the top surface of the drainage board 100 and the fourth defrosting surface 141 to the bottom of the third water guiding part 140 so that the water in the third water guiding part 140 can be discharged.
- the fourth guide surface 141 is inclined toward the outlet 114 .
- the third water guiding part 140 has a large amount of water collected, and the fourth water guiding surface 141 can guide the water backward to guide a part of the water to be discharged from the rear.
- the depth of the depression of the water guide part gradually increases, and the water guide part can be called the first water guide part 120 at this time.
- the depth of the first water guiding part 120 gradually increases toward the drain part 110 , so that water flows to the drain part 110 under the action of gravity and is discharged from the outlet 114 of the drain part 110 .
- the bottom of the first water guiding part 120 is inclined along a first direction, and the first direction forms a sixth angle ⁇ 2 with the top surface of the drainage board 100 . That is to say, the bottom of the first water guiding part 120 is inclined, and the water in the first water guiding part 120 gathers to the drainage part 110 along the inclined path (first direction), the drainage effect is good, and the problem of local water accumulation can be avoided; and the water Can flow smoothly.
- the first direction forms a sixth angle ⁇ 2 with the horizontal plane.
- the first water guiding portion 120 is gradually recessed downward from an end away from the drainage portion 110 to a position communicating with the drainage portion 110 .
- the sixth included angle ⁇ 2 is the included angle between the bottom of the first water guiding part 120 and the horizontal plane, and the first direction is an obliquely downward direction.
- the bottom of the first water guiding part 120 can be a slanted line or a slope.
- the bottom of the first water guiding part 120 is a slope, and the slope can be a plane or a curved surface, which can be selected according to needs.
- the bottom of the first water guiding part 120 does not form a continuous slope or slope, such as a stepped shape, which can still meet the water guiding requirements.
- the sixth included angle ⁇ 2 is less than or equal to 7°, and the sixth included angle ⁇ 2 is small, which helps to reduce the distance between the top surface and the bottom surface of the drainage board 100, and can realize drainage at a small angle, thereby reducing wind.
- the size of the duct assembly 200 in the height direction reduces the space occupied by the air duct assembly 200, which helps to improve the storage space of the refrigeration equipment and provides a large-capacity refrigeration equipment.
- the sixth included angle ⁇ 2 is set to 3°, 3° can meet the drainage requirements of the drainage board 100, and can fully reduce the height of the drainage board 100 to realize small-angle drainage.
- the sixth included angle may also be 1°, 2°, 4°, 5° or 6°.
- the difference between the first water guiding part 120 and the above-mentioned third water guiding part 140 is that the first water guiding part 120 is inclined toward the drainage part 110 in the drainage board 100 , and the third water guiding part 140 is inclined toward the drainage part 100 .
- the end of the slant is different, that is, the inclination direction is different, and other structures and parameters can be set to be the same, such as the inclination angle can be the same.
- the bottom surfaces of the corresponding drainage boards 100 are coplanar with multiple water guiding parts arranged side by side on the same side of the drainage part 110, so that the flatness of the bottom surface of the drainage board 100 is better, the appearance of the drainage board 100 is simple, and Easy to locate and install.
- the juxtaposition here can be understood as that, on one side of the extending direction of the drainage part 110 , a plurality of water guiding parts are arranged in sequence. Generally, a plurality of water guides are arranged side by side on both sides of the drainage part 110 , that is, the drainage part 110 is arranged between two rows of water guides. Of course, when the drain portion 110 is disposed at the end of the drain plate 100 , the water guiding portion is only disposed on one side of the drain portion 110 .
- extension direction of the water guide part is perpendicular to the wind outlet direction, which effectively prolongs the time for the wind to stay in the first cavity 282 to fully exchange heat.
- extension direction of the drainage part 110 forms an eighth included angle with the wind outlet direction, so as to minimize the discharge of wind along the extension direction of the drainage part 110, and also prolong the time that the wind stays in the first cavity 282, ensuring that the wind is replaced. heat effect.
- the drainage part 110 can also extend along the air outlet direction, and the water guide parts can be arranged symmetrically on both sides of the drain part 110, so that the water guide parts on both sides of the drain part 110 can conduct water evenly and stably.
- the water guide part is perpendicular to the wind outlet direction, so as to minimize the wind entering the water guide part.
- the depth of the depression of the drainage part 110 is greater than or equal to the depth of the depression of the water guide part. That is, the minimum depth of the drainage part 110 needs to be greater than or equal to the maximum depth of the water guide part, so that the water in the water guide part can converge to the drain part 110 to avoid water accumulation in the water guide part.
- both sides of the drainage part 110 form a wave-shaped structure, so as to reduce the area of the top surface of the drainage board 100 as much as possible, reduce the water accumulation on the top surface of the drainage board 100, and make the drainage board 100
- the received water is discharged from the outlet 114 along the water guiding part and the drain part 110 as soon as possible.
- At least two drainage parts 110 are provided, and two or more drainage parts 110 have two or more outlets 114, so as to realize drainage in multiple positions and facilitate drainage.
- the water on the plate 100 drains off quickly. Under the condition that the area of the drainage plate 100 remains unchanged, the number of the drainage parts 110 increases, and the length of the water guide part can be shortened, so that the water can enter the drainage part 110 as soon as possible.
- Adjacent drains 110 are the first drains 111 and the second drains 112, between the first drains 111 and the second drains 112 are constructed a first water guide area 123 on one side of the first drains 111 and The second water guide area 124 located on one side of the second drain part 112 faces the direction of the first drain part 111 , and the depth of the depression of the water guide part of the first water guide area 123 gradually increases toward the direction of the second drain part 112 . direction, the depth of the depression of the water guiding part of the second water guiding area 124 gradually increases.
- the recessed depth of the water guiding part is the smallest, which helps the water received by the first water guiding area 123 to be introduced into the first drainage part 111, and the second water guiding area
- the water received by the water area 124 is introduced into the second drainage part 112 , and the length of the water guiding part is shortened so that the water can be collected into the drainage part 110 .
- one drainage unit 110 can also be provided.
- the outlet 114 of the drainage unit 110 should avoid the inlet of the fan 270 as much as possible.
- Both sides of the drainage part 110 are provided with a plurality of parallel water guiding parts, which helps to shorten the water guiding path of the water guiding parts, so as to speed up the discharge of water.
- the drainage part 110 extends from the front to the rear, the outlet 114 is arranged at the rear end of the drainage plate 100, and the water guide part extends along the left and right direction, and the drainage part 110
- the left and right sides of the evaporator form a wave-shaped structure, and the setting of the wave plate can facilitate the water to gather and discharge.
- the evaporator 230 does not need to be arranged obliquely downward along the front-to-back direction.
- the water guide part and the top surface of the drainage board 100 form an included angle less than 7°, that is, the water guide part extending obliquely is formed in the left and right direction of the drainage board 100, and the inclination angle of the water guide part does not affect the angle of the drainage board 100 in the front and rear direction.
- the drainage part 110 extends from front to back, and the drainage part 110 forms a seventh included angle ⁇ 3 with the horizontal plane from front to back. The seventh included angle ⁇ 3 will affect the height change of the drainage board 100 in the front and rear direction.
- the local position of the board 100, the area of the drainage board 100 occupied by the drainage part 110 is small, and the local position of the drainage board 100 has a slightly larger inclination angle, which has little impact on the overall storage space in the compartment and can also optimize the volume of the compartment.
- the water guide part can be at least one of the above-mentioned first water guide part 120 and the third water guide part 140, that is, the drainage board 100 can be configured with the above-mentioned drain part 110 and the above-mentioned first water guide part. At least one of the part 120 and the third water guide part 140, the structure of the drainage plate 100 is various.
- the first water guide part 120 includes a first guide surface 121 arranged along the extending direction of the first water guide part 120 , and the direction from the top of the drainage board 100 to the bottom surface , the first flow guide surface 121 approaches its opposite side, that is, the longitudinal section of the first water guide part 120 converges from top to bottom, so that the water falling on the first flow guide surface 121 and the top surface can be collected to The bottom of the first water guiding part 120 is collected to the drain part 110 along the first water guiding part 120 .
- first water guiding surface 121 Among the side surfaces on both sides of the first water guiding part 120 along its extending direction, at least one side is configured as a first water guiding surface 121 .
- the shape of the longitudinal section of the first water guiding part 120 may be an inverted triangle or an inverted trapezoid. Referring to FIG. 24 and FIG. 25 , both sides of the extending direction of the first water guiding part 120 are first water guiding surfaces 121 , and both sides of the first water guiding part 120 can guide water.
- the drainage part 110 includes a second guide surface 113 arranged along the extending direction of the drainage part 110 , and the direction from the top of the drainage board 100 to the bottom surface, the second guide surface 113 Close to its opposite side, so that the vertical section of the drainage part 110 is gathered from top to bottom, and the water falling on the second guide surface 113 and the top surface can be collected to the bottom of the drainage part 110, and then discharged from the outlet 114.
- At least one of the two sides of the drainage portion 110 along the extending direction thereof is configured as the second guide surface 113 .
- the shape of the longitudinal section of the drainage part 110 may be an inverted triangle or an inverted trapezoid. Referring to FIG. 25 , both side surfaces in the extending direction of the drainage part 110 are the second diversion surfaces 113 , and both sides of the drainage part 110 can be guided.
- the first water guide part 120 is provided with a first guide surface 121
- the drain part 110 is provided with a second guide surface 113, so as to fully guide the flow, so that the water received by the drain board 100 can flow from the outlet 114 as soon as possible. discharge.
- the first flow guide surface 121 and the second flow guide surface 113 can be flat or curved, which can be selected according to actual needs.
- the width of the water guiding part gradually decreases toward the drainage part 110 . It can also be understood that, towards the direction of the drainage part 110 , the water guiding part is in a state of gradually retracting, so that the water in the water guiding part converges, which helps the water in the water guiding part to enter the drainage part 110 .
- the first preset section here can be understood as a section parallel to the top surface of the drainage board 100 , and a horizontal section of the drainage board 100 in an installed state.
- the width of the water guiding part can be understood as the distance between the two side walls in the extending direction of the water guiding part, taking the first water guiding part 120 as an example, it can be understood as the distance between the two first water guiding surfaces 121 .
- Gradual reduction is generally continuous reduction, but step reduction is not excluded.
- the width of the drain portion 110 increases toward the outlet 114 .
- the defrosting water received by multiple water guiding parts converges towards the drain part 110.
- the outlet 114 of the drain part 110 has the largest amount of water, and the width of the drain part 110 increases to provide a larger drainage space and help the water to discharge stably.
- the second preset section here can be understood as a section parallel to the top surface of the drainage board 100 , and a horizontal section of the drainage board 100 in an installed state.
- the width of the drain portion 110 can be understood as the distance between two side walls in the extending direction of the drain portion 110 , that is, the distance between the two second guide surfaces 113 .
- the increase is generally a gradual increase, but a step increase is not excluded.
- the first preset section is parallel to the second preset section, and may also be coplanar.
- the edge of the drainage board 100 is folded up to form a flange 150 , and the flange 150 surrounds the drainage board 100 and slots at a position corresponding to the outlet 114 .
- the flange 150 serves to prevent the water on the upper surface of the drainage board 100 from overflowing, so that the water on the upper surface of the drainage board 100 is discharged along the outlet 114, thereby ensuring that the water in the air duct assembly 200 is discharged from the outlet.
- the partial position of the flange 150 extends upwards to form a positioning part 151, and the two adjacent positioning parts 151 are used to limit the first heater 231 above the drainage board 100.
- the fixing method of the first heater 231 is simple, and the drainage board 100 Simple structure.
- the outline shape of the drainage board 100 is related to the shapes of the evaporator 230 and the air duct assembly 200, and the shape of the drainage board 100 is not limited.
- the outline shape of the drainage board 100 may be a rectangle, a trapezoidal circle or other shapes.
- the upper surface and the lower surface of the drainage board 100 have the same shape.
- the drain plate 100 in the above embodiment is applied in the air duct assembly 200, that is, the drain plate 100 is arranged under the evaporator 230, and the evaporator 230 does not need to slope downward from the front to the rear, which solves the problem that the evaporator 230 has The problem that the inclination angle will lose the internal volume of the compartment, while ensuring the heat exchange efficiency in the air duct assembly 200, realizes defrosting and drainage at a small angle, and reduces the height difference of the air duct assembly 200, which contributes to the internal volume of the compartment. maximize.
- the evaporator 230 can also be slightly inclined downward, but even if the evaporator 230 is not inclined downward, the drainage effect will not be affected.
- the drain board 100 is also connected with a vibrator (not shown in the figure), and the vibrator provides vibration force according to defrosting requirements.
- the opening and closing of the vibrator is closely related to the timing of defrosting.
- the vibrator can be launched synchronously with the defrosting work, or it can be delayed appropriately compared with the defrosting work.
- the vibrator can be any one of an eccentric motor, an ultrasonic vibrator or an electromagnetic vibrator.
- the air duct assembly 200 also includes a first drainage component 260 , the first drainage component 260 communicates with the opening 170 of the drainage plate 100 in the first cavity 282 , and the first drainage component 260 and the fan 270 are located On different sides of the drainage board 100 (such as adjacent two sides), the first drainage member 260 can be understood as a side drainage structure.
- the first drainage component 260 is provided with a first drainage port 262 , and the first drainage port 262 communicates with the drainage pipeline (the drainage pipeline is the first drainage pipe 263 ) to discharge the water received by the drainage board 100 .
- the first drainage member 260 is configured with a drainage channel, the cross-sectional area of the drainage channel gradually decreases from top to bottom, which can ensure the drainage of the opening 170 in an all-round way, and can also converge the drainage to the first drainage port 262 .
- the first drain member 260 covers all the openings 170 of the drain plate 100 as far as possible to ensure that the joints of the first drain member 260, the air duct member 220 and the partition member 210 are sealed to avoid air leakage and The case of water leakage. As shown in FIG. 5 and FIG. 7 , some openings 170 do not correspond to the first drainage member 260 , which is to illustrate the position of the opening 170 . In practical applications, the first drainage member 260 covers all the openings 170 .
- the first drainage member 260 is configured with a through hole communicating with the opening 170, and the area of the through hole covers all the openings 170, so as to ensure the drainage effect and the sealing effect, and avoid water leakage.
- the first drainage component 260 is provided with at least one air inlet, that is, the first drainage component 260 is provided with at least one of the first air inlet 201 and the second air inlet 202 .
- the first air inlet 201 is provided with the first drainage member 260 as an example for illustration.
- the first air inlet 201 passes through the inside of the first drainage member 260 and communicates with the first cavity 282 .
- the return air of the first chamber 410 is realized.
- the first air inlet 201 communicates with the first chamber 410 through the return air component 430 for return air.
- the first drainage component 260 includes a first wall plate 264 and a second wall plate 265 oppositely disposed, the first wall plate 264 is configured with a through hole, and the second wall plate 265 is configured with a first air inlet 201 .
- the first wall plate 264 faces the drain plate 100
- the second wall plate 265 faces the cabinet body 400 .
- the first wall plate 264 and the second wall plate 265 can be detachably connected or integrally formed.
- the first drainage component 260 is configured as an integral structure to avoid leakage at the connection.
- the partition member 210 is installed above the air channel member 220, and the partition member 210 is provided with the first air inlet, so that the first The air return component 430 of the compartment 410 enters the first cavity 282 through the first air inlet 201 .
- the opening 170 of the drainage plate 100 faces the first side of the first cavity 282 , the second cavity 281 is located on the second side of the first cavity 282 , and the second cavity 281 is provided with
- the first side of the first cavity 282 is adjacent to the second side.
- the first side of the first cavity 282 can be understood as at least one of the left side and the right side, and the second side of the second cavity 281 can be understood as the rear side.
- the water outlet direction of the drainage board 100 is different from the air outlet direction of the first cavity 282, which can reduce the water vapor carried in the wind, reduce the impact of drainage on the fan 270, and reduce the amount of frosting on the fan 270.
- the opening 170 of the drain plate 100 faces at least one of the left side and the right side.
- the drainage board 100 includes a second water guide part 130 , the second water guide part 130 is recessed relative to the top surface of the drainage board 100 , and the extension direction of the second water guide part 130 is in line with the top surface of the drainage board 100 .
- the air outlet direction of the second water guide part 130 forms an included angle, and the depth of the second water guide part 130 is gradually increased along the preset direction facing the first side of the second cavity body 281, and the second water guide part 130 faces the first side of the second cavity body 281.
- One end is configured with an opening 170, and the water received by the second water guiding part 130 is discharged from the opening 170 along the extending direction of the water guiding part.
- Port 262 exits.
- the structure of the drainage board 100 is simple, and the drainage effect is good. Moreover, the return air of the first room 410 enters the first cavity 282 through the first air inlet 201, and the wind enters the first cavity 282 from the left or right side, and can flow along the second water guiding part 130; The return air of the chamber 420 enters the first cavity 282 through the second air inlet 202 , and the wind enters the first cavity 282 from the front side of the air duct assembly 200 , then the return air of the first compartment 410 and the return air of the second compartment 420 The return air enters the first cavity 282 through different paths, the contact between the two return air is reduced, and the amount of frosting caused by the contact between the two return air is also reduced.
- the air outlet direction above the drainage board 100 is from front to rear, and the extension direction of the second water guide part 130 is the left and right direction, so the gap between the extension direction of the second water guide part 130 and the air outlet direction above the drainage board 100
- the angle is 90°, the second water guiding part 130 can slow down the flow velocity of the wind in the first cavity 282, prolong the time that the wind stays in the first cavity 282, and optimize the heat exchange effect.
- the drainage board 100 includes a second water guide part 130 extending from the preset position to the left and a second water guide part 130 extending from the preset position to the right.
- the opening 170 and the left and right sides of the air duct assembly 200 are provided with first drainage components 260 , which have a simple structure and good water guiding effect.
- the preset position may be a symmetrical plane of the drainage board 100 , or a longitudinal plane extending along the front-to-back direction.
- the predetermined surface can be the end surface of the above-mentioned drainage part, and the predetermined surface of the second water guiding part extending to the left and right sides of the drainage plate can be the same longitudinal surface or different longitudinal surfaces.
- the drainage plate 100 provided in the air channel assembly 200 is configured with a third water guide 140, and the opening 170 of the third water guide 140 is connected with the first drainage member. 260 connectivity.
- the above drainage method can be understood as side drainage. Since the fan 270 is arranged behind the air duct assembly 200, at this time, the evaporator 230 and the fan 270 drain water independently, and the defrosting water of the evaporator 230 is discharged from the left and right sides through the first drainage member 260, and the defrosting water flowing in the direction of the fan Water and water condensed when encountering the fan 270 can be discharged through the structure below the fan 270 , the structure below the fan 270 can be the following drainage structure, or other structures that can discharge the water in the second cavity 281 .
- the fan cover 240 is configured with a vent 244 , and the second cavity 281 communicates with the first cavity 282 through the vent 244 .
- both the fan cover 240 and the fan 270 are disposed on the rear side of the air duct assembly 200, and the second drainage component 290 is located on the side where the fan is located, and the second drainage component 290 provides a rear drainage method.
- the fan cover 240 is provided with a second drainage component 290 , and the second drainage component 290 is disposed inside the fan cover 240 , or, the second drainage component 290 is disposed below the outside of the fan cover 240 .
- the space in the fan cover 240 can be fully utilized to reduce the height of the air duct assembly 200 and expand the capacity of the refrigeration equipment.
- a fan cover 240 is provided on the side where the outlet 114 of the drain plate 100 is located, and the end of the fan cover 240 facing the drain plate 100 communicates with the outlet 114 of the drain plate 100 .
- the fan cover 240 includes a first cover body 241 and a second cover body 242 located below the first cover body 241 , and the fan 270 is disposed above the second cover body 242 .
- the second cover body 242 is provided with a third drain port 2423 , and the water discharged from the outlet 114 of the drain plate 100 is diverted to the third drain port 2423 along the second cover body 242 .
- the second cover 242 can receive the water from the drainage board 100, the water dripped from the first cover 241, and the water dropped from the fan 270, and lead out the defrosting water from the first cavity 282, which helps to simplify the air duct Structure of assembly 200 .
- the drainage board 100 may adopt a structure having a drainage portion 110 , and details may refer to the above-mentioned embodiment of the drainage board 100 .
- the outlet 114 of the drainage board 100 faces to the rear, and the second cover body 242 is located at the rear of the drainage board 100 .
- the second cover body 242 can provide a rear drainage structure.
- the second drainage part 290 constructs a first water guide channel 2421 communicating with the outlet 114 of the drainage board 100.
- the second drainage part 290 includes a barrier part 2422 protruding upward along the surface of the second cover body 242.
- the barrier part 2422 The first water guide channel 2421 is limited, and the fan 270 is located on one side of the barrier part 2422 .
- the blocking part 2422 functions to separate the first water guiding channel 2421 from the fan 270 , prevents water from flowing to the fan 270 , and reduces the impact of water on the fan 270 .
- the first water guiding channel 2421 In the direction away from the outlet 114 of the drain plate 100 , the first water guiding channel 2421 is inclined downward so that the water in the first water guiding channel 2421 is guided downwards, and the structure is simple and the drainage effect is good.
- the end of the first water guiding channel 2421 forms a third drain port 2423, and the third drain port 2423 is connected with a drain pipe through which water is discharged into the press chamber.
- the barrier part 2422 can be a plate-shaped structure or a block-shaped structure in which the second cover body 242 protrudes upwards, which can be selected according to needs.
- the barrier part 2422 can also be a part detachably connected to the second cover body 242, such as a plate structure plugged or clamped to the second cover body 242.
- the structure of the barrier part 2422 is not limited to this, other can realize The structure of the barrier function is also acceptable.
- a partition plate 2427 is provided between the drain plate 100 and the second cover body 242.
- the partition plate 2427 makes the drain plate 100 and the second cover body 242 communicate only at the outlet 114, and other parts pass through the partition plate 2427. The separation is performed to ensure that the first cavity 282 communicates with the second cavity 281 at the vent 244 and the outlet 114 , and other parts are separated.
- the partition plate 2427 can be integrally formed with the second cover body 242 or be detachably connected.
- the second cover body 242 and the drainage board 100 can be two independent parts, or the second cover body 242 and the drainage board 100 are integrally formed as an integral part.
- the inside of the above-mentioned fan cover 240 is provided with a first air guide part 2424 and a second air guide part 2425, and the first air guide part 2424 and the second air guide part 2425 are matched with the fan 270 to the first air outlet 203 and the second row.
- the air outlet 204 guides the air to ensure that the air flows out from the corresponding path.
- the second cover body 242 is provided with a first air guiding portion 2424 and a second air guiding portion 2425 .
- the fan 270 is installed on the upper surface of the second cover body 242 through the fan mounting base 271.
- the upper surface of the second cover body 242 is provided with a plurality of second mounting columns 2426, and the fan mounting base 271 is fixed on the second mounting column 2426.
- the upper surface of the second cover body 242 is inclined downward, so that the defrosted water on the surface of the second cover body 242 can flow toward the first water discharge port under the action of gravity.
- the direction of the three water outlets 2423 flows.
- the second cover body 242 is configured with a water collection part 2428, the water collection part 2428 is located on the side of the second cover body 242 facing the third drain port 2423, and the surface area of the water collection part 2428 gradually decreases toward the third drain port 2423
- the third drain port 2423 is connected, and the water collected by the water collecting part 2428 can be discharged through the third drain port 2423 .
- the surface area of the water collecting part 2428 gradually decreases toward the third drain port 2423 , that is, the water collecting part 2428 converges toward the third drain port 2423 , so that the defrosting water received by the second cover 242 is collected and discharged.
- the water collecting part 2428 can also be inclined downward, and the drainage effect is better.
- the second cover body 242 is provided with a heating component 226 , and the heating component 226 heats and defrosts the fan cover 240 and the fan 270 and other components inside by heating the second cover body 242 .
- the heating element 226 can be a heating film formed on the second cover body 242, or the heating element 226 is a heating plate located under the second cover body 242, the structure of the heating element 226 is not limited to this, other can realize heating A cream structure is also possible.
- the second water guide channel communicated with the outlet 114 of the drainage plate 100.
- the second water guiding channel is separated from the second cavity 281 , that is, the second water guiding channel is separated from the fan 270 by the fan cover 240 , so as to reduce the influence of the water in the second water guiding channel on the fan 270 and other components.
- the shape of the second drainage part 290 can be set as a U-shaped structure with flanges, or the second drainage part 290 can be provided with a structure integrally formed under the second cover body 242. choose.
- multiple second drainage components 290 can be provided under the fan cover 240 , so that the second water guide channel and the fan 270 do not interfere with each other.
- the local position corresponding to the second drainage member 290 protrudes downward, so that the height of the local position of the air duct assembly 200 is relatively large, which has no effect on the height of other positions, and can also expand the refrigeration equipment. The role of capacity.
- the second water guiding channel In the direction away from the outlet 114 of the drainage board 100 , the second water guiding channel is inclined downward so that the water in the second water guiding channel is guided downwards, the structure is simple and the drainage effect is good.
- the second drainage component 290 is provided with a second drainage port, and the second drainage port is connected to the second drainage pipe 291 , and the water is discharged into the press chamber through the second drainage pipe 291 .
- the water guide channel (the first water guide channel 2421 or the second water guide channel) can also be arranged horizontally, and the size of the air duct assembly 200 in the height direction will not be increased due to the water guide channel, which helps to reduce the size of the air duct assembly 200. Height, thereby increasing the storage space of the refrigeration equipment.
- the above-mentioned fan cover 240 is provided with wiring holes, so that the electrical connection parts of the air duct assembly 200 can be routed through the wiring holes to realize electrical connection, and the structure is simple and convenient for wiring.
- the air duct part 220 supports the drainage board 100, the drainage board 100 is located below the evaporator 230, and the water guide 223 is arranged on the side where the outlet 114 of the drainage board 100 is located, and the side of the water guide 223 faces the outlet 114 and communicates with the outlet 114, and the guide
- the other side of the water component 223 is configured with a drain port, so that the water guide 223 communicates with the third drain pipe 2231 , and the water discharged from the outlet 114 of the drain board 100 flows along the water guide 223 to the third drain pipe 2231 .
- the fan 270 is disposed on one side of the evaporator 230 , the fan cover 243 is located between the fan 270 and the evaporator 230 , and the inlet of the fan 270 communicates with the first cavity 282 through the vent 244 of the fan cover 243 .
- the fan cover plate 243 is arranged on the outside of the water guide 223, the fan cover plate 243 is fixed on the tank body 300, and surrounds a cavity for installing the fan 270 between the rear wall of the tank body 300. The body communicates with the first cavity 282 through the vent 244 opened by the fan cover plate 243 .
- the fan cover 243 itself encloses a cavity for installing the fan 270 , the cavity communicates with the first cavity 282 , and the fan cover 243 is fixedly installed on the tank body 300 .
- a third cavity is defined between the fan cover plate 243 and the water guide 223 , and the wind in the first cavity 282 is guided out by the fan 270 through the third cavity.
- the water guiding member 223 can be understood as a part of the air duct part 220, or a part independent of the air duct part 220, which can be specifically selected according to needs.
- Fan cover plate 243 is the mounting part of blower fan 270, and the main function of fan cover plate 243 is similar to the main function of fan cover 240, and fan cover plate 243 or fan cover 240 are set in an air channel assembly 200, and fan cover plate 243 is connected with water guide
- the component 223 is used in combination, and the fan cover 240 is used in combination with the second drain member 290 .
- a vent 244 is opened on the fan cover 240 so that the wind in the first cavity 282 is exhausted by the fan 270 through the vent 244 .
- the fan cover plate 243 is provided with a third air guide part 2431 and a fourth air guide part 2432, and the fan cover plate 243 is provided with a first air outlet 203 and a second air outlet 204, so that the fan 270 sends the wind out of the first row.
- the air duct assembly 200 also includes a fan 270, the rotation axis of the fan 270 forms a first angle ⁇ 1 with the vertical direction, the fan cover 240 has a vent 244, and the inlet of the fan 270 faces the vent 244 , the second cavity 281 communicates with the air outlet area of the first cavity 282 through the vent 244 , and the second cavity 281 communicates with the air exhaust port of the air duct assembly 200 .
- the wind in the first cavity 282 is sucked into the second cavity 281 by the fan 270 through the vent 244 on the fan cover 240, and under the action of the fan 270, the wind in the second cavity 281 is ventilated through the exhaust port. into the first chamber 410 or the second chamber 420. That is, the second cavity 281 and the above-mentioned first air outlet 203 and the second air outlet 204 can be adjusted on and off.
- the rotation axis of the fan 270 forms a first included angle ⁇ 1 with the vertical direction. It can be understood that the front end of the rotation axis of the fan 270 is lower or higher than the rear end. In the case of meeting the ventilation and drainage requirements, the angle of the first included angle ⁇ 1 should be as small as possible, and the height difference between the front end and the rear end of the rotation axis of the fan 270 should be as large as possible, that is, the fan 270 should be set as close to the level as possible, so as to reduce the fan 270.
- the space occupied by the height direction reduces the size of the air duct assembly 200 in the height direction.
- vent 244 and the drainage outlet of the first cavity 282 are misaligned, which can minimize the wind at the drainage outlet being drawn by the fan 270, prolong the heat exchange time of the wind in the first cavity 282, and improve the heat exchange efficiency.
- the fan cover 240 is fixed on the tank body 300 , and the wind in the first cavity 282 is exported by the fan 270 through the second cavity 281 .
- the air duct assembly 200 also includes a fan cover 240, the fan cover 240 includes a first cover body 241 and a second cover body 242, the first cover body 241 is configured with a flow guide surface 2411 facing the fan 270, and the flow guide surface
- the first side of 2411 is higher than the second side of the flow guide surface 2411, the first side of the flow guide surface 2411 and the second side of the flow guide surface 2411 are opposite sides; the fan cover 240 limits the second cavity 281,
- a fan 270 is disposed in the second cavity 281 .
- the first cover 241 can play the role of converging the water vapor above the fan 270, and guide the collected water droplets from the first side of the flow guide surface 2411 to the second side of the flow guide surface 2411.
- the setting of the first cover 241 can promote the collection and discharge of water vapor in the second cavity 281, reduce the corrosion of the water vapor on the fan 270, and prolong the life of the fan 270.
- the first included angle ⁇ 1 is greater than or equal to 7°, so that the water collected on the first side of the flow guide surface 2411 can flow to the second side along the slope of its own surface, and the water can flow along the air duct component 220 below the fan 270
- the water is diverted to the third drain port 2423 to prevent the water collected on the surface of the first cover 241 from dripping into the fan 270 and prevent water from falling into the fan 270 as much as possible.
- the first side of the flow guide surface 2411 is higher than the second side of the flow guide surface 2411, and the surface of the first cover 241 facing the fan 270 can be an inclined plane or a curved surface; when the flow guide surface 2411 is a plane, it helps The structure of the first cover body 241 is simplified to facilitate processing. In addition, water accumulated on the surface of the fan 270 falls and is discharged under the force of gravity.
- the first included angle ⁇ 1 needs to be less than 70° to achieve the purpose of reducing the height; the first included angle ⁇ 1 can be smaller than 60°, 50°, 45°, 30°, 20° or 10°, the smaller the first included angle ⁇ 1 , the smaller the dimension in the height direction of the air duct assembly 200 is.
- the first included angle ⁇ 1 is less than 7°, the air exhaust requirement can be met, and the height direction dimension of the air duct assembly 200 is smaller, but the water guiding effect of the surface of the first cover body 241 facing the fan 270 is not good. The drainage effect is difficult to meet the demand. If the first included angle ⁇ 1 is less than 7°, it is necessary to solve the problem of drainage of the fan cover 240 .
- the first cavity 282 and the second cavity 281 are two cavities arranged side by side; or, the second cavity 281 is surrounded by the first cavity 282; the first cavity 282 and the second cavity
- the positional relationship of 281 is not limited thereto, as long as the communication relationship between the two cavities can be realized.
- the fan 270 can be tilted forward by the first angle ⁇ 1 or tilted by the first angle ⁇ 1 towards the rear. Referring to FIG. 14 , the fan 270 is tilted forward by the first angle An included angle ⁇ 1, as shown in FIG. 8 , the fan 270 is inclined toward the rear by the first included angle ⁇ 1. That is, relative to the vertical direction, the upper end of the rotation axis of the fan 270 is inclined forward to form a first included angle ⁇ 1, or inclined backward to form a first included angle ⁇ 1.
- the fan 270 is gradually inclined upward from front to back, that is, the inlet of the fan 270 faces the air outlet direction of the first cavity 282, which helps the wind in the first cavity 282 enter the inlet of the fan 270, and can improve the ventilation effect.
- the fan 270 is gradually inclined downward from front to back, which can improve space utilization.
- the evaporator 230 and the fan 270 can share a drainage structure to simplify the structure; or, considering that the evaporator 230 and the fan 270 use an independent drainage structure for drainage, the impact of drainage on the fan 270 can be reduced.
- the drainage of the evaporator 230 is led out from the first drainage parts 260 on the left and right sides, and the drainage of the fan 270 is discharged from the rear end.
- the rotation axis of the blower fan 270 is collinear with the central axis of the vent 244, and the suction effect of the blower fan 270 will be greatly reduced during the process of sucking the wind in the first cavity 282 into the second cavity 281 through the vent 244. Well, it contributes to the effect of wind circulation in the air duct assembly 200 .
- the shape of the vent 244 is adapted to the shape of the inlet of the fan 270 , so that the wind in the first cavity 282 is drawn into the second cavity 281 by the fan 270 through the vent 244 .
- the axis of rotation of the fan 270 is collinear with the central axis of the air vent 244, and generally the guide surface 2411 of the first cover 241 is arranged to be parallel to the fan 270, or the area of the first cover 241 corresponding to the fan 270 is set To be parallel to the blower fan 270.
- the fan 270 is generally a centrifugal fan, which can change the flow direction of the wind and send the wind to the first chamber 410 or the second chamber 420 conveniently. Of course, other fans 270 that can satisfy the circulating air supply effect are also available.
- the first cover body 241 is located above the fan 270 , the first side of the flow guide surface 2411 faces away from the drain plate 100 , and the second side of the flow guide surface 2411 faces the drain plate 100 , the first side of the flow guide surface 2411 is inclined upward by a second angle ⁇ 2 relative to the second side of the flow guide surface 2411, that is, in the direction away from the drainage board 100, the flow guide surface 2411 of the first cover 241 is inclined upward by a second angle
- the included angle ⁇ 2, that is, the vent 244 faces the air outlet direction of the first cavity 282, which helps the wind in the first cavity 282 to enter the second cavity 281, which can improve the ventilation effect, and can consider the evaporator 230 and
- the fans 270 share a drainage structure to simplify the structure. As shown in FIG. 14 to FIG. 16 and FIG. 21 , the air duct assembly 200 drains water from the second drain port or the third drain port 2423 at the rear end.
- the drainage board 100 when the drainage board 100 includes a water guiding part and a drainage part 110 , the drainage part 110 is configured with an outlet 114 , and the water received by the drainage board 100 flows along the water guiding part to the drainage part 110 and is discharged from the outlet 114 , Affected by this structure, part of the wind also flows along the water guide part and the drainage part 110 to the outlet 114, and the outlet 114 and the vent 244 are set to be misaligned, so that the wind flowing in the direction of the outlet 114 can be prevented from being directly discharged from the vent 244, Prolong the heat exchange time of the wind in the first cavity 282 as much as possible to improve the heat exchange efficiency.
- the second cavity 281 when the second cavity 281 is located behind the first cavity 282 , the direction away from the drainage board 100 is from front to back.
- the first cavity 282 and the second cavity 281 can also be arranged left and right, and the direction away from the drainage plate 100 is the left and right directions, and the working principle is consistent with the front and rear directions, so it will not be repeated here.
- the second cavity 281 is located behind the first cavity 282 as an example for illustration.
- the first cover 241 is located above the fan 270, the first side of the guide surface 2411 faces the drainage board 100, and the first side of the guide surface 2411 The second side is away from the drainage board 100, and the second side of the flow guide surface 2411 is inclined downward at a third angle ⁇ 3 relative to the first side of the flow guide surface 2411, that is, in the direction away from the drainage board 100, the first cover 241
- the flow guide surface 2411 is inclined downward at a third angle ⁇ 3, and the first cover 241 guides the water flow to the rear of the fan 270, which helps the collected water to be discharged quickly.
- the second included angle ⁇ 2 and the third included angle ⁇ 3 are set to be the same as the first included angle ⁇ 1, so that the rotation axis of the fan 270 is collinear with the central axis of the vent 244 to ensure that the air duct assembly 200 The effect of wind flow and the effect of air circulation in the refrigeration equipment.
- the drainage board 100 , the fan cover 240 , the water guide 223 and other components in the above embodiments all need to be supported and kept warm by the air duct component 220 , and the structure of the air duct assembly 200 will be described below.
- the air duct part 220 can be fixed to the tank body 300 by being fixedly connected to the partition part 210 , or the air duct part 220 is directly fixedly connected to the tank body 300 .
- the air duct part 220 includes a support plate and a second thermal insulation layer 221 located below the drain plate 100, the support plate is supported below the second thermal insulation layer 221, and the shape of the upper surface of the second thermal insulation layer 221 is the same as that of the lower surface of the drain plate 100. Adaptation, so that the second heat preservation layer 221 fully insulates the drainage board 100, reduces the outward diffusion of cold energy, and ensures heat exchange efficiency.
- the upper surface of the second insulation layer 221 is a corresponding curved surface; when the lower surface of the drainage board 100 is a plane, the upper surface of the second insulation layer 221 is a plane, Specifically, it can be set as required.
- the support plate includes a first support portion 222 and a second support portion 225 inclined downward along the first support portion 222, the second support portion 225 and the outlet 114 of the drainage plate 100 are located on the same side of the air duct assembly 200, the second A support part 222 supports the second heat preservation layer 221, a third heat insulation layer 224 is arranged above the second support part 225, a water guide 223 or a fan cover 240 are arranged above the third heat preservation layer 224, and the second support part 225 supports the third heat preservation layer.
- the thermal insulation layer 224 and the components above the third thermal insulation layer 224 (such as the water guide 223 or the fan cover 240 ) function.
- the first supporting part 222 and the second supporting part 225 are parts independent of each other, such as plates, which are installed in a detachable connection, such as plugging, clamping and fasteners; or, the first supporting part 222 and The integrally formed structure of the second supporting portion 225 can reduce the number of parts and simplify assembly.
- the water guiding element 223 and the drainage plate 100 are two independent parts.
- the water guiding element 223 and the drainage plate 100 can also be formed into an integral structure.
- the air duct part 220 may define an air inlet, so that the return air from at least one of the first compartment 410 and the second compartment 420 enters the first cavity 282 through the air inlet provided by the air duct part 220 .
- an air inlet is provided on the support plate; as shown in FIG.
- the second air inlet 202 returns air to the first cavity 282 .
- the first side of the first cavity 282 is provided with a first air inlet 201
- the second side of the first cavity 282 is provided with a second air inlet 202, which can also be understood as being perpendicular to the respective In the air inlet direction, the cross section of the first air inlet 201 and the second air inlet 202 form an included angle.
- the air entering the first air inlet 201 and the air entering the second air inlet 202 have different temperatures.
- the air duct component 220 is provided with a partition 2221, the orthographic projection of the partition 2221 at the first air inlet 201 covers a partial area of the first air inlet 201, and the orthographic projection of the partition 2221 at the first air inlet 201 is located at the first air inlet 201.
- the air inlet 201 is close to one end of the second side, and there is a preset distance a between the partition 2221 and the first air inlet 201.
- the air inlet of the first air inlet 201 flows in the direction of the partition 2221. During the wind flow, a part of the wind flows along the The extension direction of the partition 2221 guides the flow, and a part continues to flow along the air inlet direction.
- the air inlet of the first air inlet 201 and the second air inlet 202 can be reduced.
- the partition 2221 plays the role of guiding part of the air intake of the first air inlet 201 to the extending direction of the partition 2221, which can reduce
- the first air inlet 201 and the second air inlet 202 enter the air in contact with the heat exchange air volume, thereby reducing the amount of frosting at the end of the evaporator 230 near the second side due to the difference in the inlet air temperature, and avoiding the amount of frosting caused by the second side
- the large amount of frosting affects the air intake of the first chamber 282, and also solves the problem of short defrosting cycle caused by the large amount of frosting on the second side, and appropriately prolongs the defrosting cycle to save power.
- the preset distance a is the distance from the first side edge of the air duct component 220 to the partition 2221 . It should be noted that the preset distance a is set to ensure an appropriate flow space between the first air inlet 201 and the partition 2221 so that the air can flow into the first cavity 282 and prevent the partition 2221 from blocking its corresponding The position of the first air inlet 201, therefore, the value of the preset distance a is not limited, and can be selected according to needs.
- the orthographic projection can be understood as a projection at the first air inlet 201 along the air inlet direction of the first air inlet 201 .
- the air duct member 220 may be formed with a first air inlet 201 (not shown in the figure).
- An evaporator 230 is arranged in the first cavity 282, and the cooling fins 234 of the evaporator 230 extend along the direction of the second air inlet 202 to the air outlet (the direction from front to back in the drawings), so that the evaporator 230 and the second The wind at the distance between the air inlets 202 can flow toward the air outlet along the guiding direction of the cooling fins 234 .
- Partition 2221 extends along the direction of the second air inlet 202 to the air outlet, part of the air intake from the first air inlet 201 flows into the evaporator 230 along the partition 2221, and the extension direction of the partition 2221 is consistent with the cooling fin 234, then The partition part 2221 cooperates with the cooling fins 234 to direct the air toward the air outlet.
- the air duct member 220 is provided with a guide surface 2222, the guide surface 2222 is a curved surface, the partition 2221 is located at the first end of the guide surface 2222 and is tangent to the first end, the guide surface
- the second end of 2222 extends toward the first wall that limits the first air inlet 201 .
- Part of the wind entering the first cavity 282 from the first air inlet 201 can flow along the guide path of the guide surface 2222, that is, this part of the wind can flow along the curved surface of the guide surface 2222, and the flow direction of part of the wind can be changed through the guide surface 2222.
- the second end of the guide surface 2222 is perpendicular to the first wall defining the first air inlet 201 , so that the air from the first air inlet 201 flows along the guide surface 2222 toward the partition 2221 .
- the second end of the guide surface 2222 can also form an obtuse angle or an acute angle with the first wall surface, so that the incoming air can flow along the guide surface 2222, and the specific structure of the guide surface 2222 can be selected according to needs.
- the guide surface 2222 includes a planar portion 22222 and a curved portion 22221, one end of the curved portion 22221 is connected to the partition 2221, and the other end of the curved portion 22221 is connected to the planar portion 22222 and is tangent to the planar portion 22222.
- the part 22222 extends towards the direction of the first wall surface, the curved part 22221 plays the role of changing the flow direction of the wind, the flat part 22222 can guide the wind direction to the curved part 22221, the flat part 22222 cooperates with the curved part 22221, the air inlet of the first air inlet 201 The wind is smoother.
- planar portion 22222 extends to connect with the first wall. However, there may also be a distance between the planar portion 22222 and the first wall, and the specific positional relationship between the planar portion 22222 and the first wall is not limited.
- the air duct part 220 is provided with a second air inlet part, the second air inlet part forms the second air inlet port 202, both ends of the second air inlet part are provided with partitions 2221, and the first side includes a side adjacent to the second side. Both sides, that is, first air inlets 201 are provided on both sides adjacent to the second air inlet 202, through the partitions 2221 at both ends of the second air inlet, the corresponding parts of the first air inlet 201 can be respectively The wind is separated, the structure is simple, and the symmetry is good.
- the air duct part 220 is provided with a deflector 2223, the deflector 2223 connects the edge of the air duct part 220 and the partition 2221, the deflector 2223 is located below the partition 2221 and the guide surface 2222, and the deflector 2223 can play a supporting role
- the role of the partition 2221 is to keep the partition 2221 at a preset height position, to ensure the corresponding relationship between the air intake of the first air inlet 201 and the partition 2221, and at the same time, the air intake of the first air inlet 201 can also be guided along the
- the plate 2223 flows in the direction of the air outlet.
- the height of the partition 2221 is less than or equal to 1/3 of the height of the first air inlet 201, so that the partition 2221 separates the part in the height direction from entering the air, which has little influence on the air inlet effect of the first air inlet 201, and can ensure that the first air inlet 201 Air intake efficiency of the air inlet 201.
- the length of the partition 2221 is less than or equal to 1/3 of the length of the first air inlet 201, so that the partition 2221 separates the part of the length direction to enter the air, which has little influence on the air inlet effect of the first air inlet 201, and can ensure that the first air inlet 201 Air intake efficiency of the air inlet 201.
- the length of the partition 2221 is the length extending from the air duct member 220 to the evaporator 230 .
- the air duct component 220 is integrally formed with a partition 2221 , and the partition 2221 does not need to be independently processed and installed, which can simplify the assembly process of the air duct assembly 200 and save assembly time.
- the air duct component 220 can be detachably connected to the partition 2221, and the structure and shape of the partition 2221 can be selected or replaced according to actual needs, making the structure of the air duct assembly 200 more flexible and diverse.
- the air duct component 220 includes a support and an insulation layer, the support plays the role of supporting the insulation layer and its upper parts, and the support is configured with a second air inlet 202 .
- the partition 2221 is integrally formed or detachably connected to the support.
- the above-mentioned guide surface 2222 is also a part of the surface of the support; The case of disconnected connections.
- the above-mentioned embodiment of the partition 2221 and the embodiments of the guide surface 2222 and the deflector 2223 related to the partition 2221 can also be arranged on the partition member 210, and at least one of the partition member 210 and the air duct member 220 It has the functions mentioned above.
- the air duct member 220 can support the drainage board 100 of the above-mentioned one embodiment.
- the air duct component 220 includes a support plate and an insulation layer positioned above the support plate; the support plate includes the above-mentioned first support portion 222 and the second support portion 225, and the insulation layer includes the above-mentioned second insulation layer 221 and the third insulation layer 224, the second A second heat insulating layer 221 is disposed above a support portion 222 , and a drainage board 100 is disposed above the second heat insulating layer 221 .
- the drainage part 110 when the structure of the drainage board 100 is: including a drainage part 110 and a water guide part, the drainage part 110 is configured with an outlet 114, and the drainage part 110 is recessed relative to the top surface of the drainage board 100; It communicates with the drain part 110, the water guide part is recessed relative to the top surface of the drain board 100, the extension direction of the water guide part forms a fifth angle with the wind outlet direction above the drain board 100, and faces the direction of the drain part 110, the water guide part
- the bottom of the drain plate 100 is inclined along the first direction, and the first direction forms a sixth angle ⁇ 2 with the top surface of the drainage board 100 .
- the water guiding part here can be understood as the first water guiding part 120 in the above embodiment.
- the upper surface of the second thermal insulation layer 221 is compatible with the lower surface of the drainage board 100.
- the upper surface of the second thermal insulation layer 221 is a suitable wave-shaped surface.
- the second thermal insulation layer 221 The shape of the lower surface can be set as required.
- the lower surface is a plane extending in the horizontal direction, so that the lower surface of the air duct member 220 can also be configured as a plane extending in the horizontal direction.
- the lower surface of the air duct assembly 200 has a regular shape and a simple appearance structure.
- the lower surface of the second thermal insulation layer 221 is configured with a first support slope inclined along the first direction, and the first support portion 222 is configured with a second support slope 2224 adapted to the first support slope.
- the processing of the first supporting slope and the second supporting slope 2224 is simple and can reduce the thickness of the air duct assembly 200 .
- the second heat preservation layer 221 is also configured with a first support groove compatible with the drainage part 110, the first support part 222 is configured with a second support groove 2225 compatible with the first support groove, and the second support groove
- the rear end opening 170 of the groove 2225 communicates with the drainage structure, so that the defrosting water received by the drainage board 100 can be easily exported.
- the evaporator 230 is placed horizontally in the first cavity 282 of the air duct assembly 200 , and the drain plate 100 under the evaporator 230 plays a role of receiving defrosting water.
- the top surface of the drain plate 100 is parallel to the bottom surface of the evaporator 230 . 1 , 2 , 10 and 11 are used to place the evaporator 230 above the drain plate 100 , but the structure of the evaporator 230 is not shown in the figures.
- the evaporator 230 is placed horizontally, it can be understood that the height of the evaporator 230 is smaller than the length and width.
- the drain plate 100 is located below the evaporator 230 , and the drain plate 100 is provided with a water guiding portion that is recessed relative to the top surface, and the included angle between the evaporator 230 and the horizontal plane is less than or equal to a preset included angle.
- the included angle between the evaporator 230 and the horizontal plane is less than or equal to the preset angle, which can be understood as that the end of the evaporator 230 facing the air outlet is lower than the end of the evaporator 230 facing the air inlet, and the end of the evaporator 230 facing the air outlet is in line with the horizontal plane.
- a line connecting one end toward the air inlet forms a predetermined angle with the horizontal plane, and the line here may be located on the bottom surface of the evaporator 230 or a plane of symmetry in the height direction.
- the shape of the evaporator 230 is a cuboid
- the bottom surface and the symmetrical plane of the evaporator 230 form a predetermined angle with the horizontal direction.
- the preset angle may be less than or equal to 7°, and the preset angle may be at least one of 1°, 2°, 3°, 4°, 5°, 6° and 7°. It should be noted that the preset angle defined here to be less than or equal to 7° is to reduce the height of the air duct assembly 200. In the case where the height of the air duct assembly 200 is not strictly limited, the preset angle can be appropriately increased .
- the drainage plate 100 is provided with a water guiding part that is recessed relative to the top surface, so that the evaporator 230 can be horizontally arranged in the first cavity 282 , and the height of the air duct assembly 200 can be sufficiently reduced at this time.
- the included angle formed by the evaporator 230 and the horizontal plane is less than or equal to the predetermined angle, so as to reduce the height space occupied by the evaporator 230, reduce the overall height of the air duct assembly 200, and achieve the purpose of expanding the capacity of the refrigeration equipment.
- the preset angle can be 7°, which can meet the defrosting and drainage requirements of the evaporator 230 while reducing the overall height of the air duct assembly 200 .
- the evaporator 230 can be installed horizontally above the drainage board 100, which can be understood as the bottom surface of the evaporator 230 is parallel to the horizontal plane, and compared with the situation where the evaporator 230 is installed obliquely, the required installation space of the horizontally arranged evaporator 230 If the height becomes smaller, the size of the air duct assembly 200 in the height direction can be reduced accordingly, and then the space in the tank body 300 occupied by the air duct assembly 200 becomes smaller. The capacity of the tank body 300 can be effectively increased so as to provide a large-capacity refrigeration device.
- the installation state of the drainage board 100 is not limited, the top surface of the drainage board 100 is parallel to the bottom surface of the evaporator 230 , or the top surface of the drainage board 100 is obliquely downward from front to rear relative to the bottom surface of the evaporator 230 .
- the top surface of the drainage board 100 is a plane and is also parallel to the horizontal plane, that is, the bottom surface of the evaporator 230 and the top surface of the drainage board 100 are placed horizontally, and the top surface of the drainage board 100 is located at the evaporator 230. below.
- the bottom surface of the evaporator 230 is parallel to or in contact with the top surface of the drain plate 100, and the gap between the evaporator 230 and the drain plate 100 becomes smaller, which can prevent the wind in the first cavity 282 from passing between the evaporator 230 and the drain plate 100.
- the gap between them flows directly to the air vent 244, which helps the wind fully exchange heat in the first cavity 282.
- the gap between the evaporator 230 and the drain plate 100 should be minimized to slow down the speed of the wind flowing from the gap between the evaporator 230 and the drain plate 100 to the air vent 244 , so as to prolong the flow of the wind in the first cavity 282
- the stay time is so that the wind can fully exchange heat with the evaporator 230 in the first cavity 282 and then flow out, so as to ensure the heat exchange efficiency.
- the evaporator 230 is a part of the refrigeration system in the refrigeration equipment.
- the refrigeration system includes a compressor, a condenser, a throttling element, and an evaporator 230.
- the refrigerant in the refrigeration system evaporates and absorbs heat in the evaporator 230.
- the wind in the first cavity 282 provides a cooling environment.
- the evaporator 230 is installed in the air duct assembly as an example for illustration, but the evaporator 230 is not limited to be applied to the air duct assembly 200 , and can also be installed in other applicable environments.
- the evaporator 230 includes a heat exchange tube 233 and a heat sink 234 connected to the heat exchange tube 233.
- the heat sink 234 is configured with a ventilation part 23421 for the air intake of the first air inlet 201 to pass through, so that the air intake of the first air intake 201 Pass through the ventilation part 23421 and flow to the inside of the evaporator 230, so that the incoming air from the first air inlet 201 can fully exchange heat.
- cooling fins 234 may be provided with ventilation parts 23421 , or all of the cooling fins 234 may be provided with ventilation parts 23421 , which can be selected according to requirements.
- the evaporator 230 includes a heat exchange tube 233, a first heat sink 2341 and a second heat sink 2342, the first heat sink 2341 and the second heat sink 2342 are connected to the heat exchange tube 233, and a plurality of first heat sinks 2341 are arranged side by side to form The first heat dissipation part, at least one side of the first heat dissipation part is provided with the second heat dissipation fin 2342 (when the evaporator is installed in the air duct assembly, the second heat dissipation fin 2342 is arranged between the first heat dissipation fin 2341 and the first air inlet 201 ), the second cooling fin 2342 is configured with a ventilation part 23421 for the air intake of the first air inlet 201 to pass through, so that part of the air intake of the first air inlet 201 is shunted to the inside of the evaporator 230 through the ventilation part 23421, thereby reducing the first The air volume of the air intake of the air inlet 201
- the second heat sink 2342 of the evaporator 230 divides the air intake of the first air inlet 201, which has little impact on the overall structure of the air duct assembly 200, and only part of the heat sink 234 needs to be replaced by the second heat sink with the ventilation part 23421
- the sheet 2342 has a simple structure, and the effect of diverting the incoming air is better.
- the second cooling fin 2342 is located on at least one side of the first cooling fin 2341, that is, the first air inlet 201 is provided on one side of the air duct assembly 200, then the second cooling fin 2342 is located on the corresponding side, and the air duct assembly 200
- the first air inlets 201 are provided on opposite sides, and the second cooling fins 2342 are provided on both sides of the first cooling fin 2341 .
- the surface of the second heat sink 2342 faces the first air inlet 201
- the second air inlet 202 is located at one end of the second heat sink 2342
- the air exhaust port is located at the other end of the second heat sink 2342 .
- the number of the second cooling fins 2342 can be set as required, and one or more second cooling fins 2342 can be set.
- part of the air intake of the first air inlet 201 flows through the ventilation part 23421 to between the second heat sink 2342 and the first heat sink 2341, and along the direction between the second heat sink 2342 and the first heat sink.
- the space between 2341 flows toward the direction of the air outlet; when there are multiple second cooling fins 2342, the wind passes through the ventilation part 23421 of the second cooling fin 2342 and flows along the space between adjacent second cooling fins 2342 and the first cooling fin 2342.
- the space between the second cooling fins 2342 and the first cooling fins 2341 flows to the air outlet, so the air flow space is larger and the fluidity is better.
- the ventilation part 23421 of the adjacent second heat sink 2342 passes through along a straight line, that is, among two adjacent second heat sinks 2342, the orthographic projection of the ventilation part 23421 of one second heat sink 2342 covers the other second heat sink
- the orthographic projection of the ventilation part 23421 of 2342 enables part of the wind to pass through the ventilation part 23421 smoothly and flow toward the first heat sink 2341 .
- the ventilation part 23421 of the adjacent second heat sink 2342 is in dislocation communication, that is, among two adjacent second heat sinks 2342, the orthographic projection of the ventilation part 23421 of one second heat sink 2342 covers the other second heat sink 2342 Part of the orthographic projection of the ventilating portion 23421, or the orthographic projections of the ventilating portion 23421 of two adjacent second cooling fins 2342 do not intersect, so that part of the wind can flow along the extending direction of the second cooling fin 2342.
- two adjacent second cooling fins 2342 may have a straight-through ventilation portion 23421 and a dislocation-connected ventilation portion 23421 , with more diverse structures.
- the cross-sectional area of the ventilation part 23421 can be gradually reduced, and the direction of the first heat sink 2341 passes through the ventilation part 23421.
- the reduced air volume and the reduced cross-sectional area of the ventilation part 23421 have little influence on the fluidity of the wind, and can also ensure the heat dissipation area of the second heat sink 2342 .
- the ventilation part 23421 includes at least one of a closed-loop through hole and a through hole with an opening.
- the ventilation part 23421 has various structures and is easy to process.
- the shape of the ventilation part 23421 is at least one of rectangle, circle, ellipse, trapezoid and triangle.
- the shape of the ventilation part 23421 is various and the structure is simple.
- the shape of the ventilation part 23421 is at least one of a closed rectangle, circle, ellipse, trapezoid and triangle, or the shape of the ventilation part 23421 is a rectangle, a circle, an ellipse, a trapezoid or a triangle with an opening. At least one of them, such as a rectangle with one end open, a circle with a notch, an oval with a notch, and the like.
- the shape of the ventilation part 23421 is not limited to the above-mentioned shapes, and the specific shape of the ventilation part 23421 can be set according to needs.
- Both sides of the evaporator 230 are provided with a first air inlet 201, a plurality of first cooling fins 2341 are arranged side by side to form a first heat dissipation part, and a second cooling fin 2342 is symmetrically arranged on both sides of the first cooling part, and the evaporator 230 corresponds to two Ventilation parts 23421 are provided at the positions of each of the first air inlets 201 to ensure that part of the incoming air from the two first air inlets 201 can be diverted through the ventilation parts 23421.
- air return components 430 are provided on the left and right sides of the air duct assembly 200 .
- the first cooling fins 2341 and the second cooling fins 2342 are arranged above the drain plate 100 to receive defrosting water from the evaporator 230 through the drain plate 100 .
- the structure is simple and the evaporator 230 is easy to install.
- the evaporator 230 can also be provided with a gravity sensor, and the weight change of the evaporator 230 can be obtained through the gravity sensor, so as to determine whether the evaporator 230 needs defrosting according to the weight change.
- the evaporator 230 can also be provided with a vibrator, which provides vibration force and can play a role in assisting defrosting.
- the heating structure for defrosting inside the air duct assembly 200 will be described below.
- a first heater 231 is arranged above the drain board 100, that is, the first heater 231 is arranged between the drain board 100 and the evaporator 230, when the evaporator 230 needs to defrost , the first heater 231 is turned on, and the heat generated by the first heater 231 is used to heat the frost attached to the surface of the evaporator 230 .
- the heat sink 234 of the evaporator 230 is provided with a snap-in slot for installing the first heater 231, the first heater 231 is fastened to the heat sink 234 through the snap-in slot, and the snap-in slot can be arranged on the heat sink 234 The position is lower, so that the first heater 231 is located between the drain plate 100 and the heat exchange tube 233. At this time, the installation of the first heater 231 is simple and the defrosting effect is good.
- the heating structure used for defrosting is not limited to be arranged between the drain plate 100 and the evaporator 230, in some cases, the heating structure can be arranged between the heat exchange tubes 233 of the evaporator 230, such as the heating structure is a plug-in
- the plug-in structure is simple and easy to install, which helps to improve the installation efficiency.
- the heat sink 234 is provided with a mounting hole 2343, and the second heater 232 is plugged into the mounting hole 2343, which has a simple structure and is easy to assemble and disassemble.
- the second heater 232 extends along the first end of the evaporator 230 to the second end, the first end and the second end are two opposite ends, so as to fully provide heat for the evaporator 230, where the second end and the first The ends are two ends forming an included angle with the extending direction of the heat sink 234 , such as the left end and the right end of the evaporator 230 .
- the second heater 232 can be plugged between the two rows of heat exchange tubes 233 to evenly heat and defrost the heat exchange tubes 233 of the upper and lower rows. 232 and the cooling fins 234 on the heat exchange tube 233 have higher heat exchange efficiency, and can also improve the efficiency of heating and defrosting.
- the second heater 232 is distributed in multiple layers along the height direction of the evaporator 230 to heat multiple positions of the evaporator 230 .
- the second heater 232 includes a plurality of fixedly connected heating elements.
- the plurality of heating elements are fixedly connected as a whole, and are directly inserted into the heat sink 234 as a whole during the assembly process, which is easy to assemble and has high assembly efficiency.
- the second heater 232 includes a plurality of independent heating elements, the location of the heating elements is flexible, and it is convenient to replace the heating elements independently, and the disassembly and assembly of the heating elements is also more convenient.
- the heating elements can be dislocated along the height direction of the evaporator 230 , which can reduce the number of heating elements and fully defrost the evaporator 230 .
- the evaporator 230 can be placed directly on the drainage board 100, which can effectively reduce the gap between the evaporator 230 and the drainage board 100, and play a role in slowing down the wind speed , can also play a role in improving the heat transfer efficiency.
- the heating structure can be set as a heating element 160, and the heating element 160 is attached to the surface of the drainage plate 100.
- the heating element 160 can be integrated with the drainage plate 100 into an integrated structure, and the drainage plate 100 with the heating element 160 can be installed in various structures.
- Below the evaporator 230, the drainage board 100 can not only receive and discharge the defrosting water, but also heat the defrosting.
- the drainage board 100 has dual functions. the height of.
- drain board 100 with the heating element 160 can be installed under the horizontal evaporator 230 .
- the drain plate 100 with the heating element 160 may be disposed below the evaporator 230 vertically installed in the cabinet body 400 , and the application scene of the drain plate 100 is not limited here.
- the heating element 160 can be integrally formed with the drainage board 100 in any one of the above-mentioned embodiments. Alternatively, the heating element 160 is integrally formed with other drainage boards 100 that can receive and discharge defrosting water, so that the drainage board 100 can be widely used in various occasions.
- the heating element 160 covers the lower surface of the drain plate 100, and the upper surface of the drain plate 100 is used to receive defrosting water.
- the heating element 160 located on the lower surface of the drain plate 100 can avoid direct contact with water, and can avoid leakage due to circuit failure. accidents, the safety performance of refrigeration equipment is better.
- the heating element 160 can also cover the upper surface of the drainage board 100 under the condition that the waterproof performance of the heating element 160 is guaranteed.
- the heating element 160 can be a heating wire or a heating film disposed on the surface of the drainage board 100 .
- the heating element as a heating film as an example.
- the heating element 160 includes an insulating layer and a composite heating layer disposed on the lower surface of the insulating layer.
- the insulating layer is connected to the lower surface of the drainage board 100 .
- the insulation protection between the drainage board 100 and the composite heating layer can reduce the risk of leakage.
- the material of the drain plate 100 is not limited, and the drain plate 100 can be made of steel, which is easy to process and can also ensure the heat conduction effect of the drain plate 100 .
- the heating element 160 includes a composite heating layer.
- the drainage board 100 is an insulating and heat-conducting structure.
- the composite heating layer is arranged on the lower surface of the drainage board 100.
- the drainage board 100 has both heat conduction and insulation functions. The processing process is simpler and helps to improve production efficiency.
- the drainage plate 100 may be a composite structure of ceramics and glass fiber materials.
- the composite heating layer of the heating element 160 may be a graphene heating layer, a nanometer heating layer or a carbon fiber heating layer and a heating layer composed of various electric heating materials.
- the composite heating layer When the composite heating layer is energized, the electric energy can be converted into heat energy of the heating element 160 to provide heat for defrosting.
- the graphene heating layer is a planar film composed of carbon atoms in a hexagonal honeycomb lattice, with a thickness of only one atom, so the thickness of the heating element 160 can be controlled.
- the heating element 160 when the heating element 160 is arranged on the lower surface of the drainage board 100 , an insulating and heat-insulating layer needs to be provided under the composite heating layer to reduce the downward diffusion of heat and ensure the thermal efficiency of heating. Between the composite heating layer and the insulation layer, between the composite heating layer and the drainage board 100, and between the insulation and heat insulation layer and the composite heating layer are bonded with a thermally conductive adhesive layer. reliable connection between.
- the heating element 160 includes a plurality of heating zones distributed along the set direction.
- the heating power per unit area of the heating zone along the set direction increases gradually.
- the heating power of the corresponding heating zone can be adjusted according to the amount of frosting in different positions. Achieve fast and full defrosting, and also reduce power consumption.
- the grid distribution of the graphene heating layer in different heating zones is different, so that the resistance distribution of the graphene heating layer in different heating zones is different.
- Two types of graphene heating layers with different resistances can be distributed on the lower surface of the drainage board 100 , and of course, any number of graphene heating layers with different resistances can also be distributed.
- graphene heating layers with different resistances can be connected in series or in parallel, and can also be connected to different circuits.
- the heating element 160 in the above embodiment is applied to the above-mentioned air duct assembly 200 for defrosting the evaporator 230, so that the space occupied by the heater can be reduced, and the height of the air duct assembly 200 can be reduced. , and further reduce the volume of the air duct assembly 200, the refrigeration equipment with such an air duct assembly 200 can appropriately increase the storage space, and play the role of expansion of the refrigeration equipment.
- the drain plate 100 with the heating element 160 in the above embodiment can be used in combination with at least one of the first heater 231 and the second heater 232 to improve the defrosting efficiency.
- heating element 160 can be applied to the drainage board 100 of the above embodiment, but it is not limited thereto, and the heating element 160 can also be applied to drainage boards of other structures.
- the above-mentioned heating structure for defrosting needs to be electrically connected to the external power supply of the air duct assembly 200 through wires, and the wires can be routed through the wire holes opened in the fan cover 240 , which has a simple structure and is convenient for assembly.
- the baffle part 210 and the air duct part 220 define a first cavity 282 , an air inlet and an air outlet.
- the evaporator 230 and the drain plate 100 are arranged in the first cavity 282 . After the internal heat exchange, it is discharged from the exhaust outlet, and the exhaust outlet sends the air into the compartment to provide a cooling environment for the refrigeration equipment.
- the air inlet includes a first air inlet 201 and a second air inlet 202
- the first air inlet 201 and the second air inlet 202 include inlet air of different temperatures.
- the partition part 210 can be fixedly connected to the tank body 300, for example, the edge of the partition part 210 is fixed to the tank body 300 by means of welding, clamping or fasteners.
- the partition member 210 includes a first plate body 211 and a second plate body 212, the first plate body 211 and the second plate body 212 are provided with a first heat insulating layer 213, and the first heat insulating layer 213 is It can be detachably disposed between the first plate body 211 and the second plate body 212 , or the first heat insulating layer 213 is integrally foamed with the first plate body 211 and the second plate body 212 .
- the first thermal insulation layer 213 is integrally foamed with the first panel body 211 and the second panel body 212
- the first panel body 211, the second panel body 212 and the tank body 300 can be fixedly installed first
- the first thermal insulation layer 213 It is integrally foamed with the insulation layer of the cabinet body 400 , and the sealing performance between the partition member 210 and the tank body 300 is better, so as to avoid cross-wind between the first compartment 410 and the second compartment 420 .
- the partition member 210 also includes a third board 214, the third board 214 and the first board 211 and the second board 212 limit the installation space, and the part that limits the installation space can be Called the installation part, the third board body 214 is located in front of the air duct assembly 200, and the installation space is located in front of the partition member 210, and the installation space is used for installing functional components, such as controllers, lighting modules, interactive modules, and display modules.
- the part (installation part) of the partition member 210 that limits the installation space is located at the front end of the second air inlet 202, and the part (installation part) that limits the installation space To cover the second air inlet 202 at the front end, so that the second air inlet 202 is hidden, and the bottom of the second air inlet 202 communicates with the second compartment 420 .
- the second air inlet 202 is not limited to be disposed on the front side of the air duct assembly 200 , and the second air inlet 202 may also be disposed on the lower side of the air duct assembly 200 near the front.
- the baffle part 210 and the air duct part 220 limit the first cavity 282, the first air inlet 201, the second air inlet 202 and the air outlet, the first air inlet 201 and the second air inlet
- the air inlet 202 includes air inlets of different temperatures; the first air inlet 201 is located on the first side of the air duct assembly 200, the second air inlet 202 is located on the second side of the air duct assembly 200, and the first side is adjacent to the second side, Or the first air inlet 201 and the second air inlet 202 are located on the same side;
- the partition member 210 is configured with an inner concave portion that is recessed toward the inner side of the partition member 210, and the inner concave portion is suitable for guiding the first air inlet 201 and the second air inlet 202.
- At least one part of the air intake is diverted into the inner recess, that is, part of the air intake of at least one of the first air inlet 201 and the second air inlet 202 is diverted to the respective corresponding inner recesses, so as to reduce the size of the first air inlet 201 and the second air inlet.
- the cross-contact air volume of the air inlet of the second air inlet 202 reduces the amount of frosting in the cross-contact area of the air inlet, thereby prolonging the time between two defrosting intervals, reducing the number of defrosting times, and reducing the power consumption of defrosting.
- first air inlet 201 and the second air inlet 202 are located on different sides and the air inlet directions intersect each other, during the air inlet process, a part of the wind from the first air inlet 201 is guided along the extending direction of the corresponding inner concave part, and a part Continue to flow along the air inlet direction.
- the wind that continues to flow along the air inlet direction crosses the air inlet of the second air inlet 202, reducing the air intake of the first air inlet.
- 201 and the second air inlet 202 in the cross-flow air volume.
- the principle of setting the concave part in the corresponding area of the second air inlet 202 is the same, and will not be repeated here.
- the extension direction of the inner concave part is consistent with the extension direction of the corresponding air inlet, and the first air inlet 201 Part of the air intake from the first air inlet 201 flows along the extension direction of the corresponding inner concave portion, and another part of the air intake from the first air inlet 201 continues to flow along its flow direction.
- the inner recess includes a first inner recess 2121, and the first inner recess 2121 extends a first predetermined length L2 along the second side of the partition member 210 to the third side with the first predetermined width L1, and the second
- the air inlet 202 is located on the second side
- the third side is a side not adjacent to the second side
- the third side can be the side where the air outlet is located
- the first inner recess 2121 is close to the first side edge of the partition member 210
- the first air inlet 201 is located on the first side.
- Part of the air entering the first cavity 282 from the first air inlet 201 flows along the air inlet direction of the first air inlet 201 and cross-contacts with the air inlet of the second air inlet 202 , and the other part flows along the direction of the first inner recess 2121 .
- the flow in the extension direction, the first inner concave part 2121 plays the role of guiding and diverting, so as to reduce the air volume of the confluence of the air intake from the first air inlet 201 and the air intake from the second air inlet 202, thereby reducing the amount of frosting.
- the first preset width L1 can be set to be less than or equal to the minimum distance from the first air inlet 201 to the second air inlet 202; the first preset length L2 can be set to be less than or equal to the length of the evaporator 230, evaporating
- the length direction of the device 230 is the direction from the air inlet to the air outlet.
- the first inner concave portion 2121 is configured with a first top surface 2123 and a first guide surface 2122 connected to the first top surface 2123, and the first guide surface 2122 is inclined downward along a direction away from the first top surface 2123.
- the first guide surface 2122 is located on the side away from the first air inlet 201, and the first guide surface 2122 guides the wind to the direction of the air outlet, preventing the wind from accumulating in the groove restricted by the first inner concave part 2121, ensuring the wind flow Loop flow effect.
- the first side of the first cavity 282 includes two or more sides, for example, the first side is set as the opposite left and right sides, and the first air inlet 201 is set on the left side and the right side of the air duct assembly 200, Both sides of the partition member 210 are symmetrically provided with first inner recesses 2121, and each first inner recess 2121 corresponds to a first air inlet 201, ensuring that the air intake of each first air inlet 201 passes through the first inner recess 2121 Divert some of the wind.
- the first guiding surface 2122 can be disposed on the rear side, left side or right side of the first inner concave portion 2121 . As shown in FIG. 26 , it is illustrated that one first guiding surface 2122 is located at the rear side of the first inner concave portion 2121 , and the other first guiding surface 2122 is located at the left side of the first inner concave portion 2121 . FIG. 26 shows the first guide surface 2122 at different positions. In practical applications, two first inner concave parts 2121 are generally arranged symmetrically.
- the inner recess includes a second inner recess 2124, and one side of the second inner recess 2124 faces the second air inlet 202, so that the second inner recess 2124 can guide part of the second air inlet 202 to enter
- the wind flows along the groove restricted by the second inner concave part 2124, and the second air inlet 202 also diverts part of the air intake, which can reduce the air volume of the air inlet of the first air inlet 201 and the air inlet of the second air inlet 202. Reduce the amount of frosting.
- the second inner concave portion 2124 extends along the second side of the partition member 210 to the third side with a second preset width L3 for a second preset length L4, and the second preset length L4 is smaller than that of the evaporator 230 in the first cavity 282 Length, the length of the evaporator 230 is the length from the second side to the third side.
- the second side and the third side can refer to the above explanations.
- the length of the second inner concave part 2124 is less than the length of the evaporator 230, so as to prevent the wind in the first inner concave part 2121 from flowing directly to the air outlet, and ensure that the wind in the first inner concave part 2121 exchanges heat with the evaporator 230 and then flows out from the air outlet. discharge.
- the second inner concave portion 2124 is configured with a second top surface 2126 and a second guide surface 2125 connected to the second top surface 2126, the second guide surface 2125 is inclined downward along the direction away from the second top surface 2126, and the second guide surface 2125 Towards the side where the air outlet is located, the slope of the second guide surface 2125 guides the wind downward, so that the wind can fully flow to the evaporator 230 .
- the first inner recess 2121 and the second inner recess 2124 can be used in combination, that is, the partition member 210 is provided with the first inner recess 2121 and the second inner recess 2124 at the same time, at this time, the second inner recess 2124 and the second inner recess 2124 An inner concave portion 2121 is separated by the third wall plate 215 , the first inner concave portion 2121 and the second inner concave portion 2124 have the same concave depth, and the structure is simple and easy to process.
- the first preset length L2 is greater than or equal to the second preset length L4, and the first inner concave portion 2121 is fully facing the direction of the air outlet.
- Guide the air from the first air inlet 201 , and the second inner recess 2124 guide the air from the second air inlet 202 toward the air outlet, which can also ensure the heat exchange effect between the wind and the evaporator 230 .
- wind in the second inner concave portion 2124 may also include wind after the air entering the first air inlet 201 and the air entering the second air inlet 202 meet and mix.
- the evaporator 230 includes a heat exchange tube 233 and a cooling fin 234 connected to the heat exchange tube 233.
- the cooling fin 234 extends along the side where the second air inlet 202 is located to the side where the air outlet is located.
- the cooling fin 234 can guide the wind from the side where the air inlet is located. Flow to the side where the exhaust vent is located.
- the cooling fin 234 is configured with a protruding portion, and the protruding portion protrudes into the second inner concave portion 2124 to ensure that the wind in the second inner concave portion 2124 can fully exchange heat with the cooling fin 234 .
- the partition member 210 is configured with a third inner recess 2127, one side of the third inner recess 2127 faces the first air inlet 201, the other side of the third inner recess 2127 faces the second air inlet 202, and the third inner recess 2127 faces the second air inlet 202.
- the first air inlet 201 and the second air inlet 202 are located on adjacent sides, so that the third inner recess 2127 is located in the intersection area corresponding to the first air inlet 201 and the second air inlet 202, and the third inner recess 2127 increases
- the space in the crossing area of the first air inlet 201 and the second air inlet 202 increases the frost-holding space, prolongs the duration of air intake at the end where the air inlet is located, reduces the number of defrosting times, prolongs the defrosting cycle, and saves Frost consumes electricity.
- first air inlet 201 and the second air inlet 202 are located on adjacent two sides, as shown in FIG.
- the chamber 410 is connected, the second air inlet 202 is located at the front side of the air duct assembly 200 , and the first air inlet 201 and the second air inlet 202 are both located at the front of the air duct assembly 200 .
- the first air inlet 201 and the second air inlet 202 can also be located on opposite sides (not shown in the figure), such as the first air inlet 201 is located on the left side of the air duct assembly 200, and the second air inlet 202 is located on the air duct assembly 200 At this time, the third inner concave portion 2127 can provide a larger intersection space for the air intake of the first air inlet 201 and the air intake of the second air inlet 202 .
- the first air inlet 201 and the second air inlet 202 can also be located on opposite sides, and the distance between the first air inlet 201 and the second air inlet 202 can also be increased to properly reduce the air volume of the cross heat exchange.
- the third inner recess 2127 extends along the side where the second air inlet 202 is located to the side where the air outlet is located with a third preset width L5 for a third preset length L6, and the third preset length L6 is smaller than the evaporator 230 in the first cavity 282
- the length of the evaporator 230 is the length along the side where the second air inlet 202 is located to the side where the air outlet is located.
- the width direction of the third inner recess 2127 is perpendicular to the direction from the second air inlet 202 to the air outlet
- the third preset width L5 is the dimension in this direction
- the third preset length L6 is from The length of the second air inlet 202 toward the air outlet.
- the third inner concave portion 2127 is configured with a third top surface 2128 and a third guide surface 2129 connected to the third top surface 2128, the third guide surface 2129 is inclined downward along the direction away from the third top surface 2128, the third guide surface 2129 Towards the side where the exhaust vents are located.
- the third guide surface 2129 guides the wind in the third concave portion 2127 to the direction of the evaporator 230 so that this part of the wind can be exhausted after sufficient heat exchange.
- the structure of the air duct assembly 200 is proposed as follows, but the air duct assembly 200 It is not limited to the structure described below.
- the air duct assembly 200 includes a baffle part 210 and an air duct part 220 , and the baffle part 210 and the air duct part 220 construct a first cavity 282 , an air inlet and an air outlet, which communicate with each other.
- the air inlet is divided into a first air inlet 201 and a second air inlet 202, and a drainage board 100 is arranged in the first cavity 282.
- the drainage board 100 is configured with a water guide part that is sunken downward relative to the top surface of the drainage board 100, and the water guide The part extends to the both sides of the preset surface to the edge of the drain plate 100, so that the edge of the drain plate 100 forms an opening 170, and the opening 170 faces the side where the first air inlet 201 is located, so that part of the air intake of the first air inlet 201 is suitable It passes through the opening 170 and flows into the first cavity 282 along the extending direction of the water guiding part.
- Part of the air intake from the first air inlet 201 passes through the opening 170 and is introduced into the first cavity 282 along the extending direction of the water guiding part, so that a part of the air intake from the first air inlet 201 can be shunted to reduce the interaction with the second air inlet 202
- the cross-contact air volume in the air intake thereby reducing the frost condensed due to the cross-contact of the air intake of the first air inlet 201 and the air intake of the second air inlet 202, reducing the number of defrosting times, prolonging the defrosting cycle, and reducing the need for defrosting. Power consumption, reduce the power consumption of refrigeration equipment.
- the water guiding part is at least one structure shown in FIGS. 1 to 13 , that is, the water guiding part can be at least one of the second water guiding part 130 and the third water guiding part 140 .
- the air duct assembly 200 further includes a first drainage component 260 located on the first side, the first drainage component 260 communicates with the opening 170 of the drainage plate 100 , and the first drainage component 260 is configured with a drainage port.
- the first drainage component 260 has the functions of drainage and air intake simultaneously.
- the air duct assembly 200 also includes a fan cover 240, the fan cover 240 defines a second cavity 281, the second cavity 281 is provided with a fan 270, and the rotation axis of the fan 270 forms a first clip with the vertical direction.
- the fan cover 240 defines a vent 244 , and the inlet of the fan 270 faces the vent 244 .
- the fan 270 is placed horizontally in the fan cover 240 , so that the height of the fan 270 can be reduced, thereby reducing the height of the air duct assembly 200 , and it is convenient to install a drawer under the air duct assembly 200 .
- the evaporator 230 is arranged in the first cavity 282, the drain board 100 is located below the evaporator 230, and the angle between the evaporator 230 and the horizontal direction is less than or equal to a preset angle, or, the evaporator 230 and the horizontal direction Parallel, the evaporator 230 is placed horizontally, and its downward slope angle can be less than or equal to 7° or horizontal, the space occupied by the evaporator 230 in the height direction is reduced, and the height of the air duct assembly 200 is also reduced, which helps To increase the space of refrigeration equipment.
- Partition plate part 210, air duct part 220, first drainage part 260, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structures in the above embodiments, and will not be repeated here.
- the air duct assembly 200 includes a partition part 210 , an air duct part 220 , an evaporator 230 and a drainage plate 100 , and the partition part 210 and the air duct part 220 construct a first cavity 282 that communicates with each other.
- the first air inlet 201, the second air inlet 202 and the air outlet the first air inlet 201 is located on the first side of the first cavity 282, the second air inlet 202 is located on the second side of the first cavity 282, the second One side is adjacent to the second side;
- the evaporator 230 is located in the first cavity 282;
- the drain plate 100 is located in the first cavity 282;
- the drain plate 100 is located below the evaporator 230 and is configured with a top Facing the downwardly recessed water guide part and the drain part 110, the drain part 110 is configured with an outlet 114 and communicates with the water guide part, the extending direction of the drain part 110 forms a fifth angle with the extending direction of the water guide part, and the end of the water guide part
- the opening 170 is configured in the part and the opening 170 faces the first air inlet 201, so that the wind from the first air inlet 201 is suitable to flow into the first cavity 282 along the extending direction of the water guide part.
- the water guide part plays the role of guiding the air intake of the first air inlet 201, so that a part of the air intake of the first air inlet 201 flows into the first cavity 282 along the water guide part, reducing the distance between the first air inlet 201 and the first air inlet 201.
- the cross-contact air volume in the air inlet of the second air inlet 202 reduces the frost condensed due to the contact of wind with different temperatures, thereby prolonging the time between defrosting intervals, reducing the number of defrosting times, saving the power consumption of defrosting, and saving energy.
- the role of energy saving is the role of energy saving.
- the structure of the water guiding part may be the third water guiding part 140 .
- outlet 114 of the drain board 100 and the air outlet are located on the same side of the first cavity 282, and the heat of the defrosting water flowing to the outlet 114 of the drain board 100 can be used by the fan 270 on the same side to defrost. role.
- both the top surface of the drainage board 100 and the bottom surface of the evaporator 230 are inclined downward at a preset angle, or the top surface of the drainage board 100 and the bottom surface of the evaporator 230 are both parallel to the horizontal plane.
- the evaporator 230 is placed horizontally, and its downward slope angle can be less than or equal to 7° or horizontal, the space occupied by the evaporator 230 in the height direction is reduced, and the height of the air duct assembly 200 is also reduced accordingly, which helps to increase the Room for large refrigeration equipment.
- the air duct assembly 200 further includes a first drainage component 260 located on the first side, the first drainage component 260 surrounds the opening 170 and communicates with the opening 170 , and the first drainage component 260 is configured with a first drainage port 262 .
- the first drainage component 260 may be disposed in the foam layer of the cabinet body 400 to increase the space of the compartment.
- the air duct assembly 200 also includes a fan cover 240, the fan cover 240 limits the second cavity 281, the second cavity 281 is provided with a fan 270, the rotation axis of the fan 270 forms a first angle ⁇ 1 with the vertical direction, the fan cover 240 defines a vent 244 , and the inlet of the fan 270 faces the vent 244 .
- the fan 270 is placed horizontally in the fan cover 240 , and the height of the fan 270 is reduced, thereby reducing the overall height of the air duct assembly 200 .
- Partition plate part 210, air duct part 220, first drainage part 260, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structures in the above embodiments, and will not be repeated here.
- the air duct assembly 200 includes a partition part 210 , an air duct part 220 , an evaporator 230 and a drainage plate 100 , and the partition part 210 and the air duct part 220 construct a first cavity 282 that communicates with each other.
- the first air inlet 201, the second air inlet 202 and the air outlet the first air inlet 201 is located on the first side of the first cavity 282, the second air inlet 202 is located on the second side of the first cavity 282, the second One side is adjacent to the second side;
- the evaporator 230 is located in the first cavity 282;
- the drain plate 100 is located in the first cavity 282;
- the drain plate 100 is located below the evaporator 230, and the drain plate 100 is configured with a water guide
- the water guiding part is recessed relative to the top surface of the drainage board 100 and communicates with the outlet 114 , and the extending direction of the water guiding part forms a fourth included angle with the air outlet direction of the first cavity 282 .
- the water guiding part can be at least one of the above-mentioned second water guiding part 130 and the third water guiding part 140 .
- the included angle between the evaporator 230 and the horizontal direction is less than or equal to a preset angle, or, the evaporator 230 is arranged along the horizontal direction.
- the evaporator 230 is placed horizontally, and its downward slope angle can be less than or equal to 7° or horizontal, the space occupied by the evaporator 230 in the height direction is reduced, and the height of the air duct assembly 200 is also reduced accordingly, which helps to increase the Room for large refrigeration equipment.
- the air duct assembly 200 further includes a fan 270 located on one side of the first cavity 282 , and the outlet 114 of the drain plate 100 faces to the side where the fan 270 is located.
- the outlet 114 of the drain plate 100 is misaligned with the inlet of the fan 270 to prevent water from flowing to the fan 270 .
- the second air inlet 202 is located on the front side of the air duct assembly 200 and communicates with the second compartment 420.
- the first air inlet 201 is located on at least one of the left and right sides of the air duct assembly 200 and is close to the front end.
- the first air inlet 201 It communicates with the first chamber 410 to return air through the front end of the air duct assembly 200 .
- Partition plate member 210, air duct member 220, first drainage member 260, second drainage member 290, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structure in the above embodiment, here I won't repeat them here.
- the air duct assembly 200 includes a baffle part 210, an air duct part 220, a fan 270, an evaporator 230 and a drainage plate 100, and the baffle part 210 and the air duct part 220 form a first connected Cavity 282, first air inlet 201, second air inlet 202 and air outlet, the first air inlet 201 is located at the first side of the first cavity 282, the second air inlet 202 is located at the second side of the first cavity 282 side, the first side is adjacent to the second side; the evaporator 230 is located in the first cavity 282; the drain plate 100 is located in the first cavity 282; the drain plate 100 is located below the evaporator 230 to receive defrosting water,
- the drainage board 100 is configured with a water guiding part that is recessed downwards relative to the top surface of the drainage board 100, and the water guiding part extends to both sides of the preset surface to the edge of the drainage board 100, so that the edge of the drainage board 100 forms a well
- the opening 170 faces the first side; the blower 270 is located on the third side of the first cavity 282 . That is, the drainage positions of the fan 270 and the drainage plate 100 are located on different sides, which can reduce the space occupied by the side where the fan 270 is located, thereby increasing the compartment space in the refrigeration equipment to provide a large-capacity refrigeration equipment.
- the air duct assembly 200 further includes a first drainage component 260 located on the first side, the drainage channel of the first drainage component 260 communicates with the opening 170 , and the first drainage component 260 is configured with a drainage port.
- the first drainage component 260 can be molded in the foam layer of the cabinet body 400, without occupying the space of the compartment, and effectively expanding the capacity of the compartment.
- the side of the opening 170 of the drain plate 100 is drained through the first drain member 260 , and the structure of the first drain member 260 can be referred to above.
- the included angle between the evaporator 230 and the horizontal direction is less than or equal to the preset angle, the evaporator 230 is placed horizontally and its downward slope angle can be less than or equal to 7°, the space occupied by the evaporator 230 in the height direction is reduced, and the air duct assembly The height of 200 is also reduced accordingly, which helps to increase the space of refrigeration equipment.
- the second air inlet 202 is located on the second side of the first cavity 282, and the first side is adjacent to the second side.
- the second air inlet 202 and the first air inlet 201 have different temperature air inlets.
- the first air inlet 201 and the first air inlet 201 have different temperatures.
- the compartments connected by the second air inlet 202 have different ambient temperatures.
- the first side is at least one of the left side and the right side, and the first air inlet 201 and the first drainage member 260 are located at least one of the left side and the right side; the second side is the front side, and the second air inlet 202 is located at the front side, the third side is the rear side, and the fan 270 is located at the rear side.
- the first air inlet 201 communicating with the refrigerating room is arranged on the left and right sides of the air duct assembly 200, and the second air inlet 201 communicating with the freezing room
- the air inlet 202 is arranged on the front side of the air duct assembly 200, the front end of the second air inlet 202 is blocked by the partition member 210, the second air inlet 202 communicates with the freezer through the bottom of the partition member 210, the rear of the air duct assembly 200
- a fan 270 is arranged on the side, and the fan 270 discharges the wind from the air outlet.
- the air duct assembly 200 also includes a fan cover 240 disposed between the partition member 210 and the air duct member 220.
- the fan cover 240 forms a second cavity 281, and a fan 270 is arranged in the second cavity 281.
- the fan cover 240 is configured There is a vent 244 , the inlet of the blower 270 faces the vent 244 , and the blower cover 240 plays a role in protecting the blower 270 .
- the rotation axis of the fan 270 forms a first included angle ⁇ 1 with the vertical direction, which can reduce the size of the fan 270 in the height direction.
- the vent 244 is located above the blower 270 so that the blower 270 is supported by the air duct member 220 , and the position above the blower 270 corresponds to the position of the evaporator 230 .
- the central axis of the air vent 244 is in line with the rotation axis of the fan 270 to ensure that the wind in the first cavity 282 is guided smoothly by the fan 270 from the air exhaust port.
- the fan cover 240 is configured with a deflector surface 2411 located above the fan 270 and facing the fan 270.
- the deflector surface 2411 is inclined upward or downward along the side facing the drain plate 100.
- the deflector surface 2411 can collect water vapor and collect it to obtain The water is discharged from the fan cover 240 side.
- Partition plate part 210, air duct part 220, first drainage part 260, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structures in the above embodiments, and will not be repeated here.
- the air duct assembly 200 includes a baffle part 210, an air duct part 220, a fan 270, an evaporator 230 and a drain plate 100, and the baffle part 210 and the air duct part 220 form a first connected Cavity 282, first air inlet 201, second air inlet 202 and air outlet, the first air inlet 201 is located at the first side of the first cavity 282, the second air inlet 202 is located at the second side of the first cavity 282 side, the first side is adjacent to the second side; the evaporator 230 is located in the first cavity 282; the drain plate 100 is located in the first cavity 282; the drain plate 100 is located below the evaporator 230, and the drain plate 100 is constructed with The opening 170 and the outlet 114, the opening 170 faces the first side, and the outlet 114 faces the third side; the first drainage member 260 is located on the first side and is configured with a drainage channel communicating with the opening 170, so that the water on the drainage board 100 passes
- the first drainage part 260 cooperates with the second drainage part 290, so that the air duct assembly 200 can drain from different sides, and the number of drainage paths increases, which helps the defrosting water received by the drainage board 100 to be discharged from multiple directions, which can improve the defrosting and cooling performance. drainage efficiency.
- the air duct assembly 200 also includes a fan cover 240 and a fan 270 disposed in the fan cover 240 , and a second drainage component 290 is disposed in the fan cover 240 or below the fan cover 240 .
- the fan cover 240 is configured with a vent 244 , the rotation axis of the fan 270 forms a first included angle with the vertical direction, and the inlet of the fan 270 faces the vent 244 .
- the fan 270 is installed horizontally, which helps to reduce the height of the air duct assembly 200 .
- the included angle between the evaporator 230 and the horizontal direction is less than or equal to the preset angle, the evaporator 230 is placed horizontally and its downward slope angle can be less than or equal to 7°, the space occupied by the evaporator 230 in the height direction is reduced, and the air duct assembly The height of 200 is also reduced accordingly, which helps to increase the space of refrigeration equipment.
- Partition plate member 210, air duct member 220, first drainage member 260, second drainage member 290, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structure in the above embodiment, here I won't repeat them here.
- the air duct assembly 200 includes a baffle part 210, an air duct part 220, a fan 270, an evaporator 230 and a drainage plate 100, and the baffle part 210 and the air duct part 220 form a first connected Cavity 282, air inlet and air outlet, evaporator 230 is located in the first cavity 282; drain plate 100 is located in the first cavity 282; drain plate 100 is located below the evaporator 230, and drain plate 100 is configured with drainage part 110 and the water guide part, the drain part 110 is configured with an outlet 114, the drain part 110 is recessed relative to the top surface of the drain plate 100;
- the extension direction of the water guide part forms a fifth angle with the wind outlet direction of the first cavity 282;
- the fan cover 240 constructs a vent 244, a second cavity 281 and a water guide channel, and the second cavity 281 passes through the vent 244 It communicates with the first cavity 282, and the water guide channel communicates with the outlet 114; the fan 270 is
- the water guide channel In the direction away from the outlet 114 , the water guide channel is inclined downward, so as to conduct water guide through the inclined angle, so that the water can be discharged quickly and completely.
- the included angle between the evaporator 230 and the horizontal direction is less than or equal to the preset angle, the evaporator 230 is placed horizontally and its downward slope angle can be less than or equal to 7°, the space occupied by the evaporator 230 in the height direction is reduced, and the air duct assembly The height of 200 is also reduced accordingly, which helps to increase the space of refrigeration equipment.
- the air duct part 220 and the partition part 210 construct an air inlet and an air outlet that communicate with the first cavity 282, and the drainage part 110 extends along the direction from the air inlet to the air outlet, so that the water from the outlet 114 of the drainage plate 100 passes through the fan cover 240 water guide channel discharge.
- the air inlet includes a first air inlet 201 and a second air inlet 202, the first air inlet 201 and the second air inlet 202 have different temperature air inlets, the first air inlet 201 and the second air inlet 202 are located in the first cavity 282 different sides of the .
- the first air inlet 201 is located on the first side of the first cavity 282
- the second air inlet 202 is located on the second side of the first cavity 282
- the first side is adjacent to the second side
- the first air inlet 201 is located near the front side position, so that the air is taken in from the front end of the air duct assembly 200 .
- Partition plate member 210, air duct member 220, first drainage member 260, second drainage member 290, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structure in the above embodiment, here I won't repeat them here.
- the air duct assembly 200 includes a partition member 210, an air duct member 220, a fan 270, an evaporator 230, a drain plate 100, and a splitter, and the partition member 210 and the air duct member 220 are configured to communicate with each other.
- the first chamber 282, the air inlet and the air outlet, the evaporator 230 is located in the first chamber 282; the drain board 100 is located in the first chamber 282;
- At least one of the baffle part 210 and the air duct part 220 is used to guide part of the air intake of the first air inlet 201 to flow along the guiding direction of the splitter part.
- the splitter plays the role of diverting part of the air intake from the first air inlet 201, thereby reducing the air volume of the intersection of the air intake from the first air inlet 201 and the air intake from the second air inlet 202, and reducing the air flow caused by different temperatures.
- Defrost prolong the time between two defrosts, and reduce the power consumption of defrosts.
- the structure of the splitter can be referred to as shown in FIG. 21 to FIG. 38 .
- the splitter is a first inner concave portion 2121 configured on the partition member 210, the first inner concave portion 2121 is recessed toward the inside of the partition member 210, and the first inner concave portion 2121 is suitable for guiding part of the air intake of the first air inlet 201 to divert to the first In the inner recess 2121 , the first air inlet 201 is located at least one of the left side and the right side of the first cavity 282 .
- the air duct assembly 200 also includes an evaporator 230 disposed in the first cavity 282, the evaporator 230 includes a heat exchange tube 233 and a cooling fin 234; the cooling fin 234 includes a first cooling fin 2341 and a second cooling fin 2342, the first The cooling fins 2341 are connected to the heat exchange tubes 233, and a plurality of first cooling fins 2341 constitute a first heat dissipation part; the second cooling fins 2342 are connected to the heat exchange tubes 233, and the second cooling fins 2342 are arranged on at least one of the first cooling parts.
- the splitter is the ventilation part 23421 constructed on the second cooling fin 2342
- the projection of the first cooling fin 2341 on the second cooling fin 2342 covers the ventilation part 23421
- the projection of the first air inlet 201 on the second cooling fin 2342 covers
- the ventilation part 23421, the first cooling fin 2341 and the second cooling fin 2342 all extend from the second side to the third side
- the third side is the side where the air outlet is located.
- the included angle between the evaporator 230 and the horizontal direction is less than or equal to the preset angle, the evaporator 230 is placed horizontally and its downward slope angle can be less than or equal to 7°, the space occupied by the evaporator 230 in the height direction is reduced, and the air duct assembly The height of 200 is also reduced accordingly, which helps to increase the space of refrigeration equipment.
- Partition plate member 210, air duct member 220, first drainage member 260, second drainage member 290, fan 270, fan cover 240, drainage plate 100, evaporator 230 and other components can all adopt the structure in the above embodiment, here I won't repeat them here.
- the air duct assembly 200 includes a baffle part 210 , an air duct part 220 , an evaporator 230 and a drainage plate 100 .
- the drainage board 100 is configured with an outlet 114 and a water guide part that is recessed relative to the top surface of the drain board 100.
- the water guide part communicates with the outlet 114, and the water guide part
- the extension direction of the air inlet forms a fourth included angle with the direction from the air inlet to the air outlet;
- the height of the air duct assembly 200; the drainage plate 100 is provided with a water guide, which meets the drainage requirements through the water guide, and can also meet the needs of air supply and heat exchange, ensuring that the wind in the first cavity 282 can fully exchange heat with the evaporator 230 and then discharged; the drainage plate 100 with the water guide part cooperates with the evaporator 230, which can reduce the inclination angle of the evaporator 230; and then by setting the heating element 160 on the drainage plate 100 to save the height occupied by the heating and defrosting structure, Further reduce the height of the air duct assembly 200 .
- the cooperation of the evaporator 230 , the drain board 100 and the heating element 160 can fully reduce the height of the air duct assembly 200 .
- the heating element 160 covers the lower surface of the drain plate 100, which can avoid direct contact between the heating element 160 and the defrosting water received above the drain plate 100, thereby reducing potential safety hazards.
- parts such as the partition plate part 210, the air duct part 220, the first drainage part 260, the second drainage part 290, the fan 270, the fan cover 240, the drainage plate 100, the heating element 160 and the evaporator 230 can all adopt the above-mentioned implementation.
- the structure in the example will not be repeated here.
- the tank and refrigeration equipment When the air duct assembly 200 in the above embodiment is applied to the tank and refrigeration equipment, the tank and refrigeration equipment will have the above-mentioned beneficial effects.
- the tank includes a tank body 300 and an air duct assembly 200 disposed in the tank body 300 .
- the air duct assembly 200 divides the space in the tank body 300 into a first compartment 410 and a second compartment 420 .
- the tank body 300 is provided with a first passage 312, the inside of the partition member 210 is formed with a cavity 216, and the side of the partition member 210 is provided with a second passage 218, the first passage 312 and The second channels 218 correspond one to one, and the cavity 216 , the second channel 218 communicate with the first channel 312 .
- the second channel 218 may be disposed on the side of the second plate body 212 , or may be disposed on the side of the first plate body 211 .
- the first channel 312 and the second channel 218 are formed together.
- the styrofoam enters the styrofoam channel of the cavity 216, so that the partition part 210 can be foamed together with the tank body 300; before foaming, the evaporator 230, the air duct part 220 and the drainage plate 100 and other components can be advanced Assembled on the partition member 210 to form the air duct assembly 200, and then put the air duct assembly 200 into the tank body 300 for foaming together to realize a modular installation method; compared with the installation method in the related art, the installation is effectively simplified Steps, shorten the installation time, improve production efficiency.
- the cabinet body of the refrigeration equipment When the tank is applied to refrigeration equipment, the cabinet body of the refrigeration equipment includes a tank body 300, the tank body 300 is configured with a first channel 312, a cavity 216 is formed inside the partition member, and a second channel is provided on the side of the partition member.
- the second channel 218, the second channel 218, and the cavity 216 communicate with the first channel 312 to form a foaming space, realize the integral foaming of the air duct assembly and the tank body 300, and ensure the sealing performance of the connection part of the air duct assembly 200.
- the cabinet body 400 of the refrigerating equipment includes an outer shell located on the outside of the tank body 300, a foaming cavity is formed between the shell and the tank body 300, the tank body is configured with a first channel 312, and the interior of the partition member 210 is formed with a cavity Cavity 216, the second channel 218 is arranged on the side of the partition part, the foaming cavity, the second channel 218, the cavity 216 communicate with the first channel 312 to form a foaming space, and realize the integrated development of the air duct assembly and the cabinet body. Foam forming, simplifying the processing procedure.
- the partition member 210 is configured with a recess 217 communicating with the cavity 216, the recess 217 communicates with the second channel 218, the recess 217 is disposed on the periphery of the cavity 216, and the foam first passes through the second channel 218 enters the recess 217, and then enters the gap from different directions through the recess 217, so that the foaming glue quickly fills the entire gap to form the first thermal insulation layer 213, which shortens the foaming time and improves the foaming efficiency.
- the partition member 210 includes a first plate body 211 and a second plate body 212
- the edge of the second plate body 212 is recessed downward to form a recess 217 communicating with the cavity 216
- the recess 217 is U-shaped
- the second plate body 212 A through hole communicating with the concave portion 217 is provided on the side of the second channel 218 .
- the bottom of the second plate body 212 is provided with a groove, and the gap between the middle part of the second plate body 212 and the first plate body 211 is small, and the foaming glue enters the gap slowly during the foaming process.
- the foam glue By setting the recess 217 on the edge of the second plate body 212, the foam glue first enters the recess 217 through the second channel 218, and then enters the gap from different directions through the recess 217, so that the foam glue quickly fills the entire gap, forming the first An insulating layer 213 shortens the foaming time and improves the foaming efficiency.
- the tank body 300 is provided with a slot 311 , the side of the partition member 210 is snap-connected with the slot 311 , and the first channel 312 is a through hole provided in the slot 311 .
- the installation of the air duct assembly 200 can be completed by simply connecting the side of the partition member 210 with the card slot 311, and then foaming the partition member 210 and the tank body 300 together, which effectively simplifies The installation steps shorten the installation time and improve work efficiency.
- both the second channel 218 and the first channel 312 are in the form of through holes, and of course they can also be in the form of strip-shaped slits.
- the specific structural form of the installation structure is not limited to the slot 311, and a buckle or other connection structures may also be used.
- the tank of the refrigerating equipment further includes a return air component 430, and the return air component 430 is arranged on the inner wall of the first compartment 410, and the return air component 430 is connected to the first air inlet. 201 connected.
- the fan 270 starts, the air in the first chamber 410 enters the first cavity 282 through the return air component 430 to exchange heat with the evaporator 230, the temperature of the air decreases to become cold air, and the cold air passes through the first cavity again.
- the air outlet 203 and the second air outlet 204 respectively enter the first compartment 410 and the second compartment 420 .
- the return air component 430 By setting the return air component 430 on the inner wall of the first compartment 410, it is convenient to maintain the return air component 430, avoiding the influence of the foaming process on the return air component 430, simplifying the installation steps of the refrigeration equipment, and improving production efficiency Because the return air component 430 is located in the first chamber 410, the space between the tank body 300 and the shell is reduced, the storage space of the tank body 300 is increased, and the capacity of the tank body 300 is effectively improved.
- the return air component 430 includes a return air pipe 431, the inner wall of the first chamber 410 is provided with a positioning groove 313, the return air pipe 431 is embedded in the corresponding positioning groove 313, the air outlet of the return air pipe 431 is connected to the The corresponding first air inlets 201 are connected.
- the space occupied by the return air component 430 is reduced, which helps to improve the storage space of the refrigeration equipment, and provides a large-capacity refrigeration equipment.
- the air outlet of the air return pipe 431 is detachably connected to the first air inlet 201
- the air outlet of the return air pipe 431 is detachably connected to the first air inlet 201
- the shape and size of the first air inlet 201 are adapted to the shape and size of the air outlet of the air return component 430 .
- the first air inlet 201 can be disposed on the side of the first plate body 211 , or can be disposed on the side of the second plate body 212 .
- the return air duct 431 is arranged along the up and down direction, the upper end of the return air duct 431 is formed with the main return air outlet 432 communicated with the air outlet of the return air duct 431, and one side of the return air duct 431 is formed with a The air outlet of the air duct 431 communicates with the auxiliary air return port 433 .
- the return air component 430 includes two return air pipes 431.
- the left side wall and the right side wall of the first compartment 410 are respectively provided with positioning grooves 313 extending up and down.
- the positioning grooves 313 are respectively located on the left side wall and the right side wall near the door body.
- the two air return pipes 431 are respectively embedded in the corresponding positioning grooves 313 .
- the return air component 430 can return the cold air near the door to the first cavity 282 through the return air component 430 for heating.
- the exchange effectively prevents the cold air coming out of the air outlet from directly entering the return air component 430, thereby improving the cooling efficiency of the refrigeration equipment.
- an embodiment of the refrigeration equipment is provided in combination with the above-mentioned air duct assembly.
- the refrigeration equipment includes a cabinet body and an air duct assembly.
- the air duct assembly is located in the cabinet and separates the first room and the second room.
- the air duct assembly includes a partition part, an air duct part, an evaporator and a drain plate.
- the partition part and The air duct part limits the first cavity, the first air inlet, the second air inlet, the first air exhaust port and the second air exhaust port, the first air inlet, the first cavity, the first air exhaust port and the first air outlet
- the compartments are suitable for communication, and the second air inlet, the first cavity, the second air outlet and the second compartment are suitable for communication;
- the evaporator and the drain plate are arranged in the first cavity, and the air duct part supports the drain plate, and the drain plate Located below the evaporator, the angle between the evaporator and the horizontal plane is less than or equal to a preset angle, or the evaporator is parallel to the horizontal plane.
- the evaporator is placed horizontally in the air duct assembly, and the downward inclination angle of the evaporator relative to the horizontal plane can be controlled within a preset angle, or the evaporator can be installed horizontally, which can reduce the height space occupied by the evaporator, thereby reducing
- the overall height of the small air duct assembly can reduce the space in the cabinet occupied by the air duct assembly, the storage space in the cabinet can be increased accordingly, and a large-capacity refrigeration device can be provided.
- the first compartment is located above the second compartment, the first compartment is a refrigerator compartment, and the second compartment is a freezer compartment.
- the first air inlet is located on the left side and the right side of the air duct assembly and close to the front side of the air duct assembly, and the first air inlet communicates with the first chamber above the air duct assembly.
- the second air inlet is located on the front side of the air duct assembly, and the second air inlet communicates with the second chamber below the air duct assembly.
- the drainage board can be one or more of the above-mentioned structures.
- the drainage structure of the air duct assembly can be the above-mentioned drainage methods, such as the first drainage part for side drainage, the second drainage part for rear drainage, or the water guide 223 for drainage, or a combination of multiple drainage methods.
- the air duct assembly also includes a fan 270, which is arranged on one side of the evaporator.
- the fan 270 can be arranged horizontally or vertically.
- the air duct assembly 200 also includes structures such as a fan cover and a fan cover 243 used in conjunction with the fan, which can also be referred to above, and will not be repeated here.
- tank body 300 partition plate part 210 , air duct part 220 and other structures, reference can be made to the above content, and details will not be repeated here.
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Abstract
本公开涉及制冷设备技术领域,提供一种制冷设备,包括柜体和风道组件,风道组件位于柜体内并分隔出第一间室和第二间室,风道组件包括隔板部件、风道部件、蒸发器和排水板,隔板部件与风道部件限制出第一腔体、第一进风口、第二进风口、第一排风口和第二排风口,第一进风口、第一腔体、第一排风口和第一间室适于连通,第二进风口、第一腔体、第二排风口和第二间室适于连通;第一腔体内设置蒸发器和排水板,蒸发器与水平面的夹角小于或等于预设角度,或,蒸发器与水平面相平行。本公开提出的制冷设备,蒸发器所占用的高度空间减小,减小风道组件所占用柜体内的空间,以起到扩大柜体内容量的作用,提供一种大容量的制冷设备。
Description
相关申请的交叉引用
本公开要求于2021年12月30日提交的申请号为202111653846.1,发明名称为“制冷设备”的中国专利申请的优先权,其通过引用方式全部并入本公开。
本公开涉及制冷设备技术领域,尤其涉及制冷设备。
随着生活品质的提升,消费者对于制冷设备内存储空间需求越来越高,制冷设备(如冰箱)内存储空间的大小也成为消费者的关注点。如何在制冷设备体积不变的情况下增大其内的存储空间,成为技术人员的一个研发方向。其中,制冷系统的部件需要占用柜体的一部分体积,制冷系统的部件在柜体内的安装位置,会影响柜体的体积以及柜体限制出存储空间的大小。制冷系统中的蒸发器设置在冰箱的制冷间室的后侧,柜体的厚度较大,柜体深度方向的存储空间不足,用户体验不佳。
发明内容
本公开旨在至少解决相关技术中存在的技术问题之一。为此,本公开提出一种制冷设备,风道组件横置在柜体内,风道组件的高度和体积均减小,制冷设备的空间扩大,提升了制冷设备的容量。
根据本公开实施例的制冷设备,包括:
柜体;
风道组件,位于所述柜体内并分隔出第一间室和第二间室,包括隔板部件、风道部件、蒸发器和排水板,所述隔板部件与所述风道部件限制出第一腔体、第一进风口、第二进风口、第一排风口和第二排风口,所述第一进风口、第一腔体、第一排风口和所述第一间室适于连通,所述第二进风口、所述第一腔体、所述第二排风口和所述第二间室适于连通;所述第一腔体内设置所述蒸发器和所述排水板,所述风道部件支撑所述排水板,所述蒸发器与水平面的夹角小于或等于预设角度,或,所述蒸发器与水平面相平行。
根据本公开实施例的制冷设备,包括柜体和设置在柜体内的风道组件,风道组件横置在柜体内,以分隔出两个间室,风道组件包括隔板部件和风道部件,隔板部件与风道部件之间设置有蒸发器,蒸发器横置在风道组件内,蒸发器与水平面形成的夹角在预设角度内,或,蒸发器与水平面相平行,通过将蒸发器与水平面的夹角限定在预设角度内,可限制蒸发器的高度,蒸发器的高度减小,则风道组件所占用柜体内的空间减小,进而可扩大柜体的容量,以增大制冷设备的容量。
根据本公开的一个实施例,所述排水板构造有相对于所述排水板的顶面向下凹陷的导水部,所述导水部的延伸方向与所述风道组件的出风方向形成第四夹角。风道组件内的风可沿导水部的延伸方向流动,延缓风沿出风方向流出,延长风在风道组件内的换热时间,优化换热效果。
根据本公开的一个实施例,所述排水板构造有相对于所述排水板的顶面向下凹陷的排水部,所述排水部构造有出口,所述排水部与所述导水部连通。排水部的延伸方向不作限定,排水板所承接的水可沿出口排出,保证换热和排水效果。
根据本公开的一个实施例,朝向所述排水部的方向,所述导水部的底部沿第一方向倾斜,所述第一方向与所述排水板的顶面形成第六夹角,以使所述导水部向所述排水部的方向凹陷的深度逐渐增大。以便导水部内的水流入排水部,提升排水效率,保证排水效果。
根据本公开的一个实施例,朝向所述出口的方向,所述排水部的底部沿第二方向倾斜,所述第二方向与所述排水板的顶面形成第七夹角,以使所述排水部向所述出口的方向凹陷的深度逐渐增大。以便排水部内的水排出排水板。
根据本公开的一个实施例,所述风道部件设置有导水件,所述导水件的一侧朝向所述出 口并与所述出口连通,所述导水件的另一侧构造出排水口,向背离出口的方向,导水件向下倾斜,以便导水件将水导出。
根据本公开的一个实施例,所述导水部延伸至所述排水板的端部并形成开口,所述开口所在侧设置有第一排水部件,导水部的开口可起到排水的作用。
根据本公开的一个实施例,还包括风机,所述风机的转动轴线与竖直方向形成第一夹角。风机横向设置,减小风机所占用的高度空间,缩小风道组件所占用的空间。
根据本公开的一个实施例,还包括风机和风机盖板,所述风机设于所述蒸发器的一侧,所述风机盖板位于所述风机与所述蒸发器之间,所述风机的进口通过所述风机盖板的通风口与所述第一腔体连通,所述风机盖板构造有所述第一排风口和所述第二排风口。此时不限定风机的安装方式,可横向设置或竖向设置。
根据本公开的一个实施例,所述柜体包括箱胆本体,所述箱胆本体构造有第一通道,所述隔板部件的内部形成有空腔,所述隔板部件的侧边设置有第二通道,所述第二通道、所述空腔与所述第一通道连通,以形成发泡空间。风道组件与箱胆本体一体发泡,可解决风道组件与箱胆本体之间产生安装间隙的问题,保证第一间室与第二间室的独立性。
根据本公开的一个实施例,所述隔板部件包括:
第一板体;
第二板体,设置于所述第一板体的下方,所述第二板体与所述第一板体围成所述空腔,所述第二板体的边沿向下凹陷形成有与所述空腔连通的凹部,所述凹部与所述第二通道连通,可优化发泡工序,提高生产效率。
根据本公开的一个实施例,所述隔板部件与所述风道部件中的至少一个设置有分隔部,所述分隔部在所述第一进风口处的正投影覆盖所述第一进风口的局部面积,所述正投影位于所述第一进风口靠近所述第二进风口的一端,所述分隔部与所述第一进风口之间间隔预设间距,对第一进风口的部分进风进行导流,减少两个进风口的进风中交叉接触的风量,减少进风交叉接触位置的结霜量,延长化霜间隔时长,减少化霜能耗。
根据本公开的一个实施例,所述第二进风口设置于所述风道部件的前侧,所述隔板部件的前侧设置有遮盖所述第二进风口的安装部,在保证第二进风口的通风效果的情况下,隐藏第二进风口,避免第二进风口进入杂物,也保证风道组件前端结构的整体性。
根据本公开的一个实施例,所述第一进风口位于所述风道组件的左侧和右侧且靠近所述风道组件的前侧。
根据本公开的一个实施例,所述第一间室位于所述第二间室的上方,所述第一间室为冷藏室,所述第二间室为冷冻室。
本公开的附加方面和优点将在下面的描述中部分给出,部分将从下面的描述中变得明显,或通过本公开的实践了解到。
为了更清楚地说明本公开实施例或相关技术中的技术方案,下面将对实施例或相关技术描述中所需要使用的附图作简单地介绍,显而易见地,下面描述中的附图仅仅是本公开的一些实施例,对于本领域普通技术人员来讲,在不付出创造性劳动的前提下,还可以根据这些附图获得其他的附图。
图1是本公开实施例提供的一种制冷设备的结构示意图,图中未示意门体;
图2是本公开实施例提供的一种制冷设备的局部结构示意图,图中未显示柜体的局部结构及箱胆;
图3是图2中A的局部放大结构示意图;
图4是本公开实施例提供的一种风道组件的局部结构示意图;
图5是本公开实施例提供的一种风道组件的部分结构分解状态示意图;
图6是本公开实施例提供的一种风道组件的分解状态结构示意图;
图7是本公开实施例提供的一种风道组件的局部俯视示意图,图中未显示排水板上方部件;
图8是图7中B-B剖视结构示意图;
图9是本公开实施例提供的一种风道组件的局部结构的侧视结构示意图;
图10是本公开实施例提供的另一种制冷设备的局部结构示意图,与图2的主要区别在于,排水板的结构不同,图中未示意门体;
图11是图10中C部位的局部放大结构示意图;
图12是本公开实施例提供的另一种风道组件的局部结构示意图,图中未示意排水板上方的部件;
图13是本公开实施例提供的另一种风道组件的部分结构分解状态的示意图;
图14是本公开实施例提供的第三种风道组件的纵向剖视结构示意图,以显示风机的位置;
图15是本公开实施例提供的第三种风道组件的局部结构示意图,图中未示意排水板上方的部件;
图16是本公开实施例提供的第三种风道组件的部分结构分解状态的示意图;
图17是本公开实施例提供的第三种制冷设备的结构示意图,图中未示意门体;
图18是本公开实施例提供的第三种制冷设备的纵向剖视结构示意图;
图19是图18中D部位的局部放大结构示意图;
图20是本公开实施例提供的第四种风道组件的分解状态结构示意图;
图21是本公开实施例提供的第四种风道组件的仰视结构示意图;
图22是本公开实施例提供的排水板的立体结构示意图;
图23是本公开实施例提供的排水板的俯视结构示意图;
图24是图23中E-E剖视结构示意图;
图25是图23中F-F剖视结构示意图;
图26是本公开实施例提供的风道组件的隔板部件中第二板体及其安装状态的结构示意图;
图27是本公开实施例提供的风道组件的隔板部件中另一种第二板体及其安装状态的结构示意图;
图28是本公开实施例提供的风道组件的隔板部件中第二板体的第一内凹部与第二内凹部的结构示意图;
图29是本公开实施例提供的风道组件的隔板部件中第二板体的第三内凹部的结构示意图;
图30是本公开实施例提供的蒸发器与排水板安装状态的立体结构示意图;
图31是本公开实施例提供的蒸发器与排水板安装状态侧视结构示意图;
图32是本公开实施例提供的蒸发器、排水板及加热件的分解状态示意图之一;
图33是本公开实施例提供的蒸发器、排水板及加热件的分解状态示意图之二;
图34是本公开实施例提供的蒸发器、排水板及第二加热器的安装状态示意图;
图35是本公开实施例提供的蒸发器、排水板及第二加热器的分解状态示意图;
图36是本公开实施例提供的蒸发器、排水板及风道部件的安装状态示意图;
图37是本公开实施例提供的风道部件中第一支撑部的结构示意图;
图38是图37中H部位的局部放大结构示意图;
图39是本公开实施例提供的隔板部件的俯视结构示意图;
图40是图39中A-A的剖视结构示意图;
图41是本公开实施例提供的箱胆的分解状态的结构示意图。
附图标记:
100、排水板;110、排水部;111、第一排水部;112、第二排水部;113、第二导流面;114、出口;115、第三排水部;120、第一导水部;121、第一导流面;123、第一导水区;124、第二导水区;130、第二导水部;131、第三导流面;140、第三导水部;141、第四导流面;150、翻边;151、定位部;160、加热件;170、开口;
200、风道组件;201、第一进风口;202、第二进风口;203、第一排风口;204、第二排风口;
210、隔板部件;211、第一板体;212、第二板体;2121、第一内凹部;2122、第一引导面;2123、第一顶面;2124、第二内凹部;2125、第二引导面;2126、第二顶面;2127、第三内凹部;2128、第三顶面;2129、第三引导面;213、第一保温层;214、第三板体;215、第三壁板;216、空腔;217、凹部;218、第二通道;
220、风道部件;221、第二保温层;222、第一支撑部;2221、分隔部;2222、导向面;22221、曲面部;22222、平面部;2223、导流板;2224、第二支撑斜面;2225、第二支撑凹槽;223、导水件;2231、第三排水管;224、第三保温层;225、第二支撑部;226、加热部件;
230、蒸发器;231、第一加热器;232、第二加热器;233、换热管;234、散热片;2341、第一散热片;2342、第二散热片;23421、通风部;2343、安装孔;
240、风机罩;241、第一罩体;2411、导流表面;242、第二罩体;2421、第一导水通道;2422、隔挡部;2423、第三排水口;2424、第一导风部;2425、第二导风部;2426、第二安装柱;2427、分隔板;2428、集水部;243、风机盖板;2431、第三导风部;2432、第四导风部;244、通风口;
250、第一风门;
260、第一排水部件;262、第一排水口;263、第一排水管;264、第一壁板;265、第二壁板;
270、风机;271、风机安装座;
281、第二腔体;282、第一腔体;
290、第二排水部件;291、第二排水管;
300、箱胆本体;312、第一通道;311、卡槽;313、定位槽;
400、柜体;410、第一间室;420、第二间室;430、回风部件;
431、回风管;432、主回风口;433、辅助回风口;
α
1、第一夹角;α
2、第二夹角;α
3、第三夹角;
θ
2、第六夹角;θ
3、第七夹角。
下面结合附图和实施例对本公开的实施方式作进一步详细描述。以下实施例用于说明本公开,但不能用来限制本公开的范围。
在本公开实施例的描述中,需要说明的是,术语“中心”、“纵向”、“横向”、“上”、“下”、“前”、“后”、“左”、“右”、“竖直”、“水平”、“顶”、“底”、“内”、“外”等指示的方位或位置关系为基于附图所示的方位或位置关系,仅是为了便于描述本公开实施例和简化描述,而不是指示或暗示所指的装置或元件必须具有特定的方位、以特定的方位构造和操作,因此不能理解为对本公开实施例的限制。此外,术语“第一”、“第二”、“第三”仅用于描述目的,而不能理解为指示或暗示相对重要性。此外,在本公开的描述中,除非另有说明,“多个”、“多根”、“多组”的含义是两个或两个以上。
在本公开实施例的描述中,需要说明的是,除非另有明确的规定和限定,术语“相连”、“连接”应做广义理解,例如,可以是固定连接,也可以是可拆卸连接,或一体连接;可以是机械连接,也可以是电连接;可以是直接相连,也可以通过中间媒介间接相连。对于本领域的普通技术人员而言,可以具体情况理解上述术语在本公开实施例中的具体含义。
在本公开实施例中,除非另有明确的规定和限定,第一特征在第二特征“上”或“下”可以是第一和第二特征直接接触,或第一和第二特征通过中间媒介间接接触。而且,第一特征在第二特征“之上”、“上方”和“上面”可是第一特征在第二特征正上方或斜上方,或仅仅表示第一特征水平高度高于第二特征。第一特征在第二特征“之下”、“下方”和“下面”可以是第一特征在第二特征正下方或斜下方,或仅仅表示第一特征水平高度小于第二特征。
在本说明书的描述中,参考术语“一个实施例”、“一些实施例”、“示例”、“具体示例”、或“一些示例”等的描述意指结合该实施例或示例描述的具体特征、结构、材料或者特点包含于本公开实施例的至少一个实施例或示例中。在本说明书中,对上述术语的示意性表述不必须针对的是相同的实施例或示例。而且,描述的具体特征、结构、材料或者特点可以在任一个或多个实施例或示例中以合适的方式结合。此外,在不相互矛盾的情况下,本领域的技术人员可以将本说明书中描述的不同实施例或示例以及不同实施例或示例的特征进行结合和组合。
本公开的实施例,结合图1至图41所示,提供一种制冷设备,包括柜体400,柜体400包括箱胆。
制冷设备可以为冰箱、冰柜、展示柜、售卖柜或酒柜等多种设备,制冷设备可用于冷藏或冷冻。
其中,下述实施例中,前后左右上下的方位,与制冷设备的方位一一对应。
本公开的实施例,提供一种箱胆,箱胆包括箱胆本体300和风道组件200,箱胆本体300内的空间通过风道组件200分隔出相互独立的第一间室410和第二间室420。
风道组件200可起到分隔间室的作用,还可以起到循环送风的作用。需要说明的是,为了保证第一间室410与第二间室420的独立性,风道组件200与箱胆本体300的安装处需要保证密封,避免第一间室410与第二间室420之间串风。
本公开的实施例,提供一种风道组件200,风道组件200可将箱胆本体300内的全部空间分成第一间室410和第二间室420两部分,或者,风道组件200将箱胆本体300内的局部空间分隔成第一间室410和第二间室420两部分。
风道组件200向第一间室410和第二间室420独立送风,第一间室410与第二间室420的功能可相同或不同。当第一间室410与第二间室420的功能不同,也就是第一间室410与第二间室420内的环境温度不同,第一间室410可为冷藏室,第二间室420可为冷冻室,则风道组件200向冷藏室送风的频率低于向冷冻室送风的温度。当第一间室410与第二间室420的功能相同,如均为冷藏室,两个冷藏室的环境温度可相同或不同,此时,风道组件200向两个冷藏室送风的频率可相同或不同,具体可根据需要设置。当然,风道组件200分隔出的间室,功能不限于冷藏和冷冻,还可以为变温间室或其他功能间室,具体可根据需要设置。
当柜体400连接门体,门体在封闭柜体400的位置,则第一间室410与第二间室420为两个密闭且独立的空间;门体在打开柜体400的位置,则可从第一间室410与第二间室420中的至少一个取放物品。
其中,风道组件200在制冷设备内设置的数量可根据需要设置。
可以理解的是,如图2至图3、图10、图11以及图17至图20所示,风道组件200包括隔板部件210、风道部件220、蒸发器230和排水板100,隔板部件210位于风道部件220的上方,隔板部件210与风道部件220构造出第一腔体282、适于与第一腔体282连通的进风口和适于与第一腔体282连通的排风口,第一腔体282内设置蒸发器230与排水板100,排水板100位于蒸发器230的下方。隔板部件210和风道部件220共同限制出相连通的进风口、第一腔体282和排风口,以便进入风道组件200的风换热后排出。
如图1和图2所示,隔板部件210连接于箱胆本体300,并使隔板部件210与箱胆本体300的连接处相密封,以将箱胆本体300内的空间分隔出相互独立的第一间室410和第二间室420。隔板部件210与风道部件220之间的第一腔体282用于安装蒸发器230、排水板100、用于化霜的加热结构等部件,以满足第一间室410与第二间室420的换热需求。
风道组件200的进风口分为第一进风口201和第二进风口202,风道组件200的排风口分为第一排风口203和第二排风口204,第一进风口201、第一腔体282、第一排风口203与第一间室410连通形成第一循环路径,第二进风口202、第一腔体282、第二排风口204与第二间室420连通形成第二循环路径,第一循环路径与第二循环路径中的至少一个连通,以向第一间室410与第二间室420送风。第一进风口201、第二进风口202、第一排风口203以及第二排风口204的数量和位置不作限定。
如图1和图2所示,第一间室410位于风道组件200的上方,第一间室410被设置为冷藏室,第二间室420位于风道组件200的下方,第二间室420被设置为冷冻室,也就是第一间室410位于第二间室420的上方,风道组件200设置有朝向上方的第一排风口203和朝向下方的第二排风口204;并在第一排风口203处设置第一风门250,以便开闭调节;在第二排风口204处设置第二风门,以便开闭调节。风道组件200靠向前端的位置设置有第一进风口201和第二进风口202,第一进风口201与冷藏室的回风风道连通,第一进风口201设置在风道组件200的左右两侧,第二进风口202与冷冻室连通,第二进风口202设置在风道组件200的前侧或下侧。
需要说明的是,第一进风口201与第二进风口202靠近风道组件200的同一端,第一排风口203与第二排风口204也靠近风道组件200的同一端,且进风口与排风口一般在相对的两端,如上述的进风口靠近前端,排风口靠近后端,但不限定前述的位置,进风口还可以均靠近左端或右端,进风口与排风口的位置灵活,具体可根据需要选择。
一些情况下,第一进风口201位于第一腔体282的第一侧,第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻,也就是第一进风口201与第二进风口202设置在风道组件200的不同侧,此时,第一进风口201的进风与第二进风口202的进风会在第一腔体282内交汇,当第一进风口201与第二进风口202具有不同的进风温度(也就是第一间室410与第二间室420的环境温度不同),第一进风口201的进风与第二进风口202的进风交汇处因接触换热而容易结霜。第一进风口201与第二进风口202位于风道组件200的不同侧,还可以理解为,第一进风口201与第二进风口202形成夹角。
如图6所示,上述的第一侧为左侧与右侧中的至少一个,第二侧为前侧。
下面,结合图1至图16以及图20至图25所示,提供排水板100的实施例,以排水板100安装于上述的风道组件200内为例,对排水板100的结构进行说明。但排水板100不限于安装在上述的风道组件200内,其他适于安装下述实施例中的排水板100的结构,亦可安装下述的排水板100。
本公开的实施例,结合图1至图7所示,提供一种排水板100,排水板100构造有相对于排水板100的顶面向下凹陷的导水部,导水部向预设面的两侧延伸至排水板100的边缘,以使排水板100的边缘形成开口170,开口170朝向第一进风口201所在侧,以使第一进风口201的部分进风适于通过开口170并沿导水部的延伸方向流入第一腔体282内。
此处的第一进风口201的功能不限,可以与冷藏室连通,导水部对冷藏风进行导向;或者,导水部与冷冻室连通,还可以对冷冻风进行导向。通过设置导水部,将排水板设计为倒V型结构,使部分冷藏回风通过V型结构空间进入蒸发器230,以解决冰箱回风凝结的问题,减少冷藏回风与冷冻回风的接触,减少与冷冻回风聚集混合冷凝,使霜更均匀分布在蒸发器内,减少霜堵塞冷冻回风。
第一进风口201的部分进风通过开口170并沿导水部的延伸方向导入第一腔体282内,可将第一进风口201的一部分进风进行分流,减少与第二进风口202的进风交汇的风量,进而减少因第一进风口201的进风与第二进风口202的进风接触而凝结的霜,延长两次化霜之间间隔的时长,减少化霜次数,减少化霜所需的耗电量,减少制冷设备的耗电量。
导水部相对于排水板100的顶面向下凹陷,则使得排水板100形成凹槽,第一进风口201的一部分进风可沿凹槽向第一腔体282的内部流动,导水部可对其内的风起到导流的作用。
其中,预设面与导水部的延伸方向形成夹角,预设面沿进风口向排风口的方向延伸,如进风口位于风道组件200的前端,排风口位于风道组件200的后端,则预设面从前向后延伸。此处,预设面的延伸趋势为从前向后即可,预设面可倾斜延伸,预设面的位置可根据需要选择。
一些情况下,预设面可为排水板100的对称面,预设面的两侧对称设置导水部,使得排水板100为对称结构,排水板100的结构稳定性更好。
当然,预设面不限于为对称面,开口170可设置在排水板100的一侧或两侧。当开口170设置在排水板100的一侧,预设面可为排水板100的一个侧面,此侧面位于第一进风口201的相对侧;当开口170设置在排水板100的两侧,预设面可以为从前向后延伸的任意面。
上述排水板100的开口170,可起到对第一进风口201的部分进风进行导流的作用,排水板100的开口170还可以起到排水的作用。
在排水板100的开口170起到分流一部分进风的作用时,导水部相对于排水板100的顶面凹陷的深度可不作限定。
一些情况下,朝向开口170的方向,导水部凹陷的深度逐渐增大,此种结构的导水部可称为第二导水部130。也就是,第二导水部130朝向开口170的一端深度较大,有助于引导风在其内流动。当蒸发器230放置在排水板100上方,第二导水部130的深度逐渐增大,也能增大蒸发器230与排水板100之间的间距,适当扩大风的流动空间;还有助于排水板100承接的化霜水从开口170排水。
其中,第二导水部130的深度朝向开口170的一端逐渐增大,可以为连续增大,或呈阶梯状增大。
可以理解的是,朝向开口170的方向,第二导水部130的底部沿第一预设方向倾斜,第一预设方向与排水板100的顶面形成第一预设夹角。也就是,第二导水部130的底面为沿第一预设方向向下延伸的斜面,有助于风向第一腔体282内流动和也方便排水。
第一预设方向为,与顶面形成第一预设夹角、且沿预设面向开口170斜向下倾斜的方向,第一预设夹角的大小可根据需要选择。
为了减小排水板100在高度方向的尺寸,第一预设夹角可为小于或等于7°的夹角,排水效果和导风效果均能满足需求,还能减小风道组件200高度方向的尺寸,减小风道组件200所占用柜体400内的高度方向空间,有助于增大柜体400内的间室空间,以便提供大容量的制冷设备。
一些情况下,第一预设夹角设置为3°,3°能够满足排水板100的排水需求,还能充分减小排水板100的高度,实现小角度排水。当然,第一预设夹角还可以设置为1°、2°、4°、5°、6°或7°。
当然,第二导水部凹陷的深度还可以不变(图中未示意),第二导水部凹陷的深度保持一致,也能起到导风和排水的作用。
可以理解的是,导水部包括沿导水部延伸方向设置的导流面,从排水板100的顶面向底面的方向,导流面向其相对的侧面靠近。也就是第二导水部130沿其延伸方向设置有第三导流面131,从排水板100的顶面向底面的方向,第三导流面131向相对的侧面靠近,第三导流面131为向其相对侧倾斜的斜面。
排水板100顶面以及第三导流面131承接的化霜水,可沿第三导流面131的导流方向落入导水部的底部,以使化霜水在导水部内聚集,以便导水部内的水排出。
第三导流面131相对的侧面可为竖直设置的面,或也为导流面,具体可根据需要选择。如图5和图6所示,第二导水部130的两个相对侧面均为第三导流面131。
如图5至图7所示,排水板100的预设面的每侧均设置多个第二导水部130,多个第二导水部130并列设置,在排水板100的两侧均形成多个开口170,以便第一进风口201的部分进风可沿多个开口170进入第一腔体282。
在预设高度位置,第二导水部130的宽度,朝向开口170的方向逐渐减小,方便第二导水部130内承接的水向开口170的方向汇集。
结合图1至图7所示以及上述内容,具有上述的第二导水部130的排水板100,可不设置排水部110。
结合图1至图16、图20至图25所示,本公开实施例,提供另一种排水板100,排水板100构造有相对于排水板100的顶面凹陷的导水部,导水部的延伸方向与排水板100上方的出风方向形成第四夹角。
当上述的排水板100与蒸发器230均设置在风道组件200的第一腔体282内,风从风道组件200的进风口进入第一腔体282并向排风口的方向流动,第一腔体282内的风会在排水板100与蒸发器230之间的空间以及蒸发器230内部的空间流动。风在排水板100与蒸发器230之间流动时,导水部与出风方向形成第四夹角,可抑制风从导水部直接流向排风口,以延长风在第一腔体282内停留的时间,以使风充分与蒸发器230接触并进行换热,换热后 的风再从排风口排出,有助于提升换热效率。
其中,出风方向为进风口向排风口的方向,一些情况下,进风口与排风口仅设置一个,为一一对应的关系,形成一个出风方向;一些情况下,进风口或排风口中的至少一个设置多个,可形成多个出风方向。导水部的延伸方向与至少一个出风方向形成夹角,可在一个方向上,保证风的换热效率;当然,导水部的延伸方向与所有的出风方向均形成夹角,则可保证多个流动路径中的风均能有效换热,可保证换热效率。其中,进风口一般设置在风道组件200靠前的一端,排风口一般设置在风道组件200靠后的一端,则出风方向可为从前向后的方向。
当进风口分为第一进风口201和第二进风口202,第二进风口202设置在风道组件200的前方,排风口设置在风道组件200的后方,第二进风口202与排风口的连通路径形成第一出风方向,第二进风口202对应于蒸发器230靠下的位置,则风沿从下向上、从前向后的方向流动。
本实施例的排水板100,导水部的延伸方向与第一出风方向形成夹角,也就是导水部的延伸方向与前后方向形成夹角。第一进风口201可设置在风道组件200的左右两侧中的至少一个,第一进风口201与排风口的连通路径形成第二出风方向,导水部的延伸方向与第二出风方向也形成夹角。导水部的延伸方向与第一出风方向形成的夹角,导水部的延伸方向与第二出风方向也形成夹角,均可理解为第四夹角,但具体的角度值可相同或不同。
导水部的延伸方向可以为直线路径或曲线路径。当导水部的延伸路径为直线路径,导水部远离排水部110的一端到导水部连通排水部110的另一端的路径为延伸路径;当导水部的延伸路径为曲线路径,曲线路径的导水部可具有多个与排水部110连通的端头,曲线路径可为多段直线路径连通形成的折线路径,或,曲线路径为具有一个或多个曲率半径的曲线,曲线路径的形状可根据需要设置。一个导水部的延伸方向可与出风方向形成一个或多个夹角,也就是第四夹角可以为一个或多个角度值,具体可根据需要设置。
结合图10至图25所示,本公开实施例,提供另一种排水板100,排水板100构造有排水部110和导水部,排水部110构造有出口114,排水部110相对于排水板100的顶面凹陷;导水部与排水部110连通,导水部相对于排水板100的顶面凹陷,导水部的延伸方向与排水板100上方的出风方向形成第五夹角θ1。
在使用状态,排水板100设置在蒸发器230的下方,用于承接蒸发器230表面的霜遇热而产生的化霜水。一部分水落入导水部并沿导水部的延伸方向导入排水部110,导水部一般设置多个,各个导水部承接到的水汇集到排水部110并通过排水部110的出口114排出。另一部分水直接落入排水部110并通过排水部110排出。
其中,第五夹角与第四夹角的区别在于,同时设置有导水部和排水部的排水板中,导水部的延伸方向与出风方向形成的夹角为第五夹角;仅设置有导水部的排水板中,导水部的延伸方向与出风方向形成的夹角为第四夹角。第五夹角与第四夹角的角度数值可根据需要选择,此处不作限定。
图23中排水板100上方的实线箭头示意了导水部的延伸方向,虚线箭头示意了出风方向,并标示第五夹角θ1,图中示意了第五夹角为90°的情况。需要说明的是,导水部和排水部110均基于排水板100的顶面凹陷,顶面可以为平面或曲面,顶面可为多条线限制出的面,或多个面限制出的面。与之对应的,导水部的底部以及排水部110的底部形成排水板100的底面,底面也可以为平面或曲面,底面可为多条线限制出的面,或多个面限制出的面。排水板100的上表面为排水板100朝向上方的全部表面,顶面为上表面的一部分;排水板100的下表面为排水板100朝向下方的全部表面,底面为下表面的一部分。
本实施例的排水板100,导水部与排水部110配合,可将承接的水排出,解决风道组件200内排水的问题,并且,通过将导水部设置为延伸方向与风道组件200的出风方向形成夹角,可延长风在风道组件200内停留的时间,也就是延长换热时间,以提升换热效率,满足制冷设备的制冷需求;并排水板100的结构简单。
本公开实施例的排水板100结构,当导水部相对于排水板100的顶面向下凹陷的深度不变,且排水板100构造有相对于排水板100的顶面凹陷的排水部110,此导水部可称之为第三导水部140,如图11至图13所示,排水部110构造有出口114,第三导水部140与排水部110连通,第三导水部140承接的化霜水可从排水板100端部的开口170排出,还可以从排水部110的出口114排出,实现多方位排水,结构简单且排水效果好。
此时,蒸发器230与排水板100可水平放置,能完成化霜水的排放,还能减小风道组件200的高度。若蒸发器230与排水板100均斜向下设置进行排水,可减小蒸发器230与排水板100向下倾斜的角度(蒸发器230与排水板100向下倾斜的角度可小于或等于7°),进而减小风道组件200高度方向的尺寸,可起到扩大制冷设备内容量的作用。
排水部110的出口114与排风口位于第一腔体282的同侧,排水部位与排风部位位于第一腔体282的同侧,方便将排水结构与排风结构集成在一起。
当风道组件200内设置有风机270,风机270与排风口位于同侧,也就是出口114、排风口和风机270均位于同侧,风机270的化霜水可随排水板100的化霜水一同排出。
沿排水部110的延伸方向,排水部110的两侧均并列设置多个第三导水部140,多个第三导水部140分布在蒸发器230的下方,以便在蒸发器230下方的多个位置承接化霜水,有助于快速排水。
排水部110也可设置多个,多个排水部110可相平行或形成夹角。在排水板100的面积不变的情况下,排水部110的数量越多,第三导水部140的长度越短,有助于第三导水部140承接的水在排水部110内汇集,以便缩短化霜排水时间。当排水部110设置多个,则靠近排水板边缘的第三导水部140具有开口,其他第三导水部140与排水部110连通。
可以理解的是,朝向出口114的方向,排水部110凹陷的深度逐渐增大,以便排水部110内的水在重力作用下流向出口114。
可以理解的是,排水部110的底部沿第二方向倾斜,第二方向与排水板100的顶面形成第七夹角θ3。也就是排水部110的底部倾斜,排水部110内的水沿倾斜路径(第二方向)汇集到出口114并排出,排水效果好,可避免出现局部积水的问题;并且水能平稳流动。
当排水板100的顶面水平设置,可以理解为,第二方向与水平面形成第七夹角θ3。沿排水板100的顶面,朝向出口114的位置逐渐向下凹陷形成排水部110。此时,第七夹角θ3为排水部110的底部与水平面的夹角,第二方向为斜向下的方向。
其中,排水部110的底部,可以为斜线或斜面,一些情况下,排水部110的底部为斜面,斜面可以为平面或曲面,具体可根据需要选择。
一些情况下,排水部110的底部不形成连续的斜线或斜面,如阶梯状,依然能够满足排水需求。
可以理解的是,第七夹角θ3可小于或等于7°,第七夹角θ3的角度小,有助于减小排水板100顶面到底面的距离,可实现小角度排水,进而减小风道组件200在高度方向的尺寸,缩小风道组件200所占用的空间,有助于提升制冷设备的储物空间,提供一种大容量的制冷设备。
需要说明的是,第七夹角θ3也可大于7°,由于排水部110所占用排水板100的面积较少,排水部110向下倾斜的角度稍大,对排水板100的整体体积影响不大,因此,对第七夹角θ3的角度不做严格限定。
一些情况下,如图12所示,排水部110凹陷的深度不变,此时排水部可称为第三排水部115,排水板100向出口114方向倾斜,以方便排水。如出口114位于风道组件200的后端,排水板100从前向后斜向下倾斜,以便排水部110内的水向后流动并排出。
如图11和图12所示,第三导水部140包括沿第三导水部140延伸方向设置的第四导流面141,从排水板100的顶面向底面的方向,第四导流面141向其相对的侧面靠近。第四导流面141可将排水板100顶面以及第四导流面141承接的化霜水导入到第三导水部140的底部,以便第三导水部140内的水排出。
从排水板100的底面向顶面的方向,第四导流面141向出口114的方向倾斜。当排水板100向出口114的方向倾斜,第三导水部140内汇聚的水量较多,则第四导流面141可向后导流,引导一部分水流从后方排出。
本公开实施例,结合图20至图25所示,朝向排水部110的方向,导水部凹陷的深度逐渐增大,此时导水部可称为第一导水部120。第一导水部120朝向排水部110的方向深度逐渐增大,以使水在重力作用下流向排水部110并从排水部110的出口114排出。
可以理解的是,朝向排水部110的方向,第一导水部120的底部沿第一方向倾斜,第一方向与排水板100的顶面形成第六夹角θ2。也就是第一导水部120的底部倾斜,第一导水部120内的水沿倾斜路径(第一方向)汇集到排水部110,排水效果好,可避免出现局部积水的问题;并且水能平稳流动。
当排水板100的顶面水平设置,可以理解为,第一方向与水平面形成第六夹角θ2。沿排水板100的顶面,从远离排水部110的一端向与排水部110连通的位置逐渐向下凹陷形成第一导水部120。此时,第六夹角θ2为第一导水部120的底部与水平面的夹角,第一方向为斜向下的方向。
其中,第一导水部120的底部,可以为斜线或斜面,一些情况下,第一导水部120的底部为斜面,斜面可以为平面或曲面,具体可根据需要选择。
一些情况下,第一导水部120的底部不形成连续的斜线或斜面,如阶梯状,依然能够满足导水需求。
可以理解的是,第六夹角θ2小于或等于7°,第六夹角θ2的角度小,有助于减小排水板100顶面到底面的距离,可实现小角度排水,进而减小风道组件200在高度方向的尺寸,缩小风道组件200所占用的空间,有助于提升制冷设备的储物空间,提供一种大容量的制冷设备。
一些情况下,第六夹角θ2设置为3°,3°能够满足排水板100的排水需求,还能充分减小排水板100的高度,实现小角度排水。当然,第六夹角还可以为1°、2°、4°、5°或6°。
一些情况下,第一导水部120与上述的第三导水部140的区别在于,第一导水部120向排水板100内的排水部110倾斜,第三导水部140向排水板100的端部倾斜,也就是倾斜方向不同,其他结构及参数可设置为相同,如倾斜的角度可相同。
可以理解的是,多个并列设置在排水部110同侧的导水部,所对应的排水板100的底面共面,使得排水板100的底面平整性更好,排水板100的外观简洁,且方便定位和安装。
此处的并列设置,可以理解为,在排水部110的延伸方向的一侧,多个导水部依次排列。一般情况下,排水部110的两侧均并列设置有多个导水部,也就是,排水部110设置在两列导水部之间。当然,当排水部110设置在排水板100的端部,则导水部仅设置在排水部110的一侧。
可以理解的是,导水部的延伸方向与出风方向相垂直,有效延长风在第一腔体282内停留的时间,以充分换热。
可以理解的是,排水部110的延伸方向与出风方向形成第八夹角,尽量减少风沿排水部110的延伸方向排出,也可延长风在第一腔体282内停留的时间,保证换热效果。
当然,排水部110也可沿出风方向延伸,排水部110的两侧可对称设置导水部,方便排水部110两侧的导水部均匀稳定导水。
如图20和图25所示,当排水部110沿出风方向延伸,导水部与出风方向相垂直,尽量减少进入导水部的风。
可以理解的是,如图24和图25所示,排水部110凹陷的深度大于或等于导水部凹陷的深度。也就是,排水部110的最小深度需要大于或等于导水部的最大深度,以使导水部的水可汇聚到排水部110,避免导水部积水。
可以理解的是,如图20、图21以及图24所示,排水部110的两侧均设置多个相平行的导水部,多个导水部将不同部位的水导入排水部110。通过设置多个导水部,也可以理解为,排水部110的两侧均形成波浪形结构,尽量减少排水板100顶面的面积,减少排水板100顶面的积水,使得排水板100所承接的水尽快沿导水部和排水部110从出口114排出。
可以理解的是,如图22和图23所示,排水部110至少设置两个,两个及以上的排水部110则具有两个及以上的出口114,实现多个位置排水,有助于排水板100上的水快速排出。在排水板100面积不变的情况下,排水部110的数量增多,则可缩短导水部的长度,水尽快进入排水部110。
相邻排水部110为第一排水部111和第二排水部112,第一排水部111和第二排水部112之间构造有位于第一排水部111的一侧的第一导水区123和位于第二排水部112的一侧的第二导水区124,朝向第一排水部111的方向,第一导水区123的导水部凹陷的深度逐渐增大,朝向第二排水部112的方向,第二导水区124的导水部凹陷的深度逐渐增大。也就是,第一导水区123与第二导水区124对接位置,导水部凹陷的深度最小,有助于第一导水区123承接的水导入到第一排水部111,第二导水区124承接的水导入到第二排水部112,缩短导水部的长度,便于水汇集到排水部110。
当然,如图15所示,排水部110还可设置一个,此时,排水部110的出口114尽量避开风机270的进口。排水部110的两侧均设置多个相平行的导水部,有助于缩短导水部的导水路径,以加快水导出。
如图12、图13、图15、图16以及图22至图23所示,排水部110从前向后延伸,出口114设置在排水板100后端,导水部沿左右方向延伸,排水部110的左右两侧形成波浪形结构,波浪板的设置可以利于水聚拢排出,此时蒸发器230无需沿着前后方向倾斜向下设置。
导水部与排水板100的顶面形成小于7°的夹角,也就是,排水板100左右方向形成有倾斜延伸的导水部,导水部的倾斜角度不影响排水板100前后方向的角度。排水部110从前向后延伸,排水部110从前向后与水平面形成第七夹角θ3,第七夹角θ3会影响排水板100前后方向的高度变化,但整体上来看,排水部110设置在排水板100的局部位置,排水部110所占用排水板100的面积较小,排水板100的局部位置倾角稍大,对间室内整体储物空间的影响较小,也能优化间室内的容积。
上述内容中,导水部可为上述的第一导水部120与第三导水部140中的至少一个,也就是,排水板100可构造有上述的排水部110以及上述的第一导水部120与第三导水部140中的至少一个,排水板100的结构多样。
可以理解的是,参考图24和图25所示,第一导水部120包括沿第一导水部120的延伸方向设置的第一导流面121,从排水板100的顶面向底面的方向,第一导流面121向其相对的侧面靠近,也就是,第一导水部120的纵截面从上向下收拢,以使落在第一导流面121以及顶面的水可汇集到第一导水部120的底部,再沿第一导水部120汇集到排水部110。
第一导水部120沿其延伸方向的两侧侧面中,至少一个侧面设置为第一导流面121。第一导水部120纵截面的形状可为倒三角形或倒梯形。参考图24和图25所示,第一导水部120延伸方向的两侧侧面均为第一导流面121,第一导水部120的两侧均可进行导流。
可以理解的是,参考图24和图25所示,排水部110包括沿排水部110延伸方向设置的第二导流面113,从排水板100的顶面向底面的方向,第二导流面113向其相对的侧面靠近,以使排水部110的纵截面从上向下收拢,落在第二导流面113及顶面的水可汇集到排水部110的底部,再从出口114排出。
排水部110沿其延伸方向的两侧侧面中,至少一个侧面设置为第二导流面113。排水部110纵截面的形状可为倒三角形或倒梯形。参考图25所示,排水部110延伸方向的两侧侧面均为第二导流面113,排水部110的两侧均可进行导流。
如图24和图25所示,第一导水部120设置第一导流面121,排水部110设置第二导流面113,充分导流,以便排水板100所承接的水尽快从出口114排出。
上述实施例中,第一导流面121与第二导流面113可为平面或曲面,具体可根据需要选择。
可以理解的是,导水部延伸方向的第一预设截面,朝向排水部110的方向导水部的宽度逐渐减小。还可以理解为,朝向排水部110的方向,导水部呈逐渐收拢的状态,以使导水部内的水汇聚,有助于导水部内的水进入排水部110。
此处的第一预设截面,可以理解为,平行于排水板100顶面的截面,排水板100处于安装状态的水平截面。导水部的宽度可以理解为导水部延伸方向的两个侧壁之间的距离,以第一导水部120为例,可以理解为两个第一导流面121之间的距离。逐渐减小一般为连续减小,但不排除阶梯减小。
可以理解的是,排水部110延伸方向的第二预设截面,朝向出口114的方向排水部110的宽度增大。多个导水部承接的化霜水向排水部110汇聚,排水部110的出口114的位置水量最大,排水部110的宽度增大,可提供更大的排水空间,有助于水稳定排出。
此处的第二预设截面,可以理解为,平行于排水板100顶面的截面,排水板100处于安装状态的水平截面。排水部110的宽度可以理解为排水部110延伸方向的两个侧壁之间的距离,也就是两个第二导流面113之间的距离。增大一般为逐渐增大,但不排除阶梯增大。
第一预设截面与第二预设截面平行,也可共面。
可以理解的是,如图22所示,排水板100的边缘向上翻折构造出翻边150,翻边150环绕排水板100且在对应于出口114的位置开槽。翻边150起到阻隔排水板100上表面的水向外溢流的作用,以使排水板100上表面的水均沿出口114排出,进而保证风道组件200内的水均从排水口排出。
翻边150的局部位置向上延伸形成定位部151,相邻两个定位部151用于限位排水板100上方的第一加热器231,第一加热器231的固定方式简单,且排水板100的结构简单。
需要说明的是,当导水部的端部形成有开口,则无需设置翻边。
上述实施例中,排水板100的轮廓形状与蒸发器230以及风道组件200的形状相关,排水板100的形状不作限定。排水板100的轮廓形状可以为矩形、梯形圆形或其他形状。排水板100的上表面与下表面的形状相同。
上述实施例中的排水板100应用于风道组件200中,也就是,排水板100设于蒸发器230的下方,从前向后的方向,蒸发器230无需向下倾斜,解决了蒸发器230具有倾斜角度会损失间室内容积的问题,在保证风道组件200内换热效率的情况下,实现了小角度化霜排水,以及减小了风道组件200高度方向落差,有助于间室内容积最大化。
当然,在实际使用中,蒸发器230也可稍微向下倾斜,但即使蒸发器230不向下倾斜,也不会影响排水效果。
排水板100还连接有振动器(图中未示意),通过振动器根据化霜需求提供振动作用力。振动器的启闭与化霜的时机密切相关,振动器可以与化霜工作同步展开,也可以相较于化霜工作适当延迟。
振动器可以为偏心电机、超声波振动器或者电磁振动器中的任意一个。
基于上述的排水板100,下面对连通排水板100与排水管的排水结构进行说明。
如图2至图13所示,风道组件200还包括第一排水部件260,第一排水部件260与第一腔体282内排水板100的开口170连通,第一排水部件260与风机270位于排水板100的不同侧(如相邻的两侧),第一排水部件260可理解为侧排水结构。
第一排水部件260设置第一排水口262,第一排水口262与排水管路(排水管路为第一排水管263)连通,以将排水板100承接的水排出。
第一排水部件260构造有排水通道,排水通道的横截面积从上向下逐渐缩小,能够保证全面承接开口170位置的排水,还能将排水汇聚到第一排水口262。
如图6和图7所示,第一排水部件260尽量覆盖排水板100的全部开口170,保证第 一排水部件260、风道部件220与隔板部件210的连接部位相密封,避免出现漏风与漏水的情况。图5和图7所示,部分开口170未对应第一排水部件260,是为了示意开口170的位置,实际应用中第一排水部件260覆盖全部的开口170。
第一排水部件260构造有与开口170连通的通孔,通孔的面积覆盖所有开口170,以保证排水效果和封闭效果,避免发生漏水。
可以理解的是,第一排水部件260设置有至少一个进风口,也就是第一排水部件260设置有第一进风口201与第二进风口202中的至少一个。如图6和图9所示,以第一排水部件260设置有第一进风口201为例进行说明,第一进风口201穿过第一排水部件260的内部而与第一腔体282连通,实现第一间室410的回风。第一进风口201通过回风部件430与第一间室410连通,以进行回风。
如图13所示,第一排水部件260包括相对设置的第一壁板264和第二壁板265,第一壁板264构造有通孔,第二壁板265构造有第一进风口201。第一壁板264朝向排水板100,第二壁板265朝向柜体400。其中,第一壁板264与第二壁板265可为可拆卸连接或一体成型。一些情况下,第一排水部件260构造为一体成型的结构,避免连接处发生泄漏。
需要说明的是,在第一排水部件260不设置第一进风口201的情况下,隔板部件210安装在风道部件220的上方,隔板部件210开设有第一进风口,以使第一间室410的回风部件430通过第一进风口201进入第一腔体282。
如图2至图13所示,排水板100的开口170朝向第一腔体282的第一侧,第二腔体281位于第一腔体282的第二侧,第二腔体281内设置有风机270,第一腔体282的第一侧与第二侧相邻。第一腔体282的第一侧可理解为左侧与右侧中的至少一个,第二腔体281的第二侧可理解为后侧。排水板100的出水方向与第一腔体282的出风方向不同,可减少风中携带的水汽,减小排水对风机270的影响,减少风机270的结霜量。此时,排水板100的开口170朝向左侧与右侧中的至少一个。
如图5至图8所示,排水板100包括第二导水部130,第二导水部130相对于排水板100的顶面凹陷,第二导水部130的延伸方向与排水板100上方的出风方向形成夹角,第二导水部130凹陷的深度沿预设面向第二腔体281的第一侧的方向逐渐增大,第二导水部130朝向第二腔体281的第一侧的端部构造出开口170,第二导水部130承接的水沿导水部的延伸方向而从开口170排出,开口170与上述的第一排水部件260连通,使水通过第一排水口262排出。排水板100的结构简单,且排水效果好。并且,第一间室410的回风通过第一进风口201进入第一腔体282,风从左侧或右侧进入第一腔体282,可沿第二导水部130流动;第二间室420的回风通过第二进风口202进入第一腔体282,风从风道组件200的前侧进入第一腔体282,则第一间室410的回风与第二间室420的回风进入第一腔体282的路径不同,两路回风接触减少,也减少因两路回风接触产生的结霜量。
此时,排水板100上方的出风方向为从前向后,第二导水部130的延伸方向为左右方向,则第二导水部130的延伸方向与排水板100上方的出风方向的夹角为90°,第二导水部130可起到减缓风在第一腔体282内的流动速度的作用,可延长风在第一腔体282内停留的时间,优化换热效果。
需要说明的是,排水板100包括从预设位置向左侧延伸的第二导水部130和从预设位置向右侧延伸的第二导水部130,排水板100具有朝向左右两侧的开口170,风道组件200的左右两侧均设置第一排水部件260,结构简单且导水效果好。其中,预设位置可以为排水板100的对称面,或,沿前后方向延伸的纵向面。预设面可以为上述的排水部的端面,向排水板的左侧和右侧延伸的第二导水部的预设面,可以为同一纵向面或不同纵向面。
与上述实施例不同的是,结合图10至图13所示,风道组件200内设置的排水板100构造有第三导水部140,第三导水部140的开口170与第一排水部件260连通。
当风机270设置在风道组件200的后侧,第一排水部件260设置在风道组件200的左侧与右侧中的至少一个,上述排水方式可理解为侧排水。由于风机270设置在风道组件200的后方,此时,蒸发器230与风机270独立排水,蒸发器230的化霜水通过第一排水部件260从左右两侧排出,向风机方向流动的化霜水以及遇到风机270而冷凝的水可通过风机270下方的结构排出,风机270下方的结构可为下述的后排水结构,或其他能够排出第二腔体281内水的结构。
与上述的第一排水部件260的排水方式不同,参考图10至图16所示,风道组件200还包括风机罩240,风机罩240限制出第二腔体281,风机270设置在风机罩240的第二腔体281内,风机罩240构造有通风口244,第二腔体281通过通风口244与第一腔体282连通。
一些情况下,风机罩240和风机270均设置风道组件200的后侧,位于风机所在侧的第二排水部件290,第二排水部件290提供后排水的方式。
风机罩240设置有第二排水部件290,第二排水部件290设置在风机罩240内,或, 第二排水部件290设置在风机罩240外侧的下方。
参考图14至图16所示,当第二排水部件290设置于风机罩240内,充分利用风机罩240内的空间,可缩小风道组件200的高度,扩大制冷设备的容量。
排水板100的出口114所在侧设置风机罩240,风机罩240朝向排水板100的一端与排水板100的出口114连通。风机罩240包括第一罩体241和位于第一罩体241下方的第二罩体242,风机270设置在第二罩体242的上方。第二罩体242设置第三排水口2423,排水板100的出口114排出的水沿第二罩体242引流到第三排水口2423。第二罩体242可承接排水板100导出的水,第一罩体241滴落的水,以及风机270滴落的水,并导出第一腔体282的化霜水,有助于简化风道组件200的结构。此时,排水板100可采用具有排水部110的结构,具体可参见上述排水板100的实施例。排水板100的出口114朝向后方,第二罩体242位于排水板100的后方,设置第二罩体242可提供一种后排水结构。
第二排水部件290构造出与排水板100的出口114连通的第一导水通道2421,第二排水部件290包括沿第二罩体242的表面向上凸起的隔挡部2422,隔挡部2422限制出第一导水通道2421,风机270位于隔挡部2422的一侧。隔挡部2422起到分隔第一导水通道2421与风机270的作用,阻止水流向风机270,减小水对风机270的影响。
向远离排水板100的出口114的方向,第一导水通道2421向下倾斜,以便第一导水通道2421内的水向下导出,结构简单且排水效果好。第一导水通道2421的端部形成第三排水口2423,第三排水口2423与排水管连接,通过排水管将水排到压机仓内。
其中,隔挡部2422可为第二罩体242向上凸起的板状结构或块状结构,具体可根据需要选择。当然,隔挡部2422还可以为可拆卸连接于第二罩体242的零件,如插接或卡接于第二罩体242的板结构,隔挡部2422的结构不限于此,其他能够实现隔挡功能的结构亦可。
需要说明的是,排水板100与第二罩体242之间设置分隔板2427,分隔板2427使得排水板100与第二罩体242仅在出口114处连通,其他部位通过分隔板2427进行分隔,以保证第一腔体282与第二腔体281在通风口244处以及出口114处连通,其他部位分隔。分隔板2427可与第二罩体242一体成型或可拆卸连接。
第二罩体242与排水板100可为独立的两个部件,或者,第二罩体242与排水板100一体成型为整体部件。
上述的风机罩240的内部设置第一导风部2424和第二导风部2425,第一导风部2424、第二导风部2425与风机270配合向第一排风口203和第二排风口204导风,保证风从对应的路径流出。如图15所示,第二罩体242设置有第一导风部2424和第二导风部2425。
风机270通过风机安装座271安装在第二罩体242的上表面,第二罩体242的上表面设置多个第二安装柱2426,风机安装座271固定在第二安装柱2426上,通过调整不同位置第二安装柱2426的高度,可调节风机270倾斜的角度和方向,且结构简单。
向远离排水板100的方向,也就是朝向第三排水口2423的方向,第二罩体242的上表面斜向下倾斜,以便第二罩体242表面的化霜水可在重力作用下向第三排水口2423的方向流动。
第二罩体242构造有集水部2428,集水部2428位于第二罩体242朝向第三排水口2423的一侧,集水部2428向第三排水口2423的方向表面积逐渐减小并与第三排水口2423连通,集水部2428收集的水可通过第三排水口2423排出。集水部2428向第三排水口2423的方向表面积逐渐减小,也就是集水部2428向第三排水口2423的方向收拢,以方便第二罩体242承接的化霜水汇集后排出。
基于第二罩体242的上表面朝向第三排水口2423的方向向下倾斜,集水部2428也可向下倾斜,排水效果更好,但集水部2428不限于向下倾斜,不排除集水部水平设置的情况。
第二罩体242设置有加热部件226,加热部件226通过加热第二罩体242以对风机罩240及其内的风机270等部件进行加热化霜。其中,加热部件226可为成型于第二罩体242的加热膜,或,加热部件226为位于第二罩体242下方的加热板,加热部件226的结构形式不限于此,其他能够实现加热化霜的结构亦可。
与上述的第二排水部件290不同的是,参考图10和图11所示,第二排水部件290还可以位于风机罩240的下方,第二排水部件290与风机罩240的外表面相密封以构造出与排水板100的出口114连通的第二导水通道。第二导水通道与第二腔体281相互分隔,也就是第二导水通道与风机270通过风机罩240分隔,减小第二导水通道内水对风机270等部件的影响。
第二排水部件290的形状可设置为具有翻边的U形结构,或者,第二排水部件290设置一体成型在第二罩体242下方的结构,第二排水部件290的结构多样,可根据需要选择。当排水板100设置多个出口114,可在风机罩240的下方设置多个第二排水部件290,第二导水通道与风机270互不干扰。在风道组件200的下方,第二排水部件290所对应的局部位 置向下凸出,使得风道组件200的局部位置高度较大,对其他位置的高度没有影响,也能起到扩大制冷设备容量的作用。
向远离排水板100的出口114的方向,第二导水通道向下倾斜,以便第二导水通道内的水向下导出,结构简单且排水效果好。第二排水部件290设置第二排水口,第二排水口与第二排水管291连接,通过第二排水管291将水排到压机仓内。
当然,导水通道(第一导水通道2421或第二导水通道)还可以水平设置,不会因导水通道而增加风道组件200高度方向的尺寸,有助于缩小风道组件200的高度,进而增大制冷设备的储物空间。
上述的风机罩240开设有走线孔,以便风道组件200的接电部件通过走线孔走线,实现电连接,结构简单且对方便走线。
当风机270的安装方式与上述方式不同,也就是在不设置风机罩240的情况下,排水方式与上述第一排水部件260和第二排水部件290不同。风道部件220支撑排水板100,排水板100位于蒸发器230的下方,排水板100的出口114所在侧设置导水件223,导水件223的一侧朝向出口114并与出口114连通,导水件223的另一侧构造出排水口,以使导水件223与第三排水管2231连通,排水板100的出口114排出的水沿导水件223引流到第三排水管2231。风机270设于蒸发器230的一侧,风机盖板243位于风机270与蒸发器230之间,风机270的进口通过风机盖板243的通风口244与第一腔体282连通。风机盖板243设置在导水件223的外侧,风机盖板243固定在箱胆本体300上,并与箱胆本体300的后壁之间围设出用于安装风机270的腔体,此腔体通过风机盖板243开设的通风口244与第一腔体282连通。或者,风机盖板243自身围设出的用于安装风机270的腔体,此腔体与第一腔体282连通,风机盖板243固定安装在箱胆本体300上。风机盖板243与导水件223之间限制出第三腔体,第一腔体282内的风通过第三腔体再被风机270导出。
其中,导水件223可以理解为风道部件220的一部分,或独立于风道部件220的零件,具体可根据需要选择。风机盖板243为风机270的安装部件,风机盖板243的主要功能与风机罩240的主要功能相近,一个风道组件200内设置风机盖板243或风机罩240,风机盖板243与导水件223组合使用,风机罩240与第二排水部件290组合使用。当风道组件200包括风机罩240,则在风机罩240上开设通风口244,以便第一腔体282内的风通过通风口244被风机270排出。
风机盖板243设置有第三导风部2431和第四导风部2432,风机盖板243设置有第一排风口203和第二排风口204,以使风机270将风送出第一排风口203和第二排风口204。
下面,对风机270以及风机270的安装方式进行说明。
如图5至图16所示,风道组件200还包括风机270,风机270的转动轴线与竖直方向形成第一夹角α1,风机罩240开设通风口244,风机270的进口朝向通风口244,第二腔体281通过通风口244与第一腔体282的出风区域连通,第二腔体281与风道组件200的排风口连通。第一腔体282内的风通过风机罩240上的通风口244被风机270抽吸到第二腔体281内,在风机270的作用下,第二腔体281内的风通过排风口通入第一间室410或第二间室420。也就是,第二腔体281与上述的第一排风口203和第二排风口204可通断调节。
风机270的转动轴线与竖直方向形成第一夹角α1,可以理解为,风机270的转动轴线的前端低于或高于后端。在满足通风和排水需求的情况下,第一夹角α1的角度尽量小,风机270的转动轴线的前端与后端的高度差尽量大,也就是风机270尽量接近水平设置,以减小风机270在高度方向所占用的空间,进而减小风道组件200在高度方向的尺寸。
此时,通风口244与第一腔体282的排水出口错位设置,可尽量减少排水出口处的风被风机270抽出,延长风在第一腔体282内的换热时间,提升换热效率。
风机罩240固定在箱胆本体300上,第一腔体282内的风,通过第二腔体281再被风机270导出。
可以理解的是,风道组件200还包括风机罩240,风机罩240包括第一罩体241和第二罩体242,第一罩体241构造有朝向风机270的导流表面2411,导流表面2411的第一侧高于导流表面2411的第二侧,导流表面2411的第一侧与导流表面2411的第二侧为相对的两侧;风机罩240限制出第二腔体281,第二腔体281内设置有风机270。第一罩体241可起到汇聚风机270上方的水汽的作用,并将汇集得到的水滴从导流表面2411的第一侧引流到导流表面2411的第二侧,第一罩体241的设置,可促进第二腔体281内水汽的汇集和排出,减小水汽对风机270的腐蚀,延长风机270的寿命。
其中,第一夹角α1大于或等于7°,使导流表面2411的第一侧汇集的水可沿其自身表面的坡度流动至第二侧,并使水沿风机270下方的风道部件220导流到第三排水口2423,避免第一罩体241表面汇集的水向风机270内滴落,尽量阻止水落入风机270。其中,导流表面2411的第一侧高于导流表面2411的第二侧,第一罩体241朝向风机270的表面可为倾斜的平面或曲面;当导流表面2411为平面,有助于简化第一罩体241的结构,方便加工。 另外,风机270表面积聚的水在重力作用下而下落并排出。
第一夹角α1需小于70°,以达到减小高度的目的;第一夹角α1可小于60°、50°、45°、30°、20°或10°,第一夹角α1越小,风道组件200的高度方向尺寸越小。
需要说明的是,当第一夹角α1小于7°,能够满足排风需求,且风道组件200的高度方向尺寸更小,但第一罩体241朝向风机270的表面导水效果不佳,排水效果难以满足需求。若第一夹角α1小于7°,则需要解决风机罩240排水的问题。
一些情况下,第一腔体282与第二腔体281为前后并列设置的两个腔体;或者,第二腔体281被第一腔体282包围;第一腔体282与第二腔体281的位置关系不限于此,可实现两个腔体的连通关系即可。以第二腔体281位于第一腔体282的后方为例,风机270可朝向前方倾斜第一夹角α1或朝向后方倾斜第一夹角α1,参考图14所示,风机270朝向前方倾斜第一夹角α1,参考图8所示,风机270朝向后方倾斜第一夹角α1。也就是,风机270的转动轴线的上端相对于竖直方向,向前倾斜形成第一夹角α1,或,向后倾斜形成第一夹角α1。
其中,风机270从前向后逐渐向上倾斜,也就是风机270的进口朝向第一腔体282的出风方向,有助于第一腔体282内的风进入风机270的进口,可以提高通风效果。风机270从前向后逐渐向下倾斜,可以提高空间利用率。前述结构,均可考虑蒸发器230与风机270可共用排水结构,以实现结构的简化;或,考虑蒸发器230与风机270采用独立的排水结构进行排水,可减小排水对风机270的影响。如图5、图6、图12和图13所示,蒸发器230的排水从左右两侧的第一排水部件260导出,风机270的排水从后端排出。
可以理解的是,风机270的转动轴线与通风口244的中心轴线共线,在将第一腔体282内的风通过通风口244吸入第二腔体281的过程中,风机270的抽吸效果好,有助于风道组件200内的风循环流动的效果。一些情况下,通风口244的形状与风机270的进口的形状相适配,以便第一腔体282内的风通过通风口244被风机270吸入第二腔体281。
风机270的转动轴线与通风口244的中心轴线共线,一般将第一罩体241的导流表面2411设置为与风机270相平行,或,将第一罩体241对应于风机270的区域设置为与风机270平行。风机270一般选用离心风机,离心风机可改变风的流动方向,方便将风送到第一间室410或第二间室420。当然,其他可满足循环送风效果的风机270亦可。
可以理解的是,如图4至图6所示,第一罩体241位于风机270的上方,导流表面2411的第一侧背离排水板100,导流表面2411的第二侧朝向排水板100,导流表面2411的第一侧相对于导流表面2411的第二侧向上倾斜第二夹角α2,即向远离排水板100的方向,第一罩体241的导流表面2411向上倾斜第二夹角α2,也就是通风口244朝向第一腔体282的出风方向,有助于第一腔体282内的风进入第二腔体281,可以提高通风效果,且可以考虑蒸发器230和风机270共用排水结构,以实现结构的简化。如图14至图16以及图21所示,风道组件200从后端的第二排水口或第三排水口2423进行排水。
结合图12至图25所示,当排水板100包括导水部和排水部110,排水部110构造有出口114,排水板100承接的水沿导水部向排水部110流动并从出口114排出,受此结构影响,一部分风也沿着导水部和排水部110向出口114流动,将出口114与通风口244设置为错位,则可阻止流向出口114方向的风直接从通风口244排出,尽量延长风在第一腔体282内换热的时间,提升换热效率。其中,当第二腔体281位于第一腔体282的后方,远离排水板100的方向为从前向后的方向。当然,第一腔体282与第二腔体281还可以左右设置,远离排水板100的方向为左右方向,工作原理与前后方向一致,此处不再赘述。结合图1至图3、图10、图11以及图17至图19所示,以第二腔体281位于第一腔体282的后方为例进行说明。
参考图1至图3、图10、图11以及图17至图19所示,第一罩体241位于风机270的上方,导流表面2411的第一侧朝向排水板100,导流表面2411的第二侧背离排水板100,导流表面2411的第二侧相对于导流表面2411的第一侧向下倾斜第三夹角α3,即向远离排水板100的方向,第一罩体241的导流表面2411向下倾斜第三夹角α3,第一罩体241向风机270的后方引导水流,有助于汇集的水快速排出。
一些情况下,第二夹角α2和第三夹角α3设置为与第一夹角α1的角度相同,以使风机270的转动轴线与通风口244的中心轴线共线,保证风道组件200内风流动效果,以及制冷设备内风循环效果。
上述实施例中的排水板100、风机罩240、导水件223等部件,均需要通过风道部件220进行支撑和保温,下面对风道组件200的结构进行说明。
风道部件220可通过固定连接于隔板部件210来与箱胆本体300固定,或风道部件220直接固定连接于箱胆本体300。
风道部件220包括支撑板以及设于排水板100下方的第二保温层221,支撑板支撑在第二保温层221下方,第二保温层221上表面的形状与排水板100下表面的形状相适配,使 得第二保温层221充分为排水板100进行保温,减少冷量向外扩散,保证换热效率。
当排水板100的下表面为曲面,如波浪形,则第二保温层221的上表面为对应的曲面;当排水板100的下表面为平面,则第二保温层221的上表面为平面,具体可根据需要设置。
其中,支撑板包括第一支撑部222和沿第一支撑部222斜向下倾斜的第二支撑部225,第二支撑部225与排水板100的出口114位于风道组件200的同侧,第一支撑部222支撑第二保温层221,第二支撑部225上方设置第三保温层224,第三保温层224上方设置导水件223或风机罩240,第二支撑部225起到支撑第三保温层224以及第三保温层224上方的部件(如导水件223或风机罩240)的作用。
第一支撑部222与第二支撑部225为相互独立的零件,如板件,通过可拆卸连接的方式安装,如插接、卡接及紧固件等方式;或,第一支撑部222与第二支撑部225为一体成型的结构,可减少零件数量,简化装配。在一些情况下,导水件223与排水板100为两个独立的零件,当然,导水件223与排水板100也可成型为一体式结构。
风道部件220可开设进风口,以便第一间室410与第二间室420中至少一个的回风通过风道部件220开设的进风口进入第一腔体282。如在支撑板上开设进风口;如图13所示,第一支撑部222的前端开设有与第二间室420连通的第二进风口202,使得第二间室420通过风道组件200前端的第二进风口202向第一腔体282内回风。
参考图36至图38所示,第一腔体282的第一侧设置第一进风口201,第一腔体282的第二侧设置第二进风口202,也可理解为,垂直于各自的进风方向,第一进风口201的截面与第二进风口202的截面形成夹角。第一进风口201的进风与第二进风口202的进风具有不同温度的进风。
风道部件220设置有分隔部2221,分隔部2221在第一进风口201处的正投影覆盖第一进风口201的局部面积,分隔部2221在第一进风口201处的正投影位于第一进风口201靠近第二侧的一端,分隔部2221与第一进风口201之间间隔预设间距a,第一进风口201的进风向分隔部2221的方向流动,风流动过程中,其中一部分风沿分隔部2221的延伸方向导流,一部分沿进风方向继续流动,当第一进风口201与第二进风口202同时进风时,可减少第一进风口201的进风与第二进风口202的进风中交叉接触的风量。
在第一腔体282内,蒸发器230朝向第二侧的一端与第二进风口202之间留有间距,第一进风口201与第二进风口202的大部分进风在此间距处交汇并接触换热之后,再沿蒸发器230向排风口流动;在此间距的位置,分隔部2221起到将第一进风口201的部分进风向分隔部2221的延伸方向引导的作用,可减少第一进风口201进风与第二进风口202进风中接触换热的风量,进而减少因进风温度不同而在蒸发器230靠近第二侧的一端的结霜量,避免因第二侧结霜量大而影响第一腔体282的进风量,也解决因第二侧结霜量大而导致的化霜周期短的问题,适当延长化霜周期,起到省电的作用。分隔部2221的设置,使得第一进风口201的进风和第二进风口202的进风尽量保持在分隔部2221的两侧。
参考图36所示,以第一进风口201与风道部件220的边缘对齐为例,预设间距a为风道部件220的第一侧边缘到分隔部2221的距离。需要说明的是,设置预设间距a,为了保证第一进风口201到分隔部2221之间提供适当的流动空间,以便风向第一腔体282内流动,避免分隔部2221封堵其所对应的第一进风口201的部位,因此,预设间距a的数值不作限定,可根据需要选择。正投影可以理解为,沿第一进风口201的进风方向在第一进风口201处的投影。
需要说明的是,风道部件220可以成型有第一进风口201(图中未示意)。
第一腔体282内设置蒸发器230,蒸发器230的散热片234沿第二进风口202向排风口的方向延伸(附图中从前向后的方向),以使蒸发器230与第二进风口202之间的间距处的风可沿散热片234的导向方向向排风口流动。
分隔部2221沿第二进风口202向排风口的方向延伸,第一进风口201的部分进风沿分隔部2221向蒸发器230内流动,分隔部2221与散热片234的延伸方向一致,则分隔部2221与散热片234配合将风向排风口的方向导流。
在第一进风口201向分隔部2221的方向,风道部件220设置有导向面2222,导向面2222为曲面,分隔部2221位于导向面2222的第一端并与第一端相切,导向面2222的第二端朝向限制出第一进风口201的第一壁面延伸。从第一进风口201进入第一腔体282的一部分风,可沿导向面2222的导向路径流动,也就是使此部分风随导向面2222的曲面流动,通过导向面2222改变部分风的流向,部分风沿分隔部2221的延伸方向流动,减少沿第一进风口201的进风方向流动的风,进而减小第一进风口201与第二进风口202的两部分进风中接触换热的风量。
一些情况下,导向面2222的第二端垂直于限制出第一进风口201的第一壁面,以使第一进风口201的进风沿导向面2222向分隔部2221流动。当然,导向面2222的第二端还可与第一壁面形成钝角或锐角夹角,以使进风沿导向面2222流动,导向面2222的具体结构 可根据需要选择。
参考图37和图38所示,导向面2222包括平面部22222和曲面部22221,曲面部22221的一端连接分隔部2221,曲面部22221的另一端连接平面部22222并与平面部22222相切,平面部22222朝向第一壁面的方向延伸,曲面部22221起到改变风的流动方向的作用,平面部22222可将风向曲面部22221引导,平面部22222与曲面部22221配合,第一进风口201的进风更加流畅。
一些情况下,平面部22222延伸至与第一壁面连接。但平面部22222也可与第一壁面之间设有间距,平面部22222与第一壁面的具体位置关系不作限定。
风道部件220设置有第二进风部,第二进风部构造出第二进风口202,第二进风部的两端均设置分隔部2221,第一侧包括与第二侧相邻的两个侧面,也就是在第二进风口202相邻的两侧均设置第一进风口201,通过第二进风部两端的分隔部2221,可分别将对应的第一进风口201的部分进风进行分隔,结构简单,且对称性好。
风道部件220设置有导流板2223,导流板2223连接风道部件220的边沿与分隔部2221,导流板2223位于分隔部2221与导向面2222的下方,导流板2223可起到支撑分隔部2221的作用,以使分隔部2221保持在预设高度位置,保证第一进风口201的进风与分隔部2221的对应关系,同时,第一进风口201的进风还可沿导流板2223向排风口的方向流动。
分隔部2221的高度小于或等于第一进风口201的高度的1/3,以使分隔部2221分隔高度方向的部分进风,对第一进风口201的进风效果影响较小,能保证第一进风口201的进风效率。
分隔部2221的长度小于或等于第一进风口201的长度的1/3,以使分隔部2221分隔长度方向的部分进风,对第一进风口201的进风效果影响较小,能够保证第一进风口201的进风效率。此处,分隔部2221的长度为沿风道部件220向蒸发器230的方向延伸的长度。
风道部件220一体成型有分隔部2221,分隔部2221无需独立加工和安装,可简化风道组件200的装配工序,节省装配时间。或,风道部件220可拆卸连接分隔部2221,分隔部2221的结构和形状可根据实际需要选择或更换,使得风道组件200的结构更加灵活和多样。
风道部件220包括支撑件和保温层,支撑件起到支撑保温层及其上部件的作用,支撑件构造有第二进风口202。一些情况下,分隔部2221一体成型于或可拆卸连接于支撑件,在此情况下,上述的导向面2222也为支撑件的部分表面;当然,不排除分隔部2221与保温层一体成型或可拆卸连接的情况。
上述的分隔部2221的实施例以及与分隔部2221相关的导向面2222、导流板2223的实施例,还可以设置在隔板部件210上,隔板部件210与风道部件220中的至少一个具有上述的功能。
基于上述关于排水板100的说明,风道部件220可支撑上述一种实施例的排水板100。风道部件220包括支撑板和位于支撑板上方的保温层;支撑板包括上述的第一支撑部222和第二支撑部225,保温层包括上述第二保温层221和第三保温层224,第一支撑部222的上方设置第二保温层221,第二保温层221的上方设置排水板100。
参考图20至图25所示,当排水板100的结构为:包括排水部110和导水部,排水部110构造有出口114,排水部110相对于排水板100的顶面凹陷;导水部与排水部110连通,导水部相对于排水板100的顶面凹陷,导水部的延伸方向与排水板100上方的出风方向形成第五夹角,朝向排水部110的方向,导水部的底部沿第一方向倾斜,第一方向与排水板100的顶面形成第六夹角θ2。此处的导水部可理解为上述实施例中的第一导水部120。
第二保温层221的上表面与排水板100的下表面相适配,当排水板100为波浪板,第二保温层221的上表面为相适配的波浪形表面,第二保温层221的下表面的形状可根据需要设置,如下表面为水平方向延伸的平面,使得风道部件220的下表面也可配置为水平方向延伸的平面,风道组件200的下表面形状规则且外观结构简洁。
参考图37所示,第二保温层221的下表面构造有沿第一方向倾斜的第一支撑斜面,第一支撑部222构造有与第一支撑斜面相适配的第二支撑斜面2224,第一支撑斜面与第二支撑斜面2224的加工简便且能够起到减小风道组件200的厚度的作用。
第二保温层221还构造有与排水部110相适配的第一支撑凹槽,第一支撑部222构造有与第一支撑凹槽相适配的第二支撑凹槽2225,第二支撑凹槽2225的后端开口170以与排水结构连通,方便将排水板100承接的化霜水导出。
下面对排水板100上方的蒸发器230进行说明。
参考图18至图20所示,蒸发器230横置在风道组件200的第一腔体282内,排水板100在蒸发器230的下方起到承接化霜水的作用。排水板100的顶面与蒸发器230的底面平行。其中,图1、图2、图10和图11的排水板100上方用于放置蒸发器230,但图中未示意蒸发器230的结构。
蒸发器230横置,可以理解为,蒸发器230的高度小于长度和宽度。
排水板100位于蒸发器230的下方,排水板100设置有相对于顶面凹陷的导水部,蒸发器230与水平面的夹角小于或等于预设夹角。
其中,蒸发器230与水平面的夹角小于或等于预设角度,可以理解为蒸发器230朝向排风口的一端低于蒸发器230朝向进风口的一端,蒸发器230朝向排风口的一端与朝向进风口的一端的连线与水平面形成预设角度,此处的连线可位于蒸发器230的底面或高度方向的对称面。当蒸发器230的形状为长方体,则蒸发器230的底面和对称面均与水平方向形成预设角度。
一些情况下,预设角度可达到小于或等于7°,预设角度可为1°、2°、3°、4°、5°、6°及7°中的至少一个角度。需要说明的是,此处限定预设角度小于或等于7°,是为了减小风道组件200的高度,在对风道组件200的高度不作严格限定的情况下,预设角度可适当增大。
或者,排水板100设置有相对于顶面凹陷的导水部,还能实现蒸发器230水平设置在第一腔体282内,此时可充分减小风道组件200的高度。
蒸发器230与水平面形成的夹角小于或等于预设角度,以减小蒸发器230所占用的高度方向空间,可减小风道组件200的整体高度,达到扩大制冷设备容量的目的。
其中,结合图3至图14所示的排水板100结构,预设角度可为7°,能够满足蒸发器230的化霜排水要求,同时减小风道组件200的整体高度。
可以理解的是,蒸发器230可水平安装在排水板100上方,可以理解为蒸发器230的底面平行于水平面,相对于蒸发器230倾斜设置的情况,水平设置的蒸发器230所需安装空间的高度变小,则风道组件200高度方向尺寸可随之变小,进而风道组件200所占用的箱胆本体300内的空间变小,在箱胆本体300的外观尺寸不变的情况下,可有效提高箱胆本体300的容量,以便提供一种大容量的制冷设备。
此时,并不限定排水板100的安装状态,排水板100的顶面与蒸发器230的底面平行,或,排水板100的顶面相对于蒸发器230的底面从前向后斜向下倾斜。
可以理解的是,排水板100的顶面为平面,也平行于水平面,也就是,蒸发器230的底面与排水板100的顶面均水平放置,排水板100的顶面起到位于蒸发器230的下方。蒸发器230的底面与排水板100的顶面相平行或相接触,蒸发器230与排水板100之间的间隙变小,可阻止第一腔体282内的风从蒸发器230与排水板100之间的间隙直接流向通风口244,有助于风在第一腔体282内充分换热。
需要说明的是,尽量减小蒸发器230与排水板100之间的间隙,减缓风从蒸发器230与排水板100之间的间隙流向通风口244的速度,延长风在第一腔体282内停留的时间,以使风在第一腔体282内充分与蒸发器230进行换热再流出,保证换热效率。
上述实时例中,蒸发器230为制冷设备中制冷系统的一部分,制冷系统包括压缩机、冷凝器、节流元件和蒸发器230,制冷系统中的制冷剂在蒸发器230中蒸发吸热,为第一腔体282内的风提供制冷环境。
下面对蒸发器230的结构进行说明。需要说明的是,以蒸发器230安装于风道组件为例进行说明,但蒸发器230不限于应用于风道组件200,还可以安装于其他适用的环境中。
蒸发器230包括换热管233和连接于换热管233的散热片234,散热片234构造有可供第一进风口201的进风通过的通风部23421,以便第一进风口201的进风穿过通风部23421向蒸发器230的内部流动,以便第一进风口201的进风充分换热。
需要说明的是,可以是部分散热片234开设有通风部23421,或者,全部的散热片234开设有通风部23421,具体可根据需要选择。
下面,以部分散热片234开设有通风部23421为例,进行说明。
蒸发器230包括换热管233、第一散热片2341和第二散热片2342,第一散热片2341与第二散热片2342均连接于换热管233,多个第一散热片2341并列设置形成第一散热部,第一散热部的至少一侧设置第二散热片2342(当蒸发器安装于风道组件内,第二散热片2342设置于第一散热片2341与第一进风口201之间),第二散热片2342构造有可供第一进风口201的进风通过的通风部23421,使得第一进风口201的部分进风通过通风部23421向蒸发器230内部分流,进而减少第一进风口201的进风与第二进风口202的进风中交叉接触而换热的风量,减少因第一进风口201的进风与第二进风口202的进风接触换热而凝结的霜。
通过蒸发器230的第二散热片2342对第一进风口201的进风进行分流,对风道组件200的整体结构影响小,仅需将部分散热片234替换为具有通风部23421的第二散热片2342,结构简单,且进风的分流效果较好。
其中,第二散热片2342位于第一散热片2341的至少一侧,也就是风道组件200的一侧设置第一进风口201,则第二散热片2342位于对应的一侧,风道组件200相对的两侧均设置第一进风口201,则第一散热片2341的两侧均设置第二散热片2342。第二散热片2342 的表面朝向第一进风口201,第二进风口202位于第二散热片2342的一端,排风口位于第二散热片2342的另一端。
第二散热片2342的数量可根据需要设置,第二散热片2342设置一个或多个。当第二散热片2342设置一个,第一进风口201的部分进风通过通风部23421流动到第二散热片2342与第一散热片2341之间,并沿第二散热片2342与第一散热片2341之间的空间向排风口的方向流动;当第二散热片2342设置多个,风穿过第二散热片2342的通风部23421并沿相邻第二散热片2342之间的空间以及第二散热片2342与第一散热片2341之间的空间流动,以流向排风口,风的流动空间更大,流动性更好。
相邻第二散热片2342的通风部23421沿直线贯通,也就是,相邻的两个第二散热片2342中,一个第二散热片2342的通风部23421的正投影覆盖另一个第二散热片2342的通风部23421的正投影,使部分风可顺利穿过通风部23421,向第一散热片2341的方向流动。
相邻第二散热片2342的通风部23421错位连通,也就是,相邻的两个第二散热片2342中,一个第二散热片2342的通风部23421的正投影覆盖另一个第二散热片2342的通风部23421的正投影的局部,或者,相邻的两个第二散热片2342的通风部23421的正投影不交叉,以使部分风可沿第二散热片2342的延伸方向流动。
其中,相邻的两个第二散热片2342,可以具有直线贯通的通风部23421和错位连通的通风部23421,结构更加多样。
当第二散热片2342设置多个,从蒸发器230的外侧向第一散热片2341的方向,通风部23421的截面面积可逐渐减小,向第一散热片2341的方向通过通风部23421的进风量减小,通风部23421的截面面积减小对风的流动性影响小,还能保证第二散热片2342的散热面积。
通风部23421包括闭环的通孔与具有开口的通孔中的至少一种,通风部23421的结构多样,且加工简便。
通风部23421的形状为矩形、圆形、椭圆形、梯形与三角形中的至少一种,通风部23421的形状多样,且结构简单。
其中,通风部23421的形状为封闭的矩形、圆形、椭圆形、梯形及三角形中的至少一种,或者,通风部23421的形状为具有开口的矩形、圆形、椭圆形、梯形及三角形中的至少一种,如一端开口的矩形、具有缺口的圆形、具有缺口的椭圆形等。
当然,通风部23421的形状不限于前述形状,通风部23421的具体形状可根据需要设置。
蒸发器230的两侧均设置第一进风口201,多个第一散热片2341并列设置形成第一散热部,第一散热部的两侧对称设置第二散热片2342,蒸发器230对应于两个第一进风口201的位置均设置有通风部23421,保证两个第一进风口201的部分进风均可通过通风部23421分流。
参考图13所示,风道组件200的左右两侧均设置有回风部件430,回风部件430与第一进风口201连通,实现风道组件200的两侧进风。
第一散热片2341和第二散热片2342设于排水板100的上方,以通过排水板100承接蒸发器230的化霜水,结构简单且方便蒸发器230安装。
蒸发器230还可设置重力传感器,通过重力传感器获得蒸发器230的重量变化,以根据重量变化确定蒸发器230是否需要化霜。蒸发器230还可设置振动器,振动器提供振动作用力,可起到辅助化霜的作用。
下面对风道组件200内部用于化霜的加热结构进行说明。
如图20所示,一些情况下,排水板100的上方设置第一加热器231,也就是,第一加热器231设置在排水板100与蒸发器230之间,在蒸发器230需要化霜时,开启第一加热器231,第一加热器231产生的热量用于加热蒸发器230表面附着的霜。一些情况下,蒸发器230的散热片234设置有用于安装第一加热器231的卡接槽,第一加热器231通过卡接槽卡固于散热片234,卡接槽可设置在散热片234靠下的位置,以使第一加热器231位于排水板100与换热管233之间,此时第一加热器231的安装简便且化霜效果好。
当然,用于化霜的加热结构不限定于设置在排水板100与蒸发器230之间,一些情况下,加热结构可设置在蒸发器230的换热管233之间,如加热结构为插接在蒸发器230的散热片234的第二加热器232,插接的结构简单且安装简便,有助于提升安装效率。散热片234开设有安装孔2343,第二加热器232插接于安装孔2343,结构简单且拆装简便。
第二加热器232沿蒸发器230的第一端延伸至第二端,第一端与第二端为相对的两端,以充分为蒸发器230提供热量,此处的第二端与第一端为与散热片234的延伸方向形成夹角的两端,如蒸发器230的左端和右端。
第二加热器232可插接在两排换热管233之间,以对上下两排的换热管233均匀加热化霜,此时第二加热器232与换热管233以及第二加热器232与换热管233上的散热片234 的换热效率更高,还能提高加热化霜的效率。
第二加热器232沿蒸发器230的高度方向分布多层,以对蒸发器230的多个位置进行加热。
第二加热器232包括多个固定连接的加热件,多个加热件固定连接为一体,装配过程中直接整体插接在散热片234上,装配简便且装配效率高。
第二加热器232包括多个相独立的加热件,加热件的位置灵活,且方便独立更换加热件,加热件的拆装也更加方便。
当第二加热器232包括多个相独立的加热件,加热件沿蒸发器230的高度方向可错位分布,可减少加热件的数量,还能充分为蒸发器230全面化霜。
当加热结构不设置在排水板100与蒸发器230之间,蒸发器230可直接放置在排水板100上,可有效减小蒸发器230与排水板100之间的间隙,起到减缓风速的作用,也能起到提高换热效率的作用。
加热结构可设置为加热件160,加热件160贴附在排水板100的表面,加热件160可与排水板100集成为一体式的结构,具有加热件160的排水板100可安装在多种结构蒸发器230下方,此排水板100既能承接和排放化霜水,又能加热化霜,排水板100具有双重功能,此排水板100安装在风道组件200内,可减小风道组件200的高度。
需要说明的是,具有加热件160的排水板100可安装在横置蒸发器230的下方。或者,具有加热件160的排水板100可设置在竖直安装于柜体400内的蒸发器230下方,此处对排水板100的应用场景不作限定。
加热件160可与上述任意一种实施方式的排水板100一体成型。或者,加热件160与其他可起到承接和排放化霜水的排水板100一体成型,使得排水板100可广泛应用于多种场合。
加热件160覆盖排水板100的下表面,排水板100的上表面用于承接化霜水,位于排水板100的下表面的加热件160可避免与水直接接触,可避免因电路故障而发生漏电事故,制冷设备的安全性能更好。
当然,在保证加热件160的防水性能的情况下,加热件160也可覆盖在排水板100的上表面。
加热件160可为设于排水板100表面的加热丝或加热膜。
下面以加热件为加热膜为例进行说明。
加热件160包括绝缘层和设置于绝缘层下表面的复合加热层,绝缘层连接于排水板100的下表面,排水板100与复合加热层之间通过绝缘层进行绝缘保护,可降低漏电风险。此时,排水板100的材料不作限定,排水板100可选用钢材,加工简便,还能保证排水板100的导热效果。
加热件160包括复合加热层,排水板100为绝缘导热结构,复合加热层设置于排水板100的下表面,排水板100同时具有导热和绝缘功能,则可省去绝缘层,使得排水板100的加工过程更加简便,有助于提升生产效率。其中,排水板100可为陶瓷与玻璃纤维材料复合而成的结构。
其中,加热件160的复合加热层可为石墨烯加热层、纳米加热层或碳纤维加热层以及多种电加热材料复合而成的加热层。复合加热层通电,则可将电能转化成加热件160的热能,为化霜提供热量。以复合加热层为石墨烯加热层为例,石墨烯加热层是一种由碳原子组成的六角型呈蜂巢晶格的平面薄膜,只有一个原子厚度,则可控制加热件160的厚度。
需要说明的是,当加热件160设置在排水板100的下表面,复合加热层的下方还需设置绝缘隔热层,可减少热量向下方扩散,保证加热的热效率。复合加热层与绝缘层之间、复合加热层与排水板100之间以及绝缘隔热层与复合加热层之间采用导热胶层粘接,导热胶层在实现导热效果的同时,可以实现各层之间的可靠连接。
加热件160包括沿设定方向分布的多个加热区,沿设定方向加热区的单位面积加热功率逐渐增大,可根据不同位置的结霜量不同,来调节对应加热区的加热功率,能实现快速且充分化霜,还可降低耗电量。
复合加热层采用石墨烯加热层时,不同加热区的石墨烯加热层的网格分布不同,使得不同加热区当中的石墨烯加热层的电阻分布不同。排水板100的下表面可分布有两种不同电阻的石墨烯加热层,当然,还可以分布任意多种不同电阻的石墨烯加热层。此外,不同电阻的石墨烯加热层之间既可以串联,也可以并联,还可以接入不同的电路当中。
上述实施方式中的加热件160应用于上述的风道组件200中,用于蒸发器230的化霜,则可减小加热器所占用的空间,可起到减小风道组件200高度的作用,进而减小风道组件200的体积,具有此种风道组件200的制冷设备可适当增大储物空间,起到制冷设备扩容的作用。
上述实施例中具有加热件160的排水板100,可与上述第一加热器231和第二加热器 232中的至少一个结合使用,以提高化霜效率。
需要说明的是,上述是加热件160可应用于上述实施例的排水板100,但不限于此,加热件160还可应用于其他结构的排水板。
上述用于化霜的加热结构需要通过导线与风道组件200外部的电源电连接,导线可通过上述的风机罩240开设的走线孔走线,结构简单且方便装配。
下面对隔板部件210的结构进行说明。
隔板部件210与风道部件220限制出第一腔体282、进风口和排风口,第一腔体282内设置蒸发器230和排水板100,进风口的进风在第一腔体282内换热后从排风口排出,排风口将风送入间室内,为制冷设备提供制冷环境。当进风口包括第一进风口201和第二进风口202,第一进风口201与第二进风口202包括不同温度的进风。
隔板部件210可固定连接于箱胆本体300,如隔板部件210的边缘通过焊接、卡接或紧固件等方式固定于箱胆本体300。参考图6和图20所示,隔板部件210包括第一板体211和第二板体212,第一板体211与第二板体212设置第一保温层213,第一保温层213为可拆卸设置于第一板体211与第二板体212之间,或第一保温层213与第一板体211和第二板体212一体发泡成型。
当第一保温层213与第一板体211和第二板体212一体发泡成型,可先将第一板体211与第二板体212与箱胆本体300固定安装,第一保温层213与柜体400的保温层一体发泡成型,隔板部件210与箱胆本体300之间的密封性能更好,避免第一间室410与第二间室420之间串风。
参考图6和图20所示,隔板部件210还包括第三板体214,第三板体214与第一板体211和第二板体212限制出安装空间,限制出安装空间的部位可称为安装部,第三板体214位于风道组件200的前方,安装空间位于隔板部件210的前方,安装空间用于安装功能部件,如控制器、照明模块、交互模块以及显示模块等。当第二进风口202设置在风道组件200的前侧,隔板部件210限制出安装空间的部位(安装部)位于第二进风口202的前端,限制出安装空间的部位(安装部)起到在前端遮盖第二进风口202的作用,以使第二进风口202被隐藏,第二进风口202的下方与第二间室420连通。
需要说明的是,第二进风口202不限定设置在风道组件200的前侧,第二进风口202还可以设置在风道组件200的下侧靠前的位置。
参考图26至图28所示,隔板部件210与风道部件220限制出第一腔体282、第一进风口201、第二进风口202和排风口,第一进风口201与第二进风口202包括不同温度的进风;第一进风口201位于风道组件200的第一侧,第二进风口202位于风道组件200的第二侧,第一侧与第二侧相邻,或第一进风口201与第二进风口202位于同侧;隔板部件210构造有朝向隔板部件210内侧凹陷的内凹部,内凹部适于引导第一进风口201与第二进风口202中至少一个的部分进风分流至内凹部内,也就是第一进风口201与第二进风口202中至少一个的部分进风分流到各自对应的内凹部,以减小第一进风口201与第二进风口202的进风中交叉接触风量,减少进风交叉接触区域的结霜量,进而延长两次化霜间隔的时长,减少化霜次数,降低化霜的耗电量。
以第一进风口201与第二进风口202位于不同侧,且进风方向相交叉为例,进风过程中,第一进风口201的一部分风沿对应的内凹部的延伸方向导流,一部分沿进风方向继续流动,当第一进风口201与第二进风口202同时进风时,沿进风方向继续流动的风与第二进风口202的进风相交叉,减少了第一进风口201的进风与第二进风口202的进风中交叉流动的风量。第二进风口202对应区域设置内凹部的原理相同,此处不再赘述。
以第一进风口201与第二进风口202位于同侧(如均位于前侧),且进风方向相同为例,内凹部的延伸方向与对应进风口的延伸方向一致,第一进风口201的部分进风沿对应的内凹部的延伸方向流动,第一进风口201的另一部分进风沿其流动方向继续流动。
参考图26所示,内凹部包括第一内凹部2121,第一内凹部2121以第一预设宽度L1沿隔板部件210的第二侧向第三侧延伸第一预设长度L2,第二进风口202位于第二侧,第三侧为与第二侧不相邻的一侧,第三侧可为排风口所在侧,第一内凹部2121靠近隔板部件210的第一侧边缘,第一进风口201位于第一侧。
从第一进风口201进入第一腔体282的进风,一部分沿第一进风口201的进风方向流动而与第二进风口202的进风交叉接触,另一部分沿第一内凹部2121的延伸方向流动,第一内凹部2121起到导向和分流的作用,以减少第一进风口201的进风与第二进风口202的进风交汇的风量,进而减少结霜量。
其中,第一预设宽度L1,可设置为小于或等于第一进风口201到第二进风口202的最小距离;第一预设长度L2,可设置为小于或等于蒸发器230的长度,蒸发器230的长度方向为进风口向排风口的方向。
参考图26所示,第一内凹部2121构造有第一顶面2123和连接于第一顶面2123的第 一引导面2122,第一引导面2122沿远离第一顶面2123的方向向下倾斜,第一引导面2122位于远离第一进风口201的一侧,第一引导面2122将风向排风口的方向引流,避免风囤积在第一内凹部2121限制出的凹槽内,保证风的循环流动效果。
当第一腔体282的第一侧包括两个及以上的侧面,如第一侧设置为相对的左侧和右侧,第一进风口201设置在风道组件200的左侧和右侧,隔板部件210的两侧对称设置有第一内凹部2121,每个第一内凹部2121均对应一个第一进风口201,保证每个第一进风口201的进风均通过第一内凹部2121分流部分风。
其中,第一引导面2122可设置在第一内凹部2121的后侧、左侧或右侧。如图26所示,示意了一个第一引导面2122位于第一内凹部2121的后侧,另一个第一引导面2122位于第一内凹部2121的左侧。图26为了示意不同位置的第一引导面2122,实际应用中,两个第一内凹部2121一般对称设置。
参考图27和图28所示,内凹部包括第二内凹部2124,第二内凹部2124的一侧朝向第二进风口202,以使第二内凹部2124可引导第二进风口202的部分进风沿第二内凹部2124限制出的凹槽流动,第二进风口202也分流部分进风,可减少第一进风口201的进风与第二进风口202的进风交汇的风量,也能减少结霜量。
第二内凹部2124以第二预设宽度L3沿隔板部件210的第二侧向第三侧延伸第二预设长度L4,第二预设长度L4小于第一腔体282内蒸发器230的长度,蒸发器230的长度为沿第二侧向第三侧的长度。此处的第二侧和第三侧可参考上述的解释。第二内凹部2124的长度小于蒸发器230的长度,避免第一内凹部2121内的风直接流向排风口,保证第一内凹部2121内的风与蒸发器230换热后再从排风口排出。
第二内凹部2124构造有第二顶面2126和连接于第二顶面2126的第二引导面2125,第二引导面2125沿远离第二顶面2126的方向向下倾斜,第二引导面2125朝向排风口所在侧,通过第二引导面2125的斜面将风向下引流,以便风充分流向蒸发器230。
一些情况下,第一内凹部2121与第二内凹部2124可结合使用,也就是隔板部件210同时设置有第一内凹部2121和第二内凹部2124,此时,第二内凹部2124与第一内凹部2121通过第三壁板215分隔,第一内凹部2121和第二内凹部2124的凹陷深度相同,结构简单且方便加工。
隔板部件210同时设置有第一内凹部2121和第二内凹部2124的情况下,第一预设长度L2大于或等于第二预设长度L4,第一内凹部2121充分向排风口的方向引导第一进风口201的进风,第二内凹部2124向排风口的方向引导第二进风口202的进风,还能保证风与蒸发器230的换热效果。
需要说明的是,第二内凹部2124内的风,也可包括第一进风口201的进风与第二进风口202的进风交汇混合后的风。
蒸发器230包括换热管233和连接于换热管233的散热片234,散热片234沿第二进风口202所在侧向排风口所在侧延伸,散热片234可引导风从进风口所在侧向排风口所在侧流动。
散热片234构造有凸出部,凸出部伸入第二内凹部2124内,以保证第二内凹部2124内的风可充分与散热片234进行换热。
参考图29所示,隔板部件210构造有第三内凹部2127,第三内凹部2127的一侧朝向第一进风口201,第三内凹部2127的另一侧朝向第二进风口202,第一进风口201与第二进风口202位于相邻的两侧,以使第三内凹部2127位于第一进风口201与第二进风口202所对应的交叉区域,第三内凹部2127增大了第一进风口201与第二进风口202的进风交叉区域的空间,增大容霜空间,延长了进风口所在端可进风的时长,减少化霜次数,可延长化霜周期,节省化霜耗电。
其中,第一进风口201与第二进风口202位于相邻的两侧,参考图5所示,第一进风口201位于风道组件200的左右两侧并通过回风部件430与第一间室410连通,第二进风口202位于风道组件200的前侧,第一进风口201与第二进风口202均位于风道组件200靠前的位置。
第一进风口201与第二进风口202还可位于相对的两侧(图中未示意),如第一进风口201位于风道组件200的左侧,第二进风口202位于风道组件200的右侧,此时,可通过第三内凹部2127为第一进风口201的进风和第二进风口202的进风提供更大的交汇空间。第一进风口201与第二进风口202还可位于相对的两侧,也可增大第一进风口201与第二进风口202的间距,适当减少交叉换热的风量。
第三内凹部2127以第三预设宽度L5沿第二进风口202所在侧向排风口所在侧延伸第三预设长度L6,第三预设长度L6小于第一腔体282内蒸发器230的长度,蒸发器230的长度为沿第二进风口202所在侧向排风口所在侧的长度。
参考图29所示,第三内凹部2127的宽度方向为垂直于第二进风口202向排风口的方 向,第三预设宽度L5即为此方向的尺寸,第三预设长度L6为从第二进风口202向排风口的方向的长度。
第三内凹部2127构造有第三顶面2128和连接于第三顶面2128的第三引导面2129,第三引导面2129沿远离第三顶面2128的方向向下倾斜,第三引导面2129朝向排风口所在侧。第三引导面2129将第三内凹部2127内的风向蒸发器230的方向引流,以便此部分风充分换热后排出。
基于上述关于排水板100、风机罩240、风机270、风道部件220、化霜的加热结构以及隔板部件210等各个部件的实施例,提出如下风道组件200的结构,但风道组件200不限于下述的结构。
结合图1至图13所示,风道组件200包括隔板部件210和风道部件220,隔板部件210与风道部件220构造出相连通的第一腔体282、进风口和排风口,进风口分为第一进风口201和第二进风口202,在第一腔体282内设置排水板100,排水板100构造有相对于排水板100的顶面向下凹陷的导水部,导水部向预设面的两侧延伸至排水板100的边缘,以使排水板100的边缘形成开口170,开口170朝向第一进风口201所在侧,以使第一进风口201的部分进风适于通过开口170并沿导水部的延伸方向流入第一腔体282内。第一进风口201的部分进风通过开口170并沿导水部的延伸方向导入第一腔体282内,可将第一进风口201的一部分进风进行分流,减少与第二进风口202的进风中交叉接触的风量,进而减少因第一进风口201的进风与第二进风口202的进风交叉接触而凝结的霜,减少化霜次数,延长化霜周期,减少化霜所需的耗电量,减少制冷设备的耗电量。
导水部为图1至图13中所示的至少一种结构,也就是,导水部可为第二导水部130与第三导水部140中的至少一种。
可以理解的是,风道组件200还包括位于第一侧的第一排水部件260,第一排水部件260与排水板100的开口170连通,第一排水部件260构造有排水口。第一排水部件260同时具有排水和进风的功能。
可以理解的是,风道组件200还包括风机罩240,风机罩240限制出第二腔体281,第二腔体281内设置有风机270,风机270的转动轴线与竖直方向形成第一夹角α1,风机罩240开设通风口244,风机270的进口朝向通风口244。风机270横置在风机罩240内,可减小风机270的高度,进而减小风道组件200的高度,方便在风道组件200的下方安装抽屉。
可以理解的是,第一腔体282内设置蒸发器230,排水板100位于蒸发器230的下方,蒸发器230与水平方向的夹角小于或等于预设角度,或,蒸发器230与水平方向平行,蒸发器230横置,且其向下倾斜的角度可小于或等于7°或水平,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
隔板部件210、风道部件220、第一排水部件260、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
结合图10至图25所示,风道组件200包括隔板部件210、风道部件220、蒸发器230和排水板100,隔板部件210和风道部件220构造出相连通的第一腔体282、第一进风口201、第二进风口202和排风口,第一进风口201位于第一腔体282的第一侧,第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻;蒸发器230设于第一腔体282内;排水板100位于第一腔体282内;排水板100位于蒸发器230下方,构造有相对于排水板100的顶面向下凹陷的导水部和排水部110,排水部110构造有出口114并与导水部连通,排水部110的延伸方向与导水部的延伸方向形成第五夹角,导水部的端部构造出开口170且开口170朝向第一进风口201,以使第一进风口201的风适于沿导水部的延伸方向流入第一腔体282内。导水部起到导流第一进风口201的进风的作用,使得第一进风口201的一部分进风沿导水部向第一腔体282内流动,减小第一进风口201与第二进风口202的进风中交叉接触的风量,减小因温度不同的风接触而凝结的霜,进而延长化霜间隔的时间,减少化霜次数,节省化霜的耗电量,起到省电节能的作用。
此时,导水部的结构可为第三导水部140。
可以理解的是,排水板100的出口114与排风口位于第一腔体282的同侧,向排水板100的出口114流动的化霜水的热量可为同侧的风机270起到化霜的作用。
可以理解的是,排水板100的顶面与蒸发器230的底面均斜向下倾斜预设角度,或排水板100的顶面与蒸发器230的底面均与水平面平行。蒸发器230横置,且其向下倾斜的角度可小于或等于7°或水平,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
风道组件200还包括位于第一侧的第一排水部件260,第一排水部件260包围开口170并与开口170连通,第一排水部件260构造有第一排水口262。第一排水部件260可设置在柜体400的发泡层内,以增大间室的空间。
风道组件200还包括风机罩240,风机罩240限制出第二腔体281,第二腔体281内设置有风机270,风机270的转动轴线与竖直方向形成第一夹角α1,风机罩240开设通风口244,风机270的进口朝向通风口244。风机270横置在风机罩240内,风机270的高度降低,进而降低风道组件200的整体高度。
隔板部件210、风道部件220、第一排水部件260、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
结合图10至图25所示,风道组件200包括隔板部件210、风道部件220、蒸发器230和排水板100,隔板部件210和风道部件220构造出相连通的第一腔体282、第一进风口201、第二进风口202和排风口,第一进风口201位于第一腔体282的第一侧,第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻;蒸发器230设于第一腔体282内;排水板100位于第一腔体282内;排水板100位于蒸发器230的下方,排水板100构造有导水部和出口114,导水部相对于排水板100的顶面凹陷并与出口114连通,导水部的延伸方向与第一腔体282的出风方向形成第四夹角。
此时,导水部可为上述第二导水部130与第三导水部140中的至少一种。
蒸发器230与水平方向的夹角小于或等于预设角度,或者,蒸发器230沿着水平方向设置。蒸发器230横置,且其向下倾斜的角度可小于或等于7°或水平,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
风道组件200还包括位于第一腔体282的一侧的风机270,排水板100的出口114朝向风机270所在侧。排水板100的出口114与风机270的进口相错位,以阻止水向风机270流动。
第二进风口202位于风道组件200前侧并与第二间室420连通,第一进风口201位于风道组件200的左侧与右侧中的至少一个且靠近前端,第一进风口201与第一间室410连通,以通过风道组件200的前端进行回风。
隔板部件210、风道部件220、第一排水部件260、第二排水部件290、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
结合图1至图25所示,风道组件200包括隔板部件210、风道部件220、风机270、蒸发器230和排水板100,隔板部件210和风道部件220构造出相连通的第一腔体282、第一进风口201、第二进风口202和排风口,第一进风口201位于第一腔体282的第一侧,第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻;蒸发器230设于第一腔体282内;排水板100位于第一腔体282内;排水板100位于蒸发器230的下方以承接化霜水,排水板100构造有相对于排水板100的顶面向下凹陷的导水部,导水部向预设面的两侧延伸至排水板100的边缘,以使排水板100的边缘形成适于排水的开口170,开口170朝向第一侧;风机270位于第一腔体282的第三侧。也就是,风机270与排水板100的排水位置位于不同侧,可减小风机270所在侧所占用的空间,进而增大制冷设备内的间室空间,以提供大容量的制冷设备。
风道组件200还包括位于第一侧的第一排水部件260,第一排水部件260的排水通道与开口170连通,第一排水部件260构造有排水口。第一排水部件260可成型在柜体400的发泡层内,不占用间室的空间,有效扩大间室的容量。排水板100的开口170侧通过第一排水部件260进行排水,第一排水部件260的结构可参见上述内容。
蒸发器230与水平方向的夹角小于或等于预设角度,蒸发器230横置且其向下倾斜的角度可小于或等于7°,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻,第二进风口202与第一进风口201具有不同温度的进风,第一进风口201与第二进风口202所连通的间室具有不同的环境温度。
第一侧为左侧与右侧中的至少一个,第一进风口201和第一排水部件260位于左侧与右侧中的至少一个;第二侧为前侧,第二进风口202位于前侧,第三侧为后侧,风机270位于后侧。
当第一间室410为冷藏室,第二间室420为冷冻室,与冷藏室连通的第一进风口201设置在风道组件200的左侧和右侧,与冷冻室连通的第二进风口202设置在风道组件200的前侧,第二进风口202的前端通过隔板部件210遮挡,第二进风口202与通过隔板部件210的下方与冷冻室连通,风道组件200的后侧设置风机270,风机270将风从排风口排出。
风道组件200还包括设于隔板部件210与风道部件220之间的风机罩240,风机罩240构造出第二腔体281,第二腔体281内设置有风机270,风机罩240构造有通风口244,风机270的进口朝向通风口244,风机罩240起到保护风机270的作用。
风机270的转动轴线与竖直方向形成第一夹角α1,可减小风机270所占用的高度方 向的尺寸。通风口244位于风机270的上方,以使风机270通过风道部件220支撑,且风机270的上方与蒸发器230的位置对应。通风口244的中心轴线与风机270的转动轴线共线,以保证第一腔体282内的风顺利被风机270从排风口导出。
风机罩240构造有位于风机270上方并朝向风机270的导流表面2411,导流表面2411沿朝向排水板100的一侧向上或向下倾斜,导流表面2411可起到汇集水汽并将汇集得到的水从风机罩240一侧排出的作用。
隔板部件210、风道部件220、第一排水部件260、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
参考图1至图13所示,风道组件200包括隔板部件210、风道部件220、风机270、蒸发器230和排水板100,隔板部件210和风道部件220构造出相连通的第一腔体282、第一进风口201、第二进风口202和排风口,第一进风口201位于第一腔体282的第一侧,第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻;蒸发器230设于第一腔体282内;排水板100位于第一腔体282内;排水板100位于蒸发器230的下方,排水板100构造有开口170和出口114,开口170朝向第一侧,出口114朝向第三侧;第一排水部件260位于第一侧并构造有与开口170连通的排水通道,以使排水板100上的水通过开口170导入第一排水部件260;第二排水部件290位于第三侧并构造有与出口114连通的导水通道。第一排水部件260与第二排水部件290配合,使得风道组件200可从不同侧排水,排水路径增多,有助于排水板100承接的化霜水从多个方位排出,可提升化霜和排水效率。
风道组件200还包括风机罩240和设于风机罩240内的风机270,风机罩240内或风机罩240的下方设置第二排水部件290。风机罩240构造有通风口244,风机270的转动轴线与竖直方向形成第一夹角,风机270的进口朝向通风口244。风机270横置安装,有助于减小风道组件200的高度。
蒸发器230与水平方向的夹角小于或等于预设角度,蒸发器230横置且其向下倾斜的角度可小于或等于7°,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
隔板部件210、风道部件220、第一排水部件260、第二排水部件290、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
参考图10至图16所示,风道组件200包括隔板部件210、风道部件220、风机270、蒸发器230和排水板100,隔板部件210和风道部件220构造出相连通的第一腔体282、进风口和排风口,蒸发器230设于第一腔体282内;排水板100位于第一腔体282内;排水板100位于蒸发器230的下方,排水板100构造有排水部110和导水部,排水部110构造有出口114,排水部110相对于排水板100的顶面凹陷;导水部与排水部110连通,导水部相对于排水板100的顶面凹陷,导水部的延伸方向与第一腔体282的出风方向形成第五夹角;风机罩240构造出通风口244、第二腔体281和导水通道,第二腔体281通过通风口244与第一腔体282连通,导水通道与出口114连通;风机270位于第二腔体281内,风机270的转动轴线与竖直方向形成第一夹角,风机270的进口通过通风口244与第一腔体282连通。通过用于安装风机270的风机罩240进行排水,可使风道组件200的结构更加紧凑,减少风道组件200的零部件数量,装配更加简便;风机270横置,还能减小风道组件200的高度。
向远离出口114的方向,导水通道向下倾斜,以通过倾斜的角度进行导水,以便水快速且全部排出。
蒸发器230与水平方向的夹角小于或等于预设角度,蒸发器230横置且其向下倾斜的角度可小于或等于7°,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
风道部件220与隔板部件210构造出与第一腔体282连通的进风口和出风口,排水部110沿进风口向出风口的方向延伸,以便排水板100的出口114的水通过风机罩240的导水通道排出。
进风口包括第一进风口201和第二进风口202,第一进风口201与第二进风口202具有不同温度的进风,第一进风口201与第二进风口202位于第一腔体282的不同侧。第一进风口201位于第一腔体282的第一侧,第二进风口202位于第一腔体282的第二侧,第一侧与第二侧相邻,第一进风口201位于靠近前侧的位置,以从风道组件200的前端进风。
隔板部件210、风道部件220、第一排水部件260、第二排水部件290、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
参考图1至图38所示,风道组件200包括隔板部件210、风道部件220、风机270、蒸发器230、排水板100和分流部,隔板部件210和风道部件220构造出相连通的第一腔体282、进风口和排风口,蒸发器230设于第一腔体282内;排水板100位于第一腔体282内; 排水板100位于蒸发器230的下方,分流部设于隔板部件210与风道部件220中的至少一个,用于引导第一进风口201的部分进风沿分流部的导向方向流动。分流部起到将第一进风口201的部分进风进行分流的作用,进而减少第一进风口201的进风与第二进风口202的进风交汇的风量,减小因温度不同而产生的霜,延长两次化霜间隔的时间,降低化霜的耗电量。
其中,分流部的结构可参考图21至图38所示。
分流部为构造于隔板部件210的第一内凹部2121,第一内凹部2121朝向隔板部件210内侧凹陷,第一内凹部2121适于引导第一进风口201的部分进风分流至第一内凹部2121内,第一进风口201位于第一腔体282的左侧与右侧中的至少一个。
风道组件200还包括设于第一腔体282内的蒸发器230,蒸发器230包括换热管233和散热片234;散热片234包括第一散热片2341和第二散热片2342,第一散热片2341连接于换热管233,多个第一散热片2341构造出第一散热部;第二散热片2342连接于换热管233,第二散热片2342设置于第一散热部的至少一侧,分流部为构造于第二散热片2342的通风部23421,第一散热片2341在第二散热片2342上的投影覆盖通风部23421,第一进风口201在第二散热片2342的投影覆盖通风部23421,第一散热片2341与第二散热片2342均沿第二侧向第三侧延伸,第三侧为排风口所在侧。通风部23421的具体实施方式及效果可参考上述蒸发器230的实施例,此处不再赘述。
蒸发器230与水平方向的夹角小于或等于预设角度,蒸发器230横置且其向下倾斜的角度可小于或等于7°,蒸发器230所占用高度方向的空间减小,风道组件200的高度也随之减小,有助于增大制冷设备的空间。
隔板部件210、风道部件220、第一排水部件260、第二排水部件290、风机270、风机罩240、排水板100以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
结合图1至图25所示,风道组件200包括隔板部件210、风道部件220、蒸发器230和排水板100,风道部件220位于隔板部件210的下方,与隔板部件210构造出相连通的第一腔体282、进风口和排风口;蒸发器230设于第一腔体282内,蒸发器230与水平方向的夹角小于或等于预设角度;排水板100设于第一腔体282内,排水板100位于蒸发器230的下方,排水板100构造有出口114和相对于排水板100的顶面凹陷的导水部,导水部与出口114连通,导水部的延伸方向与进风口向排风口的方向形成第四夹角;加热件160设于排水板100的表面。通过蒸发器230横置在风道组件200内,并且蒸发器230相对于水平方向向下倾斜的角度控制在预设角度以内,可减小蒸发器230所占用的高度,通过蒸发器230减小风道组件200的高度;排水板100设置有导水部,通过导水部满足排水需求,还可满足送风换热的需求,保证第一腔体282内的风充分与蒸发器230换热后再排出;具有导水部的排水板100与蒸发器230配合,可减小蒸发器230倾斜的角度;再通过在排水板100上设置加热件160来节省加热化霜结构所占用的高度,进一步减小风道组件200的高度。
结合上述,蒸发器230、排水板100与加热件160配合,可充分减小风道组件200的高度。
加热件160覆盖排水板100的下表面,可避免加热件160与排水板100上方承接的化霜水直接接触,减小安全隐患。
其中,隔板部件210、风道部件220、第一排水部件260、第二排水部件290、风机270、风机罩240、排水板100、加热件160以及蒸发器230等部件,均可以采用上述实施例中的结构,此处不再赘述。
当上述实施例中的风道组件200应用于箱胆以及制冷设备,则箱胆以及制冷设备具有上述的有益效果。
下面,结合上述的风道组件,对箱胆的结构进行说明。
箱胆包括箱胆本体300和设于箱胆本体300内的风道组件200,风道组件200将箱胆本体300内的空间分隔为第一间室410和第二间室420。
如图39至41所示,箱胆本体300设置有第一通道312,隔板部件210的内部形成有空腔216,隔板部件210的侧边设置有第二通道218,第一通道312与第二通道218一一对应,空腔216、第二通道218与第一通道312连通。
这里需要说明的是,第二通道218可以设置于第二板体212的侧边,也可以设置于第一板体211的侧边。
通过在箱胆本体300设置第一通道312,并在隔板部件210的侧边设置第二通道218,隔板部件210装入箱胆本体300后,第一通道312与第二通道218配合构成了发泡胶进入空腔216的发泡胶通道,使得隔板部件210可以与箱胆本体300一同进行发泡;发泡前可将蒸发器230、风道部件220和排水板100等部件提前装配于隔板部件210形成风道组件200,再将风道组件200装入箱胆本体300内一同进行发泡,实现模块化安装方式;相较于相关技术中的安装方式,有效简化了安装步骤,缩短了安装时间,提高了生产效率。
当箱胆应用于制冷设备,制冷设备的柜体包括箱胆本体300,箱胆本体300构造有第一通道312,隔板部件的内部形成有空腔216,隔板部件的侧边设置有第二通道218,第二通道218、空腔216与第一通道312连通,以形成发泡空间,实现风道组件与箱胆本体300一体发泡成型,保证风道组件200连接部位的密封性能。
制冷设备的柜体400包括设于箱胆本体300外侧的外壳,外壳与箱胆本体300之间形成有发泡腔,箱胆本体构造有第一通道312,隔板部件210的内部形成有空腔216,隔板部件的侧边设置有第二通道218,发泡腔、第二通道218、空腔216与第一通道312连通,以形成发泡空间,实现风道组件与柜体一体发泡成型,简化加工工序。
在本公开的实施例中,隔板部件210构造有与空腔216连通的凹部217,凹部217与第二通道218连通,凹部217设置在空腔216的外围,发泡胶首先通过第二通道218进入凹部217内,再通过凹部217从不同的方向进入间隙,使得发泡胶迅速将整个间隙填充,形成第一保温层213,缩短了发泡时间,提高了发泡效率。
当隔板部件210包括第一板体211和第二板体212,第二板体212的边沿向下凹陷形成有与空腔216连通的凹部217,凹部217呈U型,第二板体212的侧边设置有与凹部217连通的通孔,即第二通道218。第二板体212的底部设置有凹槽,第二板体212的中部与第一板体211之间的间隙较小,发泡过程中发泡胶进入间隙的速度较慢。通过在第二板体212的边沿设置凹部217,发泡胶首先通过第二通道218进入凹部217内,再通过凹部217从不同的方向进入间隙,使得发泡胶迅速将整个间隙填充,形成第一保温层213,缩短了发泡时间,提高了发泡效率。
如图41所示,箱胆本体300设置有卡槽311,隔板部件210的侧边与卡槽311卡接连接,第一通道312为设置于卡槽311的通孔。安装时,只需将隔板部件210的侧边与卡槽311卡接连接,再对隔板部件210与箱胆本体300一同进行发泡,便可完成风道组件200的安装,有效简化了安装步骤,缩短了安装时间,提高了工作效率。
这里需要说明的是,第二通道218与第一通道312均为通孔的形式,当然也可是条形缝隙的形式。安装结构具体结构形式并不限定于卡槽311,也可采用卡扣或者其他连接结构。
在本实用新型的实施例中,如图41所示,制冷设备的箱胆还包括回风部件430,回风部件430设置于第一间室410的内壁,回风部件430与第一进风口201连通。当风机270启动时,第一间室410内的空气通过回风部件430进入第一腔体282,以与蒸发器230进行热量交换,空气的温度降低变成冷空气,冷空气再通过第一排风口203和第二排风口204分别进入第一间室410和第二间室420。
通过将回风部件430设置于第一间室410的内壁,方便对回风部件430进行维护,避免了发泡工艺对回风部件430的影响,简化了制冷设备的安装步骤,提高了生产效率;由于回风部件430位于第一间室410内,减小了箱胆本体300与外壳之间的空间,增加了箱胆本体300的储存空间,有效提高了箱胆本体300的容量。
如图41所示,回风部件430包括回风管431,第一间室410的内壁设置有定位槽313,回风管431嵌入于对应的定位槽313内,回风管431的出风口与对应的第一进风口201连通。
通过将回风管431嵌入定位槽313内,减小了回风部件430占用的空间,有助于提升制冷设备的储物空间,提供一种大容量的制冷设备。
回风管431的出风口与第一进风口201可拆卸连接,通过将回风管431的出风口与第一进风口201可拆卸连接。第一进风口201的形状和尺寸与回风部件430出风口的形状和尺寸相适配。第一进风口201可以设置于第一板体211的侧边,也可以设置于第二板体212的侧边。
如图41所示,回风管431沿着上下方向设置,回风管431的上端形成有与回风管431的出风口连通的主回风口432,回风管431的一侧形成有与回风管431的出风口连通的辅助回风口433。
回风部件430包括两个回风管431,第一间室410的左侧壁和右侧壁分别设置有上下延伸的定位槽313,定位槽313分别位于左侧壁和右侧壁靠近门体的一侧,两个回风管431分别嵌入对应的定位槽313内。
由于门体附近的冷风温度最高,通过将回风部件430设置于内壁靠近门体的一侧,回风部件430可将门体附近的冷空气通过回风部件430回流第一腔体282内进行热量交换,有效避免排风口出来的冷风直接进入回风部件430,提高了制冷设备的制冷效率。
下面结合上述的风道组件,提供制冷设备的实施方式。
制冷设备包括柜体和风道组件,风道组件位于柜体内并分隔出第一间室和第二间室,风道组件包括隔板部件、风道部件、蒸发器和排水板,隔板部件与风道部件限制出第一腔体、第一进风口、第二进风口、第一排风口和第二排风口,第一进风口、第一腔体、第一排风口和第一间室适于连通,第二进风口、第一腔体、第二排风口和第二间室适于连通;第一腔体内设置蒸发器和排水板,风道部件支撑排水板,排水板位于蒸发器的下方,蒸发器与水平面 的夹角小于或等于预设角度,或,蒸发器与水平面相平行。蒸发器横置在风道组件内,且蒸发器相对于水平面向下倾斜的角度可控制在预设角度之内,或蒸发器可水平设置,可减小蒸发器所占用的高度空间,进而减小风道组件的整体高度,可减小风道组件所占用的柜体内的空间,柜体内的储物空间可相应增大,可提供一种大容量的制冷设备。
一些情况下,第一间室位于第二间室的上方,第一间室为冷藏室,第二间室为冷冻室。
第一进风口位于风道组件的左侧和右侧且靠近风道组件的前侧,第一进风口与风道组件上方的第一间室连通。第二进风口位于风道组件的前侧,第二进风口与风道组件下方的第二间室连通。
排水板可为上述一种或多个结构,具体可参见上述内容,此处不再赘述。风道组件的排水结构可为上述的排水方式,如侧排水的第一排水部件,后排水的第二排水部件,或者导水件223进行排水,或者多种排水方式的结合。
风道组件还包括风机270,风机270设于蒸发器的一侧,风机270可横向设置或竖向设置,具体可参见上述关于风机270的说明。风道组件200还包括与风机配合使用的风机罩、风机盖板243等结构,也可参见上述内容,此处不再赘述。
箱胆本体300、隔板部件210、风道部件220以及其他结构均可参见上述内容,此处不再赘述。
以上实施方式仅用于说明本公开,而非对本公开的限制。尽管参照实施例对本公开进行了详细说明,本领域的普通技术人员应当理解,对本公开的技术方案进行各种组合、修改或者等同替换,都不脱离本公开技术方案的精神和范围,均应涵盖在本公开的权利要求范围中。
Claims (14)
- 一种制冷设备,其特征在于,包括:柜体;风道组件,位于所述柜体内并分隔出第一间室和第二间室,包括隔板部件、风道部件、蒸发器和排水板,所述隔板部件与所述风道部件限制出第一腔体、第一进风口、第二进风口、第一排风口和第二排风口,所述第一进风口、第一腔体、第一排风口和所述第一间室适于连通,所述第二进风口、所述第一腔体、所述第二排风口和所述第二间室适于连通;所述第一腔体内设置所述蒸发器和所述排水板,所述风道部件支撑所述排水板,所述蒸发器与水平面的夹角小于或等于预设角度,或,所述蒸发器与水平面相平行。
- 根据权利要求1所述的制冷设备,其特征在于,所述排水板构造有相对于所述排水板的顶面向下凹陷的导水部,所述导水部的延伸方向与所述风道组件的出风方向形成第四夹角。
- 根据权利要求2所述的制冷设备,其特征在于,所述排水板构造有相对于所述排水板的顶面向下凹陷的排水部,所述排水部构造有出口,所述排水部与所述导水部连通。
- 根据权利要求3所述的制冷设备,其特征在于,朝向所述排水部的方向,所述导水部的底部沿第一方向倾斜,所述第一方向与所述排水板的顶面形成第六夹角,以使所述导水部向所述排水部的方向凹陷的深度逐渐增大。
- 根据权利要求3所述的制冷设备,其特征在于,朝向所述出口的方向,所述排水部的底部沿第二方向倾斜,所述第二方向与所述排水板的顶面形成第七夹角,以使所述排水部向所述出口的方向凹陷的深度逐渐增大。
- 根据权利要求2所述的制冷设备,其特征在于,所述导水部延伸至所述排水板的端部并形成开口,所述开口所在侧设置有第一排水部件。
- 根据权利要求1所述的制冷设备,其特征在于,还包括风机,所述风机的转动轴线与竖直方向形成第一夹角。
- 根据权利要求1所述的制冷设备,其特征在于,还包括风机和风机盖板,所述风机设于所述蒸发器的一侧,所述风机盖板位于所述风机与所述蒸发器之间,所述风机的进口通过所述风机盖板的通风口与所述第一腔体连通,所述风机盖板构造有所述第一排风口和所述第二排风口。
- 根据权利要求1所述的制冷设备,其特征在于,所述柜体包括箱胆本体,所述箱胆本体构造有第一通道,所述隔板部件的内部形成有空腔,所述隔板部件的侧边设置有第二通道,所述第二通道、所述空腔与所述第一通道连通。
- 根据权利要求9所述的制冷设备,其特征在于,所述隔板部件包括:第一板体;第二板体,设置于所述第一板体的下方,所述第二板体与所述第一板体围成所述空腔,所述第二板体的边沿向下凹陷形成有与所述空腔连通的凹部,所述凹部与所述第二通道连通。
- 根据权利要求1至10中任意一项所述的制冷设备,其特征在于,所述隔板部件与所述风道部件中的至少一个设置有分隔部,所述分隔部在所述第一进风口处的正投影覆盖所述第一进风口的局部面积,所述正投影位于所述第一进风口靠近所述第二进风口的一端,所述分隔部与所述第一进风口之间间隔预设间距。
- 根据权利要求1至10中任意一项所述的制冷设备,其特征在于,所述第二进风口设置于所述风道部件的前侧,所述隔板部件的前侧设置有遮蔽所述第二进风口的安装部。
- 根据权利要求1至10中任意一项所述的制冷设备,其特征在于,所述第一进风口位于所述风道组件的左侧和右侧且靠近所述风道组件的前侧。
- 根据权利要求1至10中任意一项所述的制冷设备,其特征在于,所述第一间室位于所述第二间室的上方,所述第一间室为冷藏室,所述第二间室为冷冻室。
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