CN217058121U - Air duct assembly and refrigeration equipment - Google Patents

Abstract

The utility model relates to a refrigeration plant technical field provides a wind channel subassembly and refrigeration plant. The air duct assembly comprises a partition plate component and an air duct component; the air duct component and the partition plate component define a first cavity, a first air inlet, a second air inlet and an air outlet which are communicated, the first air inlet is positioned on the first side of the first cavity, the second air inlet is positioned on the second side of the first cavity, and the first side is adjacent to the second side; the partition plate component and at least one of the air duct components are provided with a partition part, the partition part is arranged at the position, at the first air inlet, of an orthographic projection covering the local area of the first air inlet, the orthographic projection is located at the position, close to the second side, of the first air inlet, and a preset interval is arranged between the partition part and the first air inlet. The utility model provides a wind channel subassembly, partly air inlet accessible partition guide reposition of redundant personnel reduce the air inlet amount of wind of cross contact, and then reduce the frosting volume, guarantee the mobility of wind.

Description

Air duct assembly and refrigeration equipment

Technical Field

The utility model relates to a refrigeration plant technical field especially relates to wind channel subassembly and refrigeration plant.

Background

With the improvement of life quality, consumers have higher and higher requirements on the storage space in the refrigerator, and the size of the storage space in the refrigerator also becomes a concern of the consumers. How to increase the storage space of the refrigerator under the condition that the volume of the refrigerator is not changed becomes a research and development direction of technicians. The components of the refrigeration system occupy a part of the volume of the cabinet body, and the installation positions of the components of the refrigeration system in the cabinet body affect the volume of the cabinet body and the size of the storage space limited by the cabinet body. When an evaporator in the refrigerating system is arranged at the rear side of a refrigerating chamber of the refrigerator, the thickness of the cabinet body is larger, and the storage space in the depth direction of the cabinet body is insufficient. The evaporimeter among refrigerating system is horizontal between two rooms, and the evaporimeter does not occupy the space of refrigeration room rear side, and based on this structure, cold-stored return air can intersect with freezing return air in the evaporimeter towards one side of air intake, and leads to the water of evaporimeter towards one side of air intake to condense into the frost easily, and the return air route can be blockked up to the frost, leads to wind circulation flow and heat transfer effect not good, and equipment energy consumption is big, and user experience is not good.

SUMMERY OF THE UTILITY MODEL

The present invention aims to solve at least one of the technical problems existing in the related art. Therefore, the utility model provides a wind channel subassembly, the reposition of redundant personnel of partly air inlet accessible partition guide reduces the air inlet amount of wind of cross contact, and then reduces the frosting volume, guarantees the mobility and the heat transfer effect of wind, reduces and changes the frost number, reaches energy saving and consumption reduction's effect.

The utility model discloses still provide a refrigeration plant.

According to the utility model discloses wind channel subassembly of first aspect embodiment, include:

a partition member;

the air duct component is communicated with the partition plate component to define a first cavity, a first air inlet, a second air inlet and an air outlet, the first air inlet is positioned on the first side of the first cavity, the second air inlet is positioned on the second side of the first cavity, and the first side is adjacent to the second side;

at least one of the partition plate component and the air duct component is provided with a partition part, the orthographic projection of the partition part at the first air inlet covers the local area of the first air inlet, the orthographic projection is positioned at one end, close to the second side, of the first air inlet, and a preset interval is arranged between the partition part and the first air inlet.

According to the utility model discloses air duct assembly, including partition plate part and air duct component, at least one among partition plate part and the air duct component sets up the partition portion, and the partition portion can block partly air inlet for this part air inlet flows along the direction of partition portion, and then has reduced cross contact's the amount of wind in the two parts air inlet, reduces the volume of frosting, and the extension is twice when the interval of defrosting, reduces the number of times of defrosting, reduces power consumption, and simple structure.

According to an embodiment of the utility model, first air intake to the direction of partition portion has the partition portion the partition part or the wind channel part is provided with the spigot surface, the spigot surface is the curved surface, the partition portion is located the first end of spigot surface and with first end is tangent, the second end orientation of spigot surface is restricted out the first wall of first air intake extends. The guide surface guides partial inlet air of the first air inlet.

According to the utility model discloses an embodiment, the guide surface includes plane portion and curved surface portion, the one end of curved surface portion is connected the partition portion, the other end of curved surface portion is connected plane portion and with plane portion is tangent, the plane portion orientation the direction of first wall extends. The air inlet is guided along the guide surface, and the smooth flow of the air is facilitated.

According to the utility model discloses an embodiment, the wind channel part is provided with second air inlet portion, the second air inlet portion constructs the second air intake, the both ends of second air inlet portion all set up the partition portion, with the adjacent both sides in second side all set up first air intake.

According to the utility model discloses an embodiment, wind channel part integrated into one piece has the partition portion, stable in structure can also reduce spare part quantity.

According to an embodiment of the present invention, the height of the partition is less than or equal to 1/3 of the height of the first air inlet;

and/or the height of the partition part is less than or equal to 1/3 of the length of the first air inlet; the shunting effect and the flowability of the inlet air can be ensured.

According to the utility model discloses an embodiment, set up the evaporimeter in the first cavity, the fin of evaporimeter with the partition portion all follows the second air intake to the direction of air exit extends, and the fin can play the effect of air-guiding.

According to the utility model discloses an embodiment, set up the evaporimeter in the first cavity, the evaporimeter is less than or equal to with the contained angle of horizontal direction and predetermines the angle, or, the evaporimeter parallels with the horizontal direction. The small height occupied by the evaporator helps reduce the volume of the duct assembly.

According to one embodiment of the utility model, the air duct component supports the drain board,

the drain board includes:

a drain part configured with an outlet recessed with respect to a top surface of the drain plate;

the water guide portion, with the water drainage portion intercommunication, for the top surface of drain bar is sunken, the extending direction of water guide portion with the air-out direction of drain bar top forms first contained angle, orientation the direction of water drainage portion, the first direction slope is followed to the bottom of water guide portion, first direction with the top surface of drain bar forms the sixth contained angle. The drain board can guarantee drainage effect and heat transfer effect.

According to the utility model discloses an embodiment, the wind channel part includes first supporting part and is located the second heat preservation of first supporting part top, the upper surface of second heat preservation with the lower surface looks adaptation of drain bar, the lower surface structure of second heat preservation has the edge the first support inclined plane of first direction slope, first supporting part structure have with the second support inclined plane of first support inclined plane looks adaptation. The bottom of the air duct assembly is formed by connecting a plurality of inclined planes, so that the heat insulation performance can be ensured, and the thickness of the air duct assembly is not required to be increased.

According to the utility model discloses refrigeration plant of second aspect embodiment, including the cabinet body and as above the wind channel subassembly, the wind channel subassembly is located in the storing space of the cabinet body and separate first compartment and second compartment, first air intake with first compartment intercommunication, the second air intake with second compartment intercommunication.

According to the utility model discloses refrigeration plant, through the partition portion of wind channel subassembly, the frosting amount of reducible air inlet cross contact position reduces the frost number, and the extension changes the frost cycle, reduces the power consumption of changing the frost, plays the energy-conserving effect of power saving, can also guarantee that wind circulation flows and improves the heat transfer effect, makes refrigeration plant's operating stability better and power consumption lower.

Additional aspects and advantages of the invention will be set forth in part in the description which follows and, in part, will be obvious from the description, or may be learned by practice of the invention.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention or the related art, the drawings required to be used in the description of the embodiments or the related art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the drawings without creative efforts.

Fig. 1 is a schematic structural view of a refrigeration apparatus provided in an embodiment of the present invention, in which a door body is not shown;

fig. 2 is a schematic view of a partial structure of a refrigeration apparatus provided in an embodiment of the present invention, in which the partial structure of the cabinet and the tank liner are not shown;

FIG. 3 is a schematic view of a portion of the enlarged structure of A in FIG. 2;

fig. 4 is a schematic partial structural view of an air duct assembly according to an embodiment of the present invention;

fig. 5 is a schematic diagram illustrating an exploded view of a portion of an air duct assembly according to an embodiment of the present invention;

fig. 6 is an exploded structural view of an air duct assembly according to an embodiment of the present invention;

fig. 7 is a schematic top view of a portion of an air duct assembly according to an embodiment of the present invention, without showing the components above the drain plate;

FIG. 8 is a schematic cross-sectional view of B-B of FIG. 7;

fig. 9 is a schematic side view of a partial structure of an air duct assembly according to an embodiment of the present invention;

fig. 10 is a schematic partial structure view of another refrigeration apparatus according to an embodiment of the present invention, which is different from fig. 2 in that the drain plate has a different structure, and a door body is not shown in the figure;

FIG. 11 is an enlarged partial view of the structure of the portion C in FIG. 10;

FIG. 12 is a schematic view of a portion of another embodiment of an air duct assembly according to the present invention, illustrating the components above the drain plate;

fig. 13 is a schematic view of a partially exploded view of another air duct assembly according to an embodiment of the present invention;

fig. 14 is a schematic longitudinal sectional view of a third air duct assembly according to an embodiment of the present invention, illustrating a position of a fan;

fig. 15 is a schematic view of a portion of a third air duct assembly according to an embodiment of the present invention, in which the components above the drain plate are not shown;

FIG. 16 is a schematic view of a third air duct assembly according to an embodiment of the present invention in a partially exploded configuration;

fig. 17 is a schematic structural diagram of a third refrigeration plant provided in the embodiment of the present invention, in which a door body is not shown;

fig. 18 is a schematic longitudinal sectional structural view of a third refrigeration equipment provided by the embodiment of the present invention;

FIG. 19 is an enlarged partial view of the area D in FIG. 18;

fig. 20 is an exploded structural view of a fourth air duct assembly according to an embodiment of the present invention;

fig. 21 is a schematic bottom view of a fourth air duct assembly according to an embodiment of the present invention;

fig. 22 is a schematic perspective view of a drainage plate provided by an embodiment of the present invention;

fig. 23 is a schematic top view of a drainage plate provided by an embodiment of the present invention;

FIG. 24 is a schematic cross-sectional view of E-E of FIG. 23;

FIG. 25 is a schematic cross-sectional view of the structure of FIG. 23 from F to F;

fig. 26 is a schematic structural view of a second plate in a partition plate component of an air duct assembly according to an embodiment of the present invention and an installation state thereof;

fig. 27 is a schematic structural view of another second plate and an installation state thereof in a partition plate member of an air duct assembly according to an embodiment of the present invention;

fig. 28 is a schematic structural view of a first concave portion and a second concave portion of a second plate in a partition plate member of an air duct assembly according to an embodiment of the present invention;

fig. 29 is a schematic structural view of a third concave portion of the second plate in the partition plate member of the air duct assembly according to the embodiment of the present invention;

fig. 30 is a schematic perspective view illustrating an installation state of an evaporator and a drain board according to an embodiment of the present invention;

fig. 31 is a schematic side view of an evaporator and a drain board according to an embodiment of the present invention;

fig. 32 is a schematic view showing an exploded state of an evaporator, a drain board and a heating element according to an embodiment of the present invention;

fig. 33 is a second exploded view of the evaporator, the drain board and the heating element according to the embodiment of the present invention;

fig. 34 is a schematic view illustrating an installation state of the evaporator, the drain plate and the second heater according to the embodiment of the present invention;

fig. 35 is a schematic view illustrating an exploded state of the evaporator, the drain plate and the secondary heater according to the embodiment of the present invention;

fig. 36 is a schematic view illustrating an installation state of the evaporator, the drain plate and the air duct unit according to the embodiment of the present invention;

fig. 37 is a schematic structural view of a first support portion of an air duct member according to an embodiment of the present invention;

fig. 38 is a partially enlarged schematic view of a portion H in fig. 37.

Reference numerals:

100. a drain plate; 110. a water discharge part; 111. a first water discharge portion; 112. a second drain section; 113. a second flow guide surface; 114. an outlet; 115. a third water discharge part; 120. a first water guide part; 121. a first flow guide surface; 123. a first water conducting area; 124. a second water conducting area; 130. a second water guide part; 131. a third flow guide surface; 140. a third water guide part; 141. a fourth flow guide surface; 150. flanging; 151. a positioning part; 160. a heating member; 170. an opening;

200. an air duct assembly; 201. a first air inlet; 202. a second air inlet; 203. a first exhaust port; 204. a second air outlet;

210. a partition member; 211. a first plate body; 212. a second plate body; 2121. a first concave portion; 2122. a first guide surface; 2123. a first top surface; 2124. a second concave portion; 2125. a second guide surface; 2126. a second top surface; 2127. a third concave portion; 2128. a third top surface; 2129. a third guide surface; 213. a first insulating layer; 214. a third plate body; 215. a third wall panel;

220. an air duct member; 221. a second insulating layer; 222. a first support section; 2221. a partition portion; 2222. a guide surface; 22221. a curved surface portion; 22222. a planar portion; 2223. a baffle; 2224. a second support ramp; 2225. a second supporting groove; 223. a water guide; 2231. a third drain pipe; 224. a third insulating layer; 225. a second support portion; 226. a heating member;

230. an evaporator; 231. a first heater; 232. a second heater; 233. a heat exchange pipe; 234. a heat sink; 2341. a first heat sink; 2342. a second heat sink; 23421. a ventilation portion; 2343. mounting holes;

240. a fan guard; 241. a first cover body; 2411. a flow directing surface; 242. a second cover; 2421. a first water guide passage; 2422. a barrier portion; 2423. a third water discharge port; 2424. a first air guiding part; 2425. a second air guiding part; 2426. a second mounting post; 2427. a partition plate; 2428. a water collection part; 243. a fan cover plate; 2431. a third air guiding part; 2432. a fourth air guiding part; 244. a vent;

250. a first damper;

260. a first drainage member; 262. a first drain port; 263. a first drain pipe; 264. a first wall panel; 265. a second wall panel;

270. a fan; 271. a fan mounting base;

281. a second cavity; 282. a first cavity;

290. a second drain part; 291. a second drain pipe;

400. a cabinet body; 410. a first compartment; 420. a second compartment; 430. an air return component;

α ₁ a first included angle; alpha (alpha) ("alpha") ₂ A second included angle; alpha is alpha ₃ And a third included angle;

θ ₂ a sixth included angle; theta.theta. ₃ And a seventh included angle.

Detailed Description

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings and examples. The following examples are intended to illustrate the invention, but are not intended to limit the scope of the invention.

In the description of the embodiments of the present invention, it should be noted that the terms "center", "longitudinal", "lateral", "up", "down", "front", "back", "left", "right", "vertical", "horizontal", "top", "bottom", "inner", "outer", and the like indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, and are only for convenience of describing the embodiments of the present invention and simplifying the description, but do not indicate or imply that the device or element referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the embodiments of the present invention. Furthermore, the terms "first," "second," and "third" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance. In the description of the present invention, the terms "plurality", and "plural" mean two or more unless otherwise specified.

In the description of the embodiments of the present invention, it should be noted that, unless otherwise explicitly specified or limited, the terms "connected" and "connected" should be interpreted broadly, and may be, for example, a fixed connection, a detachable connection, or an integral connection; can be mechanically or electrically connected; may be directly connected or indirectly connected through an intermediate. The specific meaning of the above terms in the embodiments of the present invention can be understood in specific cases by those skilled in the art.

In embodiments of the invention, unless expressly stated or limited otherwise, the first feature may be directly on or directly under the second feature or indirectly via intermediate members. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

In the description of the present specification, references to the description of "one embodiment," "some embodiments," "an example," "a specific example," or "some examples" or the like are intended to mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the embodiments of the present invention. In this specification, the schematic representations of the terms used above are not necessarily intended to refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples. Moreover, various embodiments or examples and features of various embodiments or examples described in this specification can be combined and combined by one skilled in the art without being mutually inconsistent.

The embodiment of the utility model, combine fig. 1 to 38 to show, provide a refrigeration plant, including the cabinet body 400, the cabinet body 400 includes the case courage.

The refrigeration equipment can be a refrigerator, a freezer, a display cabinet, a vending cabinet or a wine cabinet and the like, and can be used for refrigeration or freezing.

In the following embodiments, the front, rear, left, right, up and down directions correspond to the directions of the refrigeration equipment one by one.

The embodiment of the utility model provides a box courage is provided, and the box courage includes box courage body and wind channel subassembly 200, and this internal space of box courage separates mutually independent first compartment 410 and second compartment 420 through wind channel subassembly 200.

The duct assembly 200 may serve to separate compartments and also 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 position of the air duct assembly 200 and the cabinet body needs to be sealed, so as to avoid air leakage between the first compartment 410 and the second compartment 420.

The embodiment of the utility model provides an air duct assembly 200, air duct assembly 200 can divide into first room 410 and the second room 420 two parts with this internal whole space of case courage, perhaps, air duct assembly 200 becomes first room 410 and the second room 420 two parts with this internal local space separation of case courage.

Air duct assembly 200 provides independent air flow to first compartment 410 and second compartment 420, and the functions of first compartment 410 and second compartment 420 may be the same or different. When the first compartment 410 and the second compartment 420 have different functions, that is, the first compartment 410 and the second compartment 420 have different ambient temperatures, the first compartment 410 may be a refrigerating compartment, and the second compartment 420 may be a freezing compartment, and the air duct assembly 200 supplies air to the refrigerating compartment at a lower frequency than the air to the freezing compartment. When the first compartment 410 and the second compartment 420 have the same function, such as both of the refrigerating compartments, and the ambient temperatures of the two refrigerating compartments may be the same or different, at this time, the frequency of the air duct assembly 200 supplying air to the two refrigerating compartments may be the same or different, and may be specifically set as required. Of course, the compartment separated by the air duct assembly 200 is not limited to refrigeration and freezing, and may also be a temperature changing compartment or other functional compartments, which may be specifically configured as required.

When the cabinet body 400 is connected with a door body, and the door body is located at the position of the closed cabinet body 400, the first compartment 410 and the second compartment 420 are two closed and independent spaces; when the door body is in a position for opening the cabinet 400, articles can be taken from or placed in at least one of the first compartment 410 and the second compartment 420.

Wherein, the number of the air duct assembly 200 arranged in the refrigerating apparatus can be set according to the requirement.

It is understood that, as shown in fig. 2 to 3, 10, 11 and 17 to 20, the air duct assembly 200 includes a partition member 210, an air duct member 220, an evaporator 230 and a drain plate 100, the partition member 210 is located above the air duct member 220, the partition member 210 and the air duct member 220 form a first cavity 282, an air inlet adapted to communicate with the first cavity 282 and an air outlet adapted to communicate with the first cavity 282, the evaporator 230 and the drain plate 100 are disposed in the first cavity 282, and the drain plate 100 is located below the evaporator 230. The partition member 210 and the air duct member 220 together limit the air inlet, the first cavity 282 and the air outlet which are communicated with each other, so that the air entering the air duct assembly 200 is exhausted after exchanging heat.

As shown in fig. 1 and 2, the partition member 210 is coupled to the cabinet body, and the junction of the partition member 210 and the cabinet body is sealed to divide the space inside the cabinet body into a first compartment 410 and a second compartment 420, which are independent of each other. The first cavity 282 between the partition member 210 and the air duct member 220 is used for installing the evaporator 230, the drain plate 100, the heating structure for defrosting, and the like, so as to meet the heat exchange requirement of the first compartment 410 and the second compartment 420.

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, the first air inlet 201, the first cavity 282, the first air outlet 203 and the first compartment 410 are communicated to form a first circulation path, the second air inlet 202, the first cavity 282, the second air outlet 204 and the second compartment 420 are communicated to form a second circulation path, and the first circulation path is communicated 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 intake vent 201, the second intake vent 202, the first exhaust vent 203, and the second exhaust vent 204 are not limited.

As shown in fig. 1 and 2, the first compartment 410 is located above the air duct assembly 200, the first compartment 410 is provided as a refrigerating compartment, the second compartment 420 is located below the air duct assembly 200, the second compartment 420 is provided as a freezing compartment, that is, the first compartment 410 is located above the second compartment 420, and the air duct assembly 200 is provided with a first exhaust opening 203 facing upward and a second exhaust opening 204 facing downward; a first air door 250 is arranged at the first air outlet 203 so as to open and close the adjustment; a second damper is provided at the second air outlet 204 for open-close regulation. 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 is communicated with the return air duct of the refrigerating chamber, the first air inlet 201 is arranged at the left and right sides of the air duct assembly 200, the second air inlet 202 is communicated with the freezing chamber, and the second air inlet 202 is arranged at the front side or the lower side of the air duct assembly 200.

It should be noted that the 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 outlet 203 and the second air outlet 204 are also close to the same end of the air duct assembly 200, and the air inlets and the air outlets are generally at opposite ends, such as the air inlets close to the front end and the air outlets close to the rear end, but the positions are not limited to the above positions, the air inlets may also be close to the left end or the right end, and the positions of the air inlets and the air outlets are flexible and can be specifically selected as needed.

In some cases, the first air inlet 201 is located on a first side of the first cavity 282, and the second air inlet 202 is located on a second side of the first cavity 282, where the first side is adjacent to the second side, that is, the first air inlet 201 and the second air inlet 202 are disposed on different sides of the air duct assembly 200, at this time, the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 meet in the first cavity 282, and when the first air inlet 201 and the second air inlet 202 have different inlet air temperatures (that is, the ambient temperatures of the first compartment 410 and the second compartment 420 are different), the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 are prone to frost formation due to contact heat exchange at the meeting position. 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.

As shown in fig. 6, the first side is at least one of the left side and the right side, and the second side is the front side.

Next, referring to fig. 1 to 16 and 20 to 25, an embodiment of the drain plate 100 is provided, and the structure of the drain plate 100 will be described by taking the example in which the drain plate 100 is installed in the air duct assembly 200. However, the drain plate 100 is not limited to the above-described air duct assembly 200, and the drain plate 100 may be mounted in other configurations suitable for mounting the drain plate 100 in the following embodiments.

The embodiment of the utility model provides a, combine fig. 1 to 7 to show, provide a drain bar 100, drain bar 100 is constructed the water guide portion for the top surface undercut of drain bar 100, and water guide portion extends to the edge of drain bar 100 to the both sides of predetermineeing the face to make drain bar 100's edge form opening 170, opening 170 towards first air intake 201 place side, so that the part air inlet of first air intake 201 is suitable for through opening 170 and along the extending direction of water guide portion in flowing into first cavity 282.

The first air inlet 201 has unlimited functions and can be communicated with the refrigerating chamber, and the water guide part guides refrigerating air; alternatively, the water guide part is communicated with the freezing chamber, and can guide the freezing air. Through setting up the water guide, be the type of falling V structure with the drain bar design, make partial cold-stored return air pass through V type structure space and get into the evaporimeter to solve the problem that the refrigerator return air condenses, reduce the contact of cold-stored return air and freezing return air, reduce and freeze return air gathering mixed condensation, make the more evenly distributed of frost in the evaporimeter, reduce the frost and block up freezing return air.

Part of the inlet air of the first air inlet 201 passes through the opening 170 and is guided into the first cavity 282 along the extending direction of the water guide part, so that part of the inlet air of the first air inlet 201 can be divided, the air quantity intersected with the inlet air of the second air inlet 202 is reduced, further, the condensed frost caused by the contact of the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 is reduced, the interval time between two times of defrosting is prolonged, the defrosting times are reduced, the power consumption required by defrosting is reduced, and the power consumption of the refrigeration equipment is reduced.

The water guiding portion is recessed downward relative to the top surface of the drain board 100, so that the drain board 100 forms a groove, a part of the intake air of the first intake port 201 can flow into the first cavity 282 along the groove, and the water guiding portion can guide the flow of the intake air therein.

The preset surface forms an included angle with the extending direction of the water guide part, the preset surface extends along the direction from the air inlet to the air outlet, and if the air inlet is located at the front end of the air duct assembly 200, the air outlet is located at the rear end of the air duct assembly 200, the preset surface extends from the front to the rear. Here, the extension trend of the preset surface is from front to back, the preset surface can be obliquely extended, and the position of the preset surface can be selected as required.

In some cases, the predetermined surface may be a symmetrical surface of the drain board 100, and the water guiding portions are symmetrically disposed on both sides of the predetermined surface, so that the drain board 100 has a symmetrical structure, and the structural stability of the drain board 100 is better.

It should be noted that the predetermined surface is not limited to be a symmetrical surface, the drainage plate 100 is not limited to form a symmetrical structure, and both sides of the predetermined surface may be asymmetrical.

The opening 170 of the drainage plate 100 may guide a portion of the intake air from the first intake port 201, and the opening 170 of the drainage plate 100 may also perform a drainage function.

When the opening 170 of the drain plate 100 functions to divert a portion of the intake air, the depth of the water guide recessed with respect to the top surface of the drain plate 100 may not be limited.

In some cases, the water guide recess gradually increases in depth toward the opening 170, and the water guide having such a structure may be referred to as a second water guide 130. That is, the second water guide part 130 has a greater depth toward one end of the opening 170, which helps guide the flow of air therein. When the evaporator 230 is placed above the drain board 100, the depth of the second water guiding part 130 is gradually increased, and the distance between the evaporator 230 and the drain board 100 can also be increased, so that the flowing space of wind is properly enlarged; but also helps the defrost water received by the drain plate 100 to drain from the opening 170.

The depth of the second water guide 130 gradually increases toward one end of the opening 170, and may be continuously increased or increased in a step shape.

It can be understood that, toward the direction of the opening 170, the bottom of the second water guide part 130 is inclined in a first predetermined direction, and the first predetermined direction forms a first predetermined included angle with the top surface of the drain plate 100. That is, the bottom surface of the second water guide part 130 is an inclined surface extending downward along the first predetermined direction, which facilitates the flow of the wind into the first cavity 282 and also facilitates the drainage of the water.

The first predetermined direction is a direction forming a first predetermined included angle with the top surface and inclined downward toward the opening 170 along the predetermined surface, and the size of the first predetermined included angle can be selected as required.

In order to reduce the size of the drain bar 100 in the height direction, a first preset included angle can be an included angle smaller than or equal to 7 degrees, the drainage effect and the air guide effect can meet the requirements, the size of the air duct assembly 200 in the height direction can also be reduced, the height direction space in the cabinet body 400 occupied by the air duct assembly 200 is reduced, the compartment space in the cabinet body 400 is increased, and therefore the refrigeration equipment with large capacity is provided.

Under some circumstances, first preset contained angle sets up to 3, and 3 can satisfy drain bar 100's drainage demand, can also fully reduce drain bar 100's height, realize the low-angle drainage. Of course, the first preset included angle may also be set to 1 °, 2 °, 4 °, 5 °, 6 °, or 7 °.

Of course, the depth of the second water guide part recess may be constant (not shown), and the second water guide part recess may have a uniform depth, and may also perform the functions of guiding and draining water.

It is understood that the water guide includes a guide surface disposed along an extending direction of the water guide, the guide surface being adjacent to an opposite side surface thereof in a direction from the top surface to the bottom surface of the drain board 100. That is, the second water guide 130 is provided with a third guide surface 131 along the extending direction thereof, the third guide surface 131 is close to the opposite side surface from the top surface to the bottom surface of the drain board 100, and the third guide surface 131 is an inclined surface inclined to the opposite side thereof.

The defrosting water received by the top surface of the drainage plate 100 and the third flow guiding surface 131 may fall into the bottom of the water guide part along the flow guiding direction of the third flow guiding surface 131, so that the defrosting water is collected in the water guide part, and the water in the water guide part is drained.

The opposite side of the third guiding surface 131 may be a vertically disposed surface, or may also be a guiding surface, which may be specifically selected as required. As shown in fig. 5 and 6, both opposite side surfaces of the second water guide part 130 are third guide surfaces 131.

As shown in fig. 5 to 7, a plurality of second water guides 130 are disposed on each side of the predetermined surface of the drain board 100, the plurality of second water guides 130 are disposed in parallel, and a plurality of openings 170 are formed on both sides of the drain board 100, so that part of the intake air from the first intake port 201 can enter the first cavity 282 along the plurality of openings 170.

At the preset height position, the width of the second water guide 130 gradually decreases toward the opening 170, so that the water received in the second water guide 130 can be collected toward the opening 170.

As shown in fig. 1 to 7 and described above, the drain board 100 having the second water guide 130 may not include the drain 110.

Referring to fig. 1 to 16 and 20 to 25, in an embodiment of the present invention, another water drainage plate 100 is provided, the water drainage plate 100 is configured with a water guiding portion recessed relative to a top surface of the water drainage plate 100, and an extending direction of the water guiding portion forms a fourth included angle with an air outlet direction above the water drainage plate 100.

When the drain plate 100 and the evaporator 230 are both disposed in the first cavity 282 of the air duct assembly 200, the wind enters the first cavity 282 from the wind inlet of the air duct assembly 200 and flows toward the wind outlet, and the wind in the first cavity 282 flows in the space between the drain plate 100 and the evaporator 230 and the space inside the evaporator 230. When wind flows between the drainage plate 100 and the evaporator 230, the water guide part forms a fourth included angle θ 1 with the wind outlet direction, so that the wind can be inhibited from directly flowing to the air outlet from the water guide part, the staying time of the wind in the first cavity 282 is prolonged, the wind is fully contacted with the evaporator 230 and heat exchange is carried out, the wind after heat exchange is discharged from the air outlet, and the heat exchange efficiency is promoted.

The air outlet direction is the direction from the air inlet to the air outlet, and in some cases, only one air inlet and one air outlet are arranged in a one-to-one corresponding relationship to form an air outlet direction; in some cases, at least one of the air inlet and the air outlet is provided with a plurality of air outlets, and a plurality of air outlet directions can be formed. The extending direction of the water guide part forms an included angle with at least one air outlet direction, and the included angle can be in one direction, so that the heat exchange efficiency of air is ensured; of course, the extending direction of the water guide part and all the air outlet directions form included angles, so that effective heat exchange of the air in a plurality of flow paths can be guaranteed, and the heat exchange efficiency can be guaranteed. The air inlet is generally disposed at one end of the air duct assembly 200 near the front, the air outlet is generally disposed at one end of the air duct assembly 200 near the rear, and the air outlet direction can be from front to rear.

When the air inlets are divided into the first air inlet 201 and the second air inlet 202, the second air inlet 202 is disposed in front of the air duct assembly 200, the air outlet is disposed behind the air duct assembly 200, a communication path between the second air inlet 202 and the air outlet forms a first air outlet direction, and the second air inlet 202 corresponds to a position below the evaporator 230, so that the air flows along a direction from bottom to top and from front to back.

In the drainage board 100 of this embodiment, an included angle is formed between the extending direction of the water guide portion and the first air outlet direction, that is, an included angle is formed between the extending direction of the water guide portion and the front-back direction. The first air inlet 201 may be disposed at least one of the left and right sides of the air duct assembly 200, a communication path between the first air inlet 201 and the air outlet forms a second air outlet direction, and an extending direction of the water guide portion forms an included angle with the second air outlet direction. The extension direction of the water guide part and the first air-out direction form an included angle, and the extension direction of the water guide part and the second air-out direction also form an included angle, which can be understood as a fourth included angle, but the specific angle values can be the same or different.

The extending direction of the water guide may be a straight path or a curved path. When the extension path of the water guide part is a straight path, a path from one end of the water guide part far away from the drain part 110 to the other end of the water guide part communicating with the drain part 110 is an extension path; when the extended path of the water guide portion is a curved path, the water guide portion of the curved path may have a plurality of ends communicating with the drain portion 110, the curved path may be a polygonal line path formed by a plurality of straight line paths, or the curved path may be a curve having one or more curvature radii, and the shape of the curved path may be set as desired. The extending direction of one water guide part can form one or more included angles with the air outlet direction, namely the fourth included angle can be one or more angle values, and can be specifically set as required. Referring to fig. 10 to 25, in an embodiment of the present invention, another drain board 100 is provided, in which the drain board 100 is configured with a drain portion 110 and a water guide portion, the drain portion 110 is configured with an outlet 114, and the drain portion 110 is recessed with respect to a top surface of the drain board 100; the water guide part is communicated with the water discharge part 110, the water guide part is sunken relative to the top surface of the water discharge plate 100, and a fifth included angle theta 1 is formed between the extending direction of the water guide part and the air outlet direction above the water discharge plate 100.

In a use state, the drain plate 100 is disposed below the evaporator 230 for receiving the defrosting water generated when the frost on the surface of the evaporator 230 is heated. A part of the water falls into the water guide portion and is guided into the drain portion 110 along the extending direction of the water guide portion, and a plurality of water guide portions are generally provided, and the water received by each water guide portion is collected into the drain portion 110 and is discharged through the outlet 114 of the drain portion 110. The other part of the water directly falls into the drain part 110 and is discharged through the drain part 110.

The water guide part is arranged in the water discharging plate, and the water guide part is arranged in the water discharging plate; and in the water discharging plate only provided with the water guide part, the extending direction of the water guide part and the air outlet direction form an included angle which is a fourth included angle. The angle values of the fifth angle and the fourth angle can be selected according to needs, and are not limited herein.

In fig. 23, a solid arrow above the drain board 100 indicates an extending direction of the water guiding portion, a dotted arrow indicates an air outlet direction, and indicates a fifth included angle θ 1, which indicates a case where the fifth included angle is 90 °.

It should be noted that the water guiding part and the water discharging part 110 are both recessed based on the top surface of the water discharging plate 100, the top surface may be a plane or a curved surface, and the top surface may be a surface defined by a plurality of lines or a surface defined by a plurality of surfaces. Correspondingly, the bottom of the water guide part and the bottom of the drain part 110 form the bottom surface of the drain board 100, the bottom surface may also be a plane or a curved surface, and the bottom surface may be a surface defined by a plurality of lines or a surface defined by a plurality of surfaces. The upper surface of the drain board 100 is the entire surface of the drain board 100 facing upward, and the top surface is a part of the upper surface; the lower surface of the drain board 100 is the entire surface of the drain board 100 facing downward, and the bottom surface is a part of the lower surface.

In the water discharging plate 100 of the embodiment, the water guide part is matched with the water discharging part 110, so that the received water can be discharged, the problem of water discharging in the air duct assembly 200 is solved, and the water guide part is arranged to form an included angle between the extending direction and the air outlet direction of the air duct assembly 200, so that the staying time of air in the air duct assembly 200 can be prolonged, that is, the heat exchange time is prolonged, the heat exchange efficiency is improved, and the refrigeration requirement of refrigeration equipment is met; the drainage board 100 is simple in structure.

The utility model discloses drain bar 100 structure, it is unchangeable for the sunken degree of depth of the top surface of drain bar 100 to be as the water guide, and drain bar 100 is constructed the sunken water drainage 110 of top surface for drain bar 100, this water guide can be called as third water guide 140, as shown in fig. 11 to 13, water drainage 110 is constructed and is exported 114, third water guide 140 and water drainage 110 intercommunication, the change frost water that third water guide 140 accepted can be followed the opening 170 of drain bar 100 tip and discharged, can also discharge from water drainage 110's export 114, realize diversified drainage, simple structure and drainage are effectual.

At this time, the evaporator 230 and the drain plate 100 may be horizontally disposed, thereby accomplishing the discharge of the defrost water and reducing the height of the duct assembly 200. If the evaporator 230 and the drainage plate 100 are both disposed obliquely downward for drainage, the downward inclination angle between the evaporator 230 and the drainage plate 100 (the downward inclination angle between the evaporator 230 and the drainage plate 100 may be less than or equal to 7 °) may be reduced, and the size of the air duct assembly 200 in the height direction may be reduced, thereby expanding the internal capacity of the refrigeration apparatus.

The outlet 114 of the drainage portion 110 and the air outlet are located at the same side of the first cavity 282, and the drainage portion and the air outlet are located at the same side of the first cavity 282, so that the drainage structure and the air outlet structure can be integrated conveniently.

When the fan 270 is disposed in the air duct assembly 200, 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 located on the same side, and the defrosting water of the fan 270 can be discharged along with the defrosting water of the drain plate 100.

The plurality of third water guides 140 are disposed in parallel on both sides of the drain part 110 along the extending direction of the drain part 110, and the plurality of third water guides 140 are distributed under the evaporator 230 so as to receive the defrost water at a plurality of positions under the evaporator 230, which facilitates rapid drainage.

The drainage part 110 may be provided in plurality, and the drainage parts 110 may be parallel or form an included angle. In the case where the area of the drain plate 100 is not changed, the greater the number of the drain parts 110, the shorter the length of the third water conveying part 140, which contributes to the collection of the water received by the third water conveying part 140 in the drain part 110, so as to shorten the defrosting and draining time. When a plurality of the drain parts 110 are provided, the third water conveying part 140 near the edge of the drain plate has an opening, and the other third water conveying parts 140 communicate with the drain part 110.

It will be appreciated that the depth of depression of the drain 110 increases progressively towards the outlet 114, so that water within the drain 110 flows under gravity towards the outlet 114.

It is understood that the bottom of the drain part 110 is inclined in the second direction forming a seventh angle θ 3 with the top surface of the drain plate 100. That is, the bottom of the drainage part 110 is inclined, and the water in the drainage part 110 is collected to the outlet 114 along an inclined path (second direction) and is discharged, so that the drainage effect is good, and the problem of local water accumulation can be avoided; and water can flow smoothly.

When the top surface of the drain board 100 is horizontally disposed, it can be understood that the second direction forms a seventh angle θ 3 with the horizontal plane. Along the top surface of the drain plate 100, a drain portion 110 is formed to be gradually depressed downward toward the position of the outlet 114. At this time, the seventh included angle θ 3 is an included angle between the bottom of the drainage portion 110 and the horizontal plane, and the second direction is a downward direction.

The bottom of the drainage portion 110 may be an inclined plane or an inclined plane, and in some cases, the bottom of the drainage portion 110 is an inclined plane, and the inclined plane may be a plane or a curved surface, which may be specifically selected as needed.

In some cases, the bottom of the drainage portion 110 does not form a continuous slope or slant, such as a step shape, and still meets the drainage requirement.

It can be understood that the seventh included angle θ 3 may be less than or equal to 7 °, and the angle of the seventh included angle θ 3 is small, which is helpful to reduce the distance from the top surface to the bottom surface of the drainage plate 100, so as to realize drainage at a small angle, further reduce the size of the air duct assembly 200 in the height direction, reduce the space occupied by the air duct assembly 200, be helpful to promote the storage space of the refrigeration equipment, and provide the refrigeration equipment with a large capacity.

It should be noted that the seventh included angle θ 3 may also be greater than 7 °, because the area of the drainage plate 100 occupied by the drainage portion 110 is small, the angle of the downward inclination of the drainage portion 110 is slightly large, and the influence on the overall volume of the drainage plate 100 is not large, therefore, the angle of the seventh included angle θ 3 is not strictly limited.

In some cases, as shown in fig. 12, the depth of the recess of the drain portion 110 is constant, and in this case, the drain portion may be referred to as a third drain portion 115, and the drain plate 100 is inclined toward the outlet 114 to facilitate drainage. If the outlet 114 is located at the rear end of the duct assembly 200, the drain plate 100 is inclined obliquely downward from front to rear so that the water in the drain portion 110 flows rearward and is discharged.

As shown in fig. 11 and 12, the third water guide part 140 includes a fourth guide surface 141 provided along an extending direction of the third water guide part 140, and the fourth guide surface 141 approaches an opposite side surface thereof in a direction from the top surface to the bottom surface of the drain board 100. The fourth guide surface 141 guides the defrosted water received by the top surface of the drain panel 100 and the fourth guide surface 141 to the bottom of the third water guide 140 so that the water in the third water guide 140 is discharged.

The fourth guide surface 141 is inclined toward the outlet 114 from the bottom surface toward the top surface of the drain board 100. When the water discharge plate 100 is inclined toward the outlet 114 and the amount of water collected in the third water guide part 140 is large, the fourth guide surface 141 guides the water backward to guide a part of the water to be discharged backward.

The embodiment of the present invention is shown in fig. 20 to 25, and the depth of the water guide recess gradually increases toward the direction of the water discharge portion 110, and at this time, the water guide portion may be referred to as a first water guide portion 120. The first water conduit 120 gradually increases in depth toward the drain 110 so that water flows toward the drain 110 by gravity and is discharged from the outlet 114 of the drain 110.

It can be understood that, toward the direction of the drain part 110, the bottom of the first water guiding part 120 is inclined in the first direction, and the first direction forms a sixth angle θ 2 with the top surface of the drain plate 100. That is, the bottom of the first water guide part 120 is inclined, and the water in the first water guide part 120 is collected to the water discharge part 110 along an inclined path (first direction), so that the water discharge effect is good, and the problem of local water accumulation can be avoided; and water can flow smoothly.

When the top surface of the drain board 100 is horizontally disposed, it can be understood that the first direction forms a sixth angle θ 2 with the horizontal plane. The first water guide 120 is formed to be gradually depressed downward from one end distant from the drain part 110 to a position communicating with the drain part 110 along the top surface of the drain plate 100. At this time, the sixth angle θ 2 is an angle between the bottom of the first water guide 120 and the horizontal plane, and the first direction is a downward direction.

The bottom of the first water guide part 120 may be an inclined line or an inclined plane, and in some cases, the bottom of the first water guide part 120 is an inclined plane, and the inclined plane may be a plane or a curved surface, which may be specifically selected as needed.

In some cases, the bottom of the first water guiding part 120 does not form a continuous oblique line or an inclined plane, such as a step shape, and still can satisfy the water guiding requirement.

It can be understood that sixth included angle θ 2 is less than or equal to 7 °, and the angle of sixth included angle θ 2 is small, which helps to reduce the distance from the top surface to the bottom surface of the drainage plate 100, and can realize small-angle drainage, thereby reducing the size of the air duct assembly 200 in the height direction, reducing the space occupied by the air duct assembly 200, helping to promote the storage space of the refrigeration equipment, and providing the refrigeration equipment with large capacity.

Under some circumstances, sixth contained angle θ 2 sets up to 3 °, and 3 ° can satisfy the drainage demand of drain bar 100, can also fully reduce the height of drain bar 100, realize the small-angle drainage. Of course, the sixth angle may also be 1 °, 2 °, 4 °, 5 °, or 6 °.

In some cases, the first water conveying part 120 is different from the third water conveying part 140 described above in that the first water conveying part 120 is inclined toward the drain part 110 in the drain board 100, the third water conveying part 140 is inclined toward the end of the drain board 100, that is, the inclination direction is different, and other structures and parameters may be set to be the same, for example, the inclination angle may be the same.

It can be understood that, a plurality of water guiding portions are arranged side by side on the same side of the drainage portion 110, and the corresponding bottom surfaces of the drainage plates 100 are coplanar, so that the bottom surfaces of the drainage plates 100 are better in flatness, the appearance of the drainage plates 100 is concise, and positioning and installation are convenient.

Here, the parallel arrangement is understood to mean that a plurality of water guides are arranged in order on one side of the extending direction of the drain 110. In general, a plurality of water guide portions are provided in parallel on both sides of the drain portion 110, that is, the drain portion 110 is provided between two rows of water guide portions. Of course, when the drain part 110 is provided at the end of the drain plate 100, the water guide part is provided only at one side of the drain part 110.

It can be understood that the extending direction of the water guide part is perpendicular to the air outlet direction, so as to effectively prolong the stay time of the air in the first cavity 282, and fully exchange heat.

It can be understood that the extending direction of the water discharging part 110 and the air outlet direction form an eighth included angle, so that the extending direction of the air discharging part 110 is reduced as much as possible, the staying time of the air in the first cavity 282 can be prolonged, and the heat exchange effect is ensured.

Of course, the drainage portion 110 may also extend along the air outlet direction, and the water guide portions may be symmetrically disposed on both sides of the drainage portion 110, so as to facilitate uniform and stable water guide of the water guide portions on both sides of the drainage portion 110.

As shown in fig. 20 and 25, when the water drainage portion 110 extends in the air outlet direction, the water guide portion is perpendicular to the air outlet direction, and the amount of air entering the water guide portion is minimized.

It is understood that, as shown in fig. 24 and 25, the depth of the depression of the water discharge 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 drain part 110 needs to be greater than or equal to the maximum depth of the water guide part so that the water of the water guide part can be collected to the drain part 110 to avoid water accumulation in the water guide part.

As shown in fig. 20, 21 and 24, a plurality of water guides are provided in parallel on both sides of the drain 110, and the water guides guide water from different positions into the drain 110. By providing a plurality of water guides, it can also be understood that both sides of the drainage portion 110 form a wave-shaped structure, which reduces the area of the top surface of the drainage plate 100 as much as possible, and reduces the accumulated water on the top surface of the drainage plate 100, so that the water received by the drainage plate 100 is discharged from the outlet 114 along the water guides and the drainage portion 110 as soon as possible.

It can be understood that, as shown in fig. 22 and 23, at least two drainage portions 110 are provided, and two or more drainage portions 110 have two or more outlets 114, so that drainage at multiple positions is realized, which facilitates rapid drainage of water on the drainage plate 100. If the area of the drain plate 100 is not changed and the number of the drain portions 110 is increased, the length of the water guide portion can be shortened, and water can be rapidly introduced into the drain portions 110.

Adjacent water drainage 110 is first water drainage 111 and second water drainage 112, is equipped with the first water guide area 123 that is located one side of first water drainage 111 and the second water guide area 124 that is located one side of second water drainage 112 between first water drainage 111 and the second water drainage 112, and towards the direction of first water drainage 111, the sunken degree of depth of water guide portion of first water guide area 123 increases gradually, towards the direction of second water drainage 112, the sunken degree of depth of water guide portion of second water guide area 124 increases gradually. That is, at the butt joint position of the first water guiding area 123 and the second water guiding area 124, the depth of the water guiding portion is minimized, which facilitates the water received by the first water guiding area 123 to be guided to the first water discharging portion 111, and the water received by the second water guiding area 124 to be guided to the second water discharging portion 112, which shortens the length of the water guiding portion, and facilitates the water to be collected to the water discharging portion 110.

Of course, as shown in fig. 15, one drain 110 may be provided, and in this case, the outlet 114 of the drain 110 may be kept away from the inlet of the blower 270. Both sides of the drain part 110 are provided with a plurality of parallel water guide parts, which helps to shorten the water guide path of the water guide part to accelerate water discharge.

As shown in fig. 12, 13, 15, 16 and 22 to 23, the drain unit 110 extends from the front to the rear, the outlet 114 is provided at the rear end of the drain board 100, the water guide unit extends in the left-right direction, the left and right sides of the drain unit 110 form a wave-shaped structure, and the arrangement of the wave-shaped plate can facilitate the water gathering and draining, and the evaporator 230 does not need to be arranged obliquely downward in the front-rear direction.

The water guide part forms an included angle of less than 7 degrees with the top surface of the water discharge plate 100, that is, the water guide part extending obliquely is formed in the left and right direction of the water discharge plate 100, and the inclination angle of the water guide part does not affect the angle of the front and rear direction of the water discharge plate 100. The water drainage part 110 extends from the front to the back, and the water drainage part 110 forms seventh contained angle theta 3 with the horizontal plane backward in the past, and the seventh contained angle theta 3 can influence the altitude variation of direction before and after the drain bar 100, but wholly sees, and the water drainage part 110 sets up the local position at the drain bar 100, and the shared drain bar 100 of water drainage part 110 area is less, and the local position inclination of drain bar 100 is slightly bigger, and is less to indoor whole storing space's influence in room, also can optimize the indoor volume in room.

In the above, the water guide may be at least one of the first water guide 120 and the third water guide 140, that is, the drain board 100 may have the drain 110 and at least one of the first water guide 120 and the third water guide 140, and the structure of the drain board 100 may be various.

It can be understood that, referring to fig. 24 and 25, the first water guide part 120 includes a first flow guide surface 121 disposed along an extending direction of the first water guide part 120, and the first flow guide surface 121 approaches to an opposite side surface thereof in a direction from a top surface to a bottom surface of the drain board 100, that is, a longitudinal section of the first water guide part 120 is tapered from top to bottom, so that water falling on the first flow guide surface 121 and the top surface may be collected to a bottom of the first water guide part 120 and then collected to the drain part 110 along the first water guide part 120.

At least one of both side surfaces of the first water guide part 120 in the extending direction thereof is provided as a first guide surface 121. The shape of the longitudinal section of the first water guide 120 may be an inverted triangle or an inverted trapezoid. Referring to fig. 24 and 25, both side surfaces of the first water guide part 120 in the extending direction are first flow guide surfaces 121, and both sides of the first water guide part 120 may guide flow.

It is understood that, referring to fig. 24 and 25, the drain part 110 includes the second guide surface 113 disposed along the extending direction of the drain part 110, and the second guide surface 113 is adjacent to the opposite side surface thereof in the direction from the top surface to the bottom surface of the drain plate 100, so that the longitudinal section of the drain part 110 is closed from the top to the bottom, and the water falling on the second guide surface 113 and the top surface can be collected to the bottom of the drain part 110 and then discharged from the outlet 114.

At least one of both side surfaces of the drain part 110 in an extending direction thereof is provided as the second guide surface 113. The longitudinal section of the drain part 110 may have an inverted triangle or an inverted trapezoid shape. Referring to fig. 25, both side surfaces of the extending direction of the drain part 110 are the second flow guiding surfaces 113, and both sides of the drain part 110 may guide the flow.

As shown in fig. 24 and 25, the first water guide part 120 is provided with the first guide surface 121, and the drain part 110 is provided with the second guide surface 113 to guide the water sufficiently so that the water received by the drain board 100 is discharged from the outlet 114 as soon as possible.

In the above embodiments, the first guiding surface 121 and the second guiding surface 113 may be a plane or a curved surface, and may be specifically selected according to the requirement.

It can be understood that the first predetermined section of the water guide extending direction is gradually reduced in width of the water guide toward the drain 110. It can also be understood that the water guide portion is gradually folded toward the drain portion 110, so that the water in the water guide portion is gathered to help the water in the water guide portion to enter the drain portion 110.

The first predetermined cross section herein may be understood as a cross section parallel to the top surface of the drain board 100, and a horizontal cross section of the drain board 100 in an installed state. The width of the water guide portion may be understood as a distance between two sidewalls in an extending direction of the water guide portion, and the first water guide portion 120 may be understood as a distance between two first guide surfaces 121. The gradual reduction is typically a continuous reduction, but does not preclude a step reduction.

It can be understood that the second predetermined cross-section of the extending direction of the drain 110 increases the width of the drain 110 toward the outlet 114. The defrosted water received by the plurality of water guide parts is gathered to the drain part 110, the water amount is the largest at the position of the outlet 114 of the drain part 110, the width of the drain part 110 is increased, a larger drain space is provided, and the stable drainage of the water is facilitated.

The second predetermined cross section herein may be understood as a cross section parallel to the top surface of the drain board 100, and a horizontal cross section of the drain board 100 in an installed state. The width of the drain part 110 may be understood as a distance between two sidewalls in an extending direction of the drain part 110, that is, a distance between two second flow guide surfaces 113. The increase is generally a gradual increase, but does not exclude a step increase.

The first predetermined cross-section is parallel to the second predetermined cross-section, or coplanar therewith.

It will be appreciated that the edges of the drain panel 100 are folded upwardly to form a flange 150, as shown in fig. 22, and the flange 150 surrounds the drain panel 100 and is slotted at a location corresponding to the outlet 114. The flange 150 functions to prevent water on the upper surface of the drain plate 100 from overflowing outwards, so that water on the upper surface of the drain plate 100 is discharged along the outlet 114, and water in the air duct assembly 200 is discharged from the water outlet.

The positioning parts 151 are formed by extending the partial positions of the flanges 150 upwards, two adjacent positioning parts 151 are used for limiting the first heater 231 above the drainage plate 100, the fixing mode of the heater is simple, and the structure of the drainage plate 100 is simple.

When the end of the water guide portion is formed with an opening, it is not necessary to provide a flange.

In the above embodiment, the shape of the drain plate 100 is related to the shape of the evaporator 230 and the air duct assembly 200, and the shape of the drain plate 100 is not limited. The outline shape of the drain board 100 may be a rectangle, a trapezoidal circle, or other shapes. The upper and lower surfaces of the drain board 100 have the same shape.

The drain board 100 in the above embodiment is applied to the air duct assembly 200, that is, the drain board 100 is disposed below the evaporator 230, and from the front to the back direction, the evaporator 230 does not need to be inclined downward, so that the problem that the indoor volume of the evaporator 230 is lost due to the fact that the evaporator 230 has an inclined angle is solved, under the condition that the heat exchange efficiency in the air duct assembly 200 is ensured, the small-angle defrosting and draining is realized, the height direction fall of the air duct assembly 200 is reduced, and the indoor volume maximization is facilitated.

Of course, in actual use, the evaporator 230 may be slightly inclined downward, but even if the evaporator 230 is not inclined downward, the drainage effect is not affected.

The drain board 100 is further connected with a vibrator (not shown in the figure) for providing a vibration force according to the defrosting requirement. The on-off of the vibrator is closely related to the defrosting time, and the vibrator can be synchronously unfolded with the defrosting work and can be properly delayed compared with the defrosting work.

The vibrator may be any one of an eccentric motor, an ultrasonic vibrator, or an electromagnetic vibrator.

A drainage structure for communicating the drainage plate 100 with the drainage pipe will be described below based on the drainage plate 100.

As shown in fig. 2 to 13, the air duct assembly 200 further includes a first water discharging part 260, the first water discharging part 260 is communicated with the opening 170 of the water discharging plate 100 in the first cavity 282, the first water discharging part 260 and the fan 270 are located at two adjacent sides of the water discharging plate 100, and the first water discharging part 260 may be understood as a side water discharging structure.

The first drain part 260 is provided with a first drain port 262, and the first drain port 262 communicates with a drain line (the drain line is a first drain pipe 263) to discharge water received by the drain plate 100.

The first drainage part 260 is configured with a drainage channel whose cross-sectional area is gradually reduced from top to bottom, which can ensure that drainage at the position of the opening 170 is fully received, and can also converge drainage to the first drainage port 262.

As shown in fig. 6 and 7, the first drainage member 260 covers all the openings 170 of the drainage plate 100 as much as possible, so that the connection portions between the first drainage member 260, the air duct member 220, and the partition member 210 are sealed, thereby preventing air leakage and water leakage. As shown in fig. 5 and 7, a part of the openings 170 does not correspond to the first drainage member 260, in order to show the positions of the openings 170, and in actual use, the first drainage member 260 covers all the openings 170.

The first drain part 260 is constructed with a through hole communicating with the openings 170, and the area of the through hole covers all the openings 170 to ensure a drainage effect and a sealing effect, preventing water leakage from occurring.

It is understood that the first drain part 260 is provided with at least one air inlet, that is, the first drain part 260 is provided with at least one of the first air inlet 201 and the second air inlet 202. As shown in fig. 6 and 9, the first air inlet 201 is provided in the first drainage part 260, and the first air inlet 201 passes through the inside of the first drainage part 260 and communicates with the first cavity 282, thereby returning air to the first compartment 410. The first air inlet 201 is communicated with the first compartment 410 through the air return component 430 for air return.

As shown in fig. 13, the first drain part 260 includes a first wall plate 264 and a second wall plate 265 which are oppositely disposed, the first wall plate 264 is configured with a through hole, and the second wall plate 265 is configured with the first intake vent 201. The first wall 264 faces the drain board 100 and the second wall 265 faces the cabinet 400. The first wall plate 264 and the second wall plate 265 can be detachably connected or integrally formed. In some cases, first drain member 260 is constructed as an integrally formed structure to prevent leakage at the joint.

It should be noted that, under the condition that the first air inlet 201 is not disposed in the first water discharging component 260, the partition component 210 is installed above the air duct component 220, and the first air inlet is disposed in the partition component 210, so that the air returning component 430 of the first compartment 410 enters the first cavity 282 through the first air inlet 201.

As shown in fig. 2 to 13, the opening 170 of the drain plate 100 faces a first side of the first cavity 282, the second cavity 281 is located at a second side of the first cavity 282, the fan 270 is disposed in the second cavity 281, and the first side and the second side of the first cavity 282 are adjacent to each other. The first side of the first cavity 282 may be understood as at least one of the left and right sides, and the second side of the second cavity 281 may be understood as the rear side. The water outlet direction of the water discharging plate 100 is different from the air outlet direction of the first cavity 282, so that water vapor carried in air can be reduced, the influence of water discharging on the fan 270 is reduced, and the frost formation amount of the fan 270 is reduced. At this time, the opening 170 of the drain plate 100 faces at least one of the left and right sides.

As shown in fig. 5 to 8, the drain board 100 includes the second water guide portion 130, the second water guide portion 130 is recessed relative to the top surface of the drain board 100, an extending direction of the second water guide portion 130 forms an included angle with an air outlet direction above the drain board 100, a depth of the recess of the second water guide portion 130 is gradually increased along a direction facing the first side of the second cavity 281 in advance, the second water guide portion 130 forms an opening 170 towards an end of the first side of the second cavity 281, water received by the second water guide portion 130 is discharged from the opening 170 along the extending direction of the water guide portion, the opening 170 is communicated with the first water discharge component 260, so that the water is discharged through the first water discharge port 262. The drain board 100 has a simple structure and a good drainage effect. The return air in the first compartment 410 enters the first cavity 282 through the first air inlet 201, and the air enters the first cavity 282 from the left side or the right side and can flow along the second water guide part 130; the return air in the second compartment 420 enters the first cavity 282 through the second air inlet 202, and the air enters the first cavity 282 from the front side of the air duct assembly 200, so that the return air in the first compartment 410 and the return air in the second compartment 420 have different paths to enter the first cavity 282, contact of the two return air paths is reduced, and frost formation caused by contact of the two return air paths is also reduced.

At this moment, the air-out direction of drain bar 100 top is from the front to the back, and the extending direction of second water guide portion 130 is left right direction, and then the extending direction of second water guide portion 130 and the contained angle of the air-out direction of drain bar 100 top are 90, and second water guide portion 130 can play the effect that slows down the velocity of flow of wind in first cavity 282, can prolong the time that wind stayed in first cavity 282, optimizes the heat transfer effect.

It should be noted that the drain plate 100 includes the second water guide portion 130 extending from the preset position to the left side and the second water guide portion 130 extending from the preset position to the right side, the drain plate 100 has the opening 170 facing the left and right sides, and the left and right sides of the air duct assembly 200 are both provided with the first drain parts 260, so that the structure is simple and the water guide effect is good. Here, the predetermined position may be a symmetrical plane of the drain board 100, or a longitudinal plane extending in the front-rear direction. The preset surface may be the end surface of the drain portion, and the preset surfaces of the second water guide portion extending to the left and right sides of the drain plate may be the same longitudinal surface or different longitudinal surfaces.

Unlike the above-described embodiment, as shown in conjunction with fig. 10 to 13, the drain plate 100 provided in the duct assembly 200 is configured with the third water guide 140, and the opening 170 of the third water guide 140 communicates with the first drain part 260.

When the fan 270 is disposed at the rear side of the air duct assembly 200, and the first drain 260 is disposed at least one of the left and right sides of the air duct assembly 200, the above-mentioned drainage may be understood as side drainage. Because the fan 270 is disposed behind the air duct assembly 200, at this time, the evaporator 230 and the fan 270 independently drain water, the defrosting water of the evaporator 230 is discharged from the left and right sides through the first water discharging part 260, the defrosting water flowing toward the fan direction and the water condensed when encountering the fan 270 can be discharged through a structure below the fan 270, and the structure below the fan 270 may be a rear water discharging structure as described below, or another structure capable of discharging water in the second cavity 281.

Unlike the drainage pattern of the first drainage member 260 described above, referring to fig. 10-16, the air duct assembly 200 further includes a fan guard 240, the fan guard 240 defines a second cavity 281, the fan 270 is disposed within the second cavity 281 of the fan guard 240, the fan guard 240 is configured with ventilation openings 244, and the second cavity 281 is in communication with the first cavity 282 through the ventilation openings 244.

In some cases, both the fan guard 240 and the fan 270 are disposed on the rear side of the duct assembly 200, and a second drain 290 is located on the side of the fan, the second drain 290 providing a means for rear drainage.

The fan guard 240 is provided with a second water drain member 290. the second water drain member 290 is provided inside the fan guard 240, or the second water drain member 290 is provided below the outside of the fan guard 240.

Referring to fig. 14 to 16, when the second drain member 290 is installed in the fan guard 240, the space in the fan guard 240 is fully utilized, the height of the duct assembly 200 can be reduced, and the capacity of the refrigerating apparatus can be increased.

A fan guard 240 is provided on the side of the drain board 100 where the outlet 114 is located, and one end of the fan guard 240 facing the drain board 100 communicates with the outlet 114 of the drain board 100. The fan guard 240 includes a first guard 241 and a second guard 242 located below the first guard 241, and the fan 270 is disposed above the second guard 242. The second cover 242 is provided with a third water outlet 2423, and water discharged from the outlet 114 of the water discharging plate 100 is guided to the third water outlet 2423 along the second cover 242. The second cover 242 can receive water drained by the drain board 100, water dripped by the first cover 241, and water dripped by the fan 270, and drain defrosting water of the first cavity 282, which helps to simplify the structure of the air duct assembly 200. At this time, the drain board 100 may have a structure having the drain part 110, and in particular, refer to the above-described embodiment of the drain board 100. The outlet 114 of the drain 100 is directed rearwardly and the second hood 242 is located rearwardly of the drain 100. the provision of the second hood 242 provides a rear drain structure.

The second water discharge member 290 configures a first water guide passage 2421 communicating with the outlet 114 of the water discharge panel 100, the second water discharge member 290 includes a barrier 2422 protruded upward along the surface of the second cover 242, the barrier 2422 defines the first water guide passage 2421, and the fan 270 is located at one side of the barrier 2422. The barrier 2422 functions to separate the first water guide path 2421 from the fan 270, to prevent water from flowing to the fan 270, and to reduce the influence of water on the fan 270.

The first water guide path 2421 is inclined downward in a direction away from the outlet 114 of the drain board 100, so that water in the first water guide path 2421 is guided downward, and the structure is simple and the drainage effect is good. A third water outlet 2423 is formed at the end of the first water channel 2421, and the third water outlet 2423 is connected with a water discharge pipe through which water is discharged into the press cabin.

The blocking part 2422 may be a plate-shaped structure or a block-shaped structure protruding upwards from the second cover 242, and may be selected according to the requirement. Of course, the blocking part 2422 may also be a part detachably connected to the second cover 242, such as a plate structure inserted into or clamped in the second cover 242, the structure of the blocking part 2422 is not limited thereto, and other structures capable of implementing the blocking function may also be used.

It should be noted that a partition 2427 is disposed between the drain 100 and the second cover 242, the partition 2427 enables the drain 100 and the second cover 242 to communicate only at the outlet 114, and other parts are partitioned by the partition 2427 to ensure that the first cavity 282 and the second cavity 281 communicate at the ventilation opening 244 and the outlet 114, and other parts are partitioned. The divider 2427 may be integrally formed with the second cover 242 or may be detachably connected thereto.

The second cover 242 and the drain board 100 may be separate two parts, or the second cover 242 and the drain board 100 may be integrally formed as a single part.

The first air guiding part 2424 and the second air guiding part 2425 are arranged inside the fan cover 240, and the first air guiding part 2424, the second air guiding part 2425 and the fan 270 are matched to guide air to the first air outlet 203 and the second air outlet 204, so that air is ensured to flow out from corresponding paths. As shown in fig. 15, the second cover 242 is provided with a first air guide part 2424 and a second air guide part 2425.

The fan 270 is mounted on the upper surface of the second cover 242 through the fan mounting seat 271, the plurality of second mounting columns 2426 are arranged on the upper surface of the second cover 242, the fan mounting seat 271 is fixed on the second mounting columns 2426, the inclination angle and direction of the fan 270 can be adjusted by adjusting the heights of the second mounting columns 2426 at different positions, and the structure is simple.

The upper surface of the second cover 242 is inclined obliquely downward in a direction away from the drain board 100, that is, in a direction toward the third drain port 2423, so that the defrosted water on the surface of the second cover 242 can flow toward the third drain port 2423 by gravity.

The second cover 242 is configured with a water collecting part 2428, the water collecting part 2428 is located on one side of the second cover 242 facing the third water outlet 2423, the surface area of the water collecting part 2428 gradually decreases towards the third water outlet 2423 and is communicated with the third water outlet 2423, and water collected by the water collecting part 2428 can be discharged through the third water outlet 2423. The surface area of the water collecting part 2428 towards the third water outlet 2423 is gradually reduced, that is, the water collecting part 2428 is folded towards the third water outlet 2423, so that the defrosting water received by the second cover 242 is discharged after being collected.

Water collecting part 2428 may be inclined downward based on the downward inclination of the upper surface of second cover 242 toward third drain port 2423, which is more effective in draining water, but water collecting part 2428 is not limited to inclined downward, and the arrangement of water collecting part horizontally is not excluded.

The second cover 242 is provided with a heating member 226, and the heating member 226 heats the second cover 242 to defrost the fan guard 240 and the fan 270 therein. The heating member 226 may be a heating film formed on the second cover 242, or the heating member 226 may be a heating plate located below the second cover 242, and the structure of the heating member 226 is not limited thereto, and other structures capable of heating and defrosting may be used.

Unlike the second water discharge member 290 described above, referring to fig. 10 and 11, the second water discharge member 290 may be positioned under the fan guard 240, and the second water discharge member 290 is sealed with the outer surface of the fan guard 240 to form a second water guide passage communicating with the outlet 114 of the water discharge plate 100. The second water guide channel and the second cavity 281 are separated from each other, that is, the second water guide channel and the fan 270 are separated from each other through the fan guard 240, so that the influence of water in the second water guide channel on the fan 270 and other components is reduced.

The second water discharge member 290 may be shaped to have a U-shaped structure with a burring, or the second water discharge member 290 may be integrally formed under the second cover 242, and the structure of the second water discharge member 290 may be varied and selected as needed. When the drain board 100 is provided with a plurality of outlets 114, a plurality of second drain parts 290 may be provided under the fan guard 240, and the second water guide path does not interfere with the fan 270. Under the air duct assembly 200, the local position corresponding to the second drainage component 290 protrudes downwards, so that the height of the local position of the air duct assembly 200 is large, the heights of other positions are not affected, and the effect of expanding the capacity of the refrigeration equipment can be achieved.

The second water guide channel is inclined downwards in a direction away from the outlet 114 of the drain board 100, so that water in the second water guide channel is guided downwards, and the structure is simple and the drainage effect is good. The second drain member 290 is provided with a second drain port connected to a second drain pipe 291, and discharges water into the press compartment through the second drain pipe 291.

Certainly, the water guide channel (the first water guide channel 2421 or the second water guide channel) can also be horizontally arranged, so that the size of the air duct assembly 200 in the height direction cannot be increased due to the water guide channel, the height of the air duct assembly 200 is favorably reduced, and the storage space of the refrigeration equipment is further increased.

The fan guard 240 is provided with a wire routing hole (not shown in the figure) so that the electrical connection component of the air duct assembly 200 can be routed through the wire routing hole to realize electrical connection, and the fan guard is simple in structure and convenient to route.

When the fan 270 is installed in a manner different from that described above, that is, when the fan guard 240 is not provided, the drainage manner is different from that of the first and second drainage members 260 and 290 described above. The air duct member 220 supports the drain board 100, the drain board 100 is located below the evaporator 230, a water guide 223 is disposed at a side of the outlet 114 of the drain board 100, one side of the water guide 223 faces the outlet 114 and communicates with the outlet 114, a drain opening is configured at the other side of the water guide 223, so that the water guide 223 communicates with the third drain pipe 2231, and water discharged from the outlet 114 of the drain board 100 is guided to the third drain pipe 2231 along the water guide 223.

The fan 270 is disposed at one side of the evaporator 230, the fan cover 243 is disposed between the fan 270 and the evaporator 230, and an inlet of the fan 270 is communicated with the first cavity 282 through the ventilation opening 244 of the fan cover 243. The fan cover plate 243 is arranged on the outer side of the water guide member 223, the fan cover plate 243 is fixed on the box liner body, a cavity for installing the fan 270 is defined between the fan cover plate 243 and the box liner body, and the cavity is communicated with the first cavity 282 through a ventilation opening 244 formed in the fan cover plate 243. Or, a cavity for installing the fan 270 is enclosed by the fan cover plate 243, the cavity is communicated with the first cavity 282, and the fan cover plate 243 is fixedly installed on the box liner body. A third cavity is defined between the fan cover 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 guide 223 may be understood as a part of the air channel component 220, or may be independent of the part of the air channel component 220, and may be selected according to the requirement. The fan cover 243 is a mounting component of the fan 270, the main function of the fan cover 243 is similar to that of the fan guard 240, the fan cover 243 or the fan guard 240 is arranged in one air duct assembly 200, the fan cover 243 is used in combination with the water guide 223, and the fan guard 240 is used in combination with the second water discharge component 290. When the duct assembly 200 includes the fan guard 240, the fan guard 240 is provided with a vent 244, so that the air in the first cavity 282 is exhausted by the fan 270 through the vent 244.

The fan cover 243 is provided with third and fourth wind guide portions 2431 and 2432 so that the fan 270 sends the wind out of the first and second wind discharge ports 203 and 204.

Next, the fan 270 and the manner of mounting the fan 270 will be described.

As shown in fig. 5-16, the air duct assembly 200 further includes a fan guard 240, the fan guard 240 includes a first cover 241 and a second cover 242, the first cover 241 is configured with a flow guide surface 2411 facing the fan 270, a first side of the flow guide surface 2411 is higher than a second side of the flow guide surface 2411, and the first side of the flow guide surface 2411 is opposite to the second side of the flow guide surface 2411; the fan guard 240 defines a second cavity 281, and a fan 270 is disposed in the second cavity 281. The first cover body 241 can collect water vapor above the fan 270, and drains collected water drops from the first side of the flow guide surface 2411 to the second side of the flow guide surface 2411, and the arrangement of the first cover body 241 can promote the collection and the discharge of the water vapor in the second cavity 281, reduce the corrosion of the water vapor on the fan 270, and prolong the service life of the fan 270.

The air duct assembly 200 further comprises a fan 270, a first included angle α 1 is formed between a rotation axis of the fan 270 and the vertical direction, a ventilation opening 244 is formed in the fan cover 240, an inlet of the fan 270 faces the ventilation opening 244, the second cavity 281 is communicated with an air outlet area of the first cavity 282 through the ventilation opening 244, and the second cavity 281 is communicated with an air outlet of the air duct assembly 200. The wind in the first cavity 282 is drawn into the second cavity 281 by the fan 270 through the ventilation opening 244 on the fan guard 240, and under the action of the fan 270, the wind in the second cavity 281 passes through the exhaust opening and enters the first compartment 410 or the second compartment 420. That is, the second chamber 281 is on-off adjustable with the first and second exhaust ports 203 and 204.

The rotation axis of the fan 270 forms a first included angle α 1 with the vertical direction, and it can be understood that the front end of the rotation axis of the fan 270 is lower or higher than the rear end. Under the condition that satisfies ventilation and drainage demand, the angle of first contained angle alpha 1 is as little as possible, and the difference in height of the front end of the axis of rotation of fan 270 and rear end is as big as possible, namely fan 270 is close to the level setting as far as possible to reduce the shared space of fan 270 in the direction of height, and then reduce the size of wind channel subassembly 200 in the direction of height.

At this time, the vent 244 and the drainage outlet of the first cavity 282 are arranged in a staggered manner, so that the air at the drainage outlet can be reduced as much as possible to be drawn out by the fan 270, the heat exchange time of the air in the first cavity 282 is prolonged, and the heat exchange efficiency is improved.

The fan cover 240 is fixed to the tank body, and the air in the first cavity 282 is guided out by the fan 270 through the second cavity 281.

The first included angle α 1 is greater than or equal to 7 °, so that water collected on the first side of the flow guide surface 2411 can flow to the second side along the slope of the surface of the first side, and the water is guided to the third drain 2423 along the air duct component 220 below the fan 270, so that the water collected on the surface of the first cover 241 is prevented from dripping into the fan 270, and the water is prevented 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 may be an inclined plane or a curved surface; when the flow guide surface 2411 is a plane, the structure of the first cover 241 is simplified, and the processing is facilitated. In addition, water accumulated on the surface of the fan 270 falls and is discharged by gravity.

The first included angle alpha 1 needs to be smaller than 70 degrees so as to achieve the purpose of reducing the height; the first included angle α 1 may be less than 60 °, 50 °, 45 °, 30 °, 20 °, or 10 °, the smaller the first included angle α 1, the smaller the height direction dimension of the air duct assembly 200.

It should be noted that, when the first included angle α 1 is smaller than 7 °, the air exhaust requirement can be met, and the size of the air duct assembly 200 in the height direction is smaller, but the water guiding effect of the first cover body 241 facing the surface of the fan 270 is not good, and the water drainage effect is difficult to meet the requirement. If the first included angle α 1 is less than 7 °, the problem of the fan guard 240 draining water needs to be solved.

In some cases, the first cavity 282 and the second cavity 281 are two cavities arranged in parallel; alternatively, the second cavity 281 is surrounded by the first cavity 282; the positional relationship between the first cavity 282 and the second cavity 281 is not limited thereto, and the two cavities may be connected to each other. Taking the second cavity 281 located at the rear of the first cavity 282 as an example, the fan 270 may be inclined toward the front by the first included angle α 1 or inclined toward the rear by the first included angle α 1, as shown in fig. 14, the fan 270 is inclined toward the front by the first included angle α 1, and as shown in fig. 8, the fan 270 is inclined toward the rear by the first included angle α 1. That is, the upper end of the rotational axis of the fan 270 is inclined forward with respect to the vertical direction at a first angle α 1, or inclined backward at a first angle α 1.

Wherein, fan 270 is upwards inclined from the front to the back gradually, that is to say the inlet of fan 270 is towards the air-out direction of first cavity 282, helps the wind in first cavity 282 to get into the inlet of fan 270, can improve ventilation effect. The fan 270 is inclined downward from the front to the rear gradually, so that the space utilization rate can be improved. In the above structure, the evaporator 230 and the fan 270 may share a drainage structure, so as to simplify the structure; alternatively, considering that the evaporator 230 and the fan 270 adopt independent drainage structures for drainage, the influence of drainage on the fan 270 may be reduced. As shown in fig. 5, 6, 12, and 13, the drain water of the evaporator 230 is guided out from the first drain parts 260 on the left and right sides, and the drain water of the fan 270 is discharged from the rear end.

It will be appreciated that the axis of rotation of the fan 270 is collinear with the central axis of the vent 244, and that the fan 270 provides a good suction effect during the process of drawing the wind in the first cavity 282 into the second cavity 281 through the vent 244, which contributes to the effect of the wind circulation in the wind tunnel assembly 200. In some cases, the shape of the vent 244 is adapted to the shape of the inlet of the fan 270, such that 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 vent opening 244 and the flow guide surface 2411 of the first housing 241 is generally disposed parallel to the fan 270 or the area of the first housing 241 corresponding to the fan 270 is disposed parallel to the fan 270. The fan 270 is typically a centrifugal fan, which changes the direction of the wind to facilitate the wind to be sent to the first compartment 410 or the second compartment 420. Of course, other fans 270 that can satisfy the effect of circulating air supply may be used.

It can be understood that, as shown in fig. 4 to fig. 6, the first cover 241 is located above the fan 270, the first side of the flow guiding surface 2411 faces the water draining plate 100, the second side of the flow guiding surface 2411 faces the water draining plate 100, the first side of the flow guiding surface 2411 is inclined upward by a second included angle α 2 relative to the second side of the flow guiding surface 2411, that is, in a direction away from the water draining plate 100, the flow guiding surface 2411 of the first cover 241 is inclined upward by the second included angle α 2, that is, the air outlet direction of the air vent 244 facing the first cavity 282 helps the air in the first cavity 282 to enter the second cavity 281, so that the air venting effect can be improved, and a water draining structure shared by the evaporator 230 and the fan 270 can be considered, so as to simplify the structure. As shown in fig. 14-16 and 21, the air duct assembly 200 drains from the second or third drain 2423 at the rear end.

As shown in fig. 12 to 25, when the drain plate 100 includes the water guide portion and the drain portion 110, the drain portion 110 has the outlet 114, and the water received in the drain plate 100 flows along the water guide portion to the drain portion 110 and is discharged from the outlet 114, and due to this structure, a part of the wind also flows along the water guide portion and the drain portion 110 to the outlet 114, and the outlet 114 and the vent 244 are arranged to be misaligned, so that the wind flowing in the direction of the outlet 114 is prevented from being directly discharged from the vent 244, the time for the wind to exchange heat in the first cavity 282 is prolonged as much as possible, and the heat exchange efficiency is improved. When the second cavity 281 is located behind the first cavity 282, the direction away from the drain board 100 is from the front to the back. Of course, the first cavity 282 and the second cavity 281 may be disposed left and right, and the direction away from the drain board 100 is left and right, and the working principle is consistent with the front and back direction, which is not described herein again. As shown in fig. 1 to 3, 10, 11, and 17 to 19, the second cavity 281 is located behind the first cavity 282 for example.

Referring to fig. 1 to 3, 10, 11, and 17 to 19, the first cover 241 is located above the fan 270, a first side of the flow guide surface 2411 faces the water discharge plate 100, a second side of the flow guide surface 2411 faces away from the water discharge plate 100, and the second side of the flow guide surface 2411 is inclined downward by a third included angle α with respect to the first side of the flow guide surface 2411 ₃ I.e. in a direction away from the drainage plate 100, the flow guiding surface 2411 of the first cover 241 is inclined downwards by a third angle α ₃ The first cover 241 guides the flow of water to the rear of the fan 270, thereby helping the collected water to be quickly discharged.

In some cases, second included angle α ₂ And a third angle alpha ₃ Is arranged at an angle alpha to the first ₁ Are angled such that the axis of rotation of the fan 270 is collinear with the central axis of the vent 244, thereby ensuring the flow of air within the duct assembly 200 and the cooling deviceAnd (5) circulation effect.

The drain plate 100, the fan guard 240, the water guide 223, and other components in the above embodiments are all required to be supported and insulated by the air duct member 220, and the structure of the air duct assembly 200 will be described below.

The air duct member 220 may be fixed to the tank body by being fixedly coupled to the partition member 210, or the air duct member 220 may be directly fixedly coupled to the tank body.

Air duct component 220 includes the backup pad and locates the second heat preservation 221 of drain bar 100 below, and the backup pad supports in second heat preservation 221 below, the shape of second heat preservation 221 upper surface and the shape looks adaptation of drain bar 100 lower surface for second heat preservation 221 fully keeps warm for drain bar 100, reduces cold volume outdiffusion, guarantees heat exchange efficiency.

When the lower surface of the drain board 100 is a curved surface, such as a wave shape, the upper surface of the second insulating layer 221 is a corresponding curved surface; when the lower surface of the drainage plate 100 is a plane, the upper surface of the second insulating layer 221 is a plane, and may be specifically disposed as required.

The supporting plate comprises a first supporting portion 222 and a second supporting portion 225 inclined downwards along the first supporting portion 222, the second supporting portion 225 and the outlet 114 of the drain plate 100 are located on the same side of the air duct assembly 200, the first supporting portion 222 supports a second insulating layer 221, a third insulating layer 224 is arranged above the second supporting portion 225, a water guide member 223 or a fan cover 240 is arranged above the third insulating layer 224, and the second supporting portion 225 plays a role of supporting the third insulating layer 224 and components (such as the water guide member 223 or the fan cover 240) above the third insulating layer 224.

The first supporting portion 222 and the second supporting portion 225 are independent parts, such as plates, and are mounted in a detachable connection manner, such as an insertion manner, a clamping manner, a fastening manner and the like; alternatively, the first supporting portion 222 and the second supporting portion 225 are integrally formed, so that the number of parts can be reduced, and the assembly can be simplified. In some cases, the water guide 223 and the drain board 100 are two separate pieces, and of course, the water guide 223 and the drain board 100 may be formed as an integral structure.

The air duct member 220 may be provided with an air inlet, so that the return air of at least one of the first compartment 410 and the second compartment 420 enters the first cavity 282 through the air inlet of the air duct member 220. If the supporting plate is provided with an air inlet; as shown in fig. 13, the front end of the first supporting portion 222 is provided with a second air inlet 202 communicated with the second compartment 420, so that the second compartment 420 returns air into the first cavity 282 through the second air inlet 202 at the front end of the air duct assembly 200.

Referring to fig. 36 to 38, a first air inlet 201 is disposed on a first side of the first cavity 282, and a second air inlet 202 is disposed on a second side of the first cavity 282, it can also be understood that a cross section of the first air inlet 201 forms an included angle with a cross section of the second air inlet 202 perpendicular to the respective air inlet direction. The inlet air of the first inlet 201 and the inlet air of the second inlet 202 have different temperatures.

The air duct component 220 is provided with a partition portion 2221, an orthographic projection of the partition portion 2221 at the first air inlet 201 covers a local area of the first air inlet 201, the orthographic projection of the partition portion 2221 at the first air inlet 201 is located at one end, close to the second side, of the first air inlet 201, a preset distance a is arranged between the partition portion 2221 and the first air inlet 201 at intervals, the air inlet of the first air inlet 201 flows towards the partition portion 2221, in the air flowing process, a part of air is guided along the extending direction of the partition portion 2221, a part of air continuously flows along the air inlet direction, and when the first air inlet 201 and the second air inlet 202 simultaneously supply air, the air volume of cross contact between the air inlet of the first air inlet 201 and the air inlet of the second air inlet 202 can be reduced.

In the first cavity 282, a gap is left between one end of the evaporator 230 facing the second side and the second air inlet 202, and most of the inlet air of the first air inlet 201 and the second air inlet 202 meet at the gap and contact for heat exchange, and then flows along the evaporator 230 to the air outlet; at the position of the distance, the partition portion 2221 plays a role of guiding a part of the intake air of the first intake port 201 to the extending direction of the partition portion 2221, so that the amount of air for contact heat exchange between the intake air of the first intake port 201 and the intake air of the second intake port 202 can be reduced, the frosting amount at the end of the evaporator 230 close to the second side due to different intake air temperatures can be further reduced, the influence on the intake air amount of the first cavity 282 due to the large frosting amount at the second side can be avoided, the problem of short defrosting period due to the large frosting amount at the second side can be solved, the defrosting period can be properly prolonged, and the power saving effect can be achieved. The partition portion 2221 is provided such that the intake air of the first intake vent 201 and the intake air of the second intake vent 202 are maintained at both sides of the partition portion 2221 as much as possible.

Referring to fig. 36, taking the first intake vent 201 aligned with the edge of the air duct member 220 as an example, the predetermined distance a is the distance from the first side edge of the air duct member 220 to the partition 2221. It should be noted that, the preset distance a is set, in order to ensure that a proper flow space is provided between the first air inlet 201 and the separating portion 2221, so that the air flows into the first cavity 282, and the separating portion 2221 is prevented from blocking the corresponding portion of the first air inlet 201, therefore, the value of the preset distance a is not limited, and can be selected as needed. The orthographic projection may be understood as a projection at the first air inlet 201 along the air inlet direction of the first air inlet 201.

It should be noted that the air duct component 220 may be formed with a first air inlet 201 (not shown).

The evaporator 230 is disposed in the first chamber 282, and the heat dissipation fins 234 of the evaporator 230 extend in a direction from the second inlet 202 toward the outlet (from front to rear in the drawing), so that the wind at the interval between the evaporator 230 and the second inlet 202 can flow toward the outlet in a direction of the heat dissipation fins 234.

The separating portion 2221 extends along the second inlet 202 toward the outlet, a part of the inlet air from the first inlet 201 flows toward the evaporator 230 along the separating portion 2221, and the separating portion 2221 and the heat sink 234 extend in the same direction, so that the separating portion 2221 and the heat sink 234 cooperate to guide the air toward the outlet.

In the direction from the first air inlet 201 to the partition portion 2221, the air duct component 220 is provided with a guide surface 2222, the guide surface 2222 is a curved surface, the partition portion 2221 is located at a first end of the guide surface 2222 and is tangent to the first end, and a second end of the guide surface 2222 extends toward a first wall surface that defines the first air inlet 201. A part of the air entering the first cavity 282 from the first air inlet 201 can flow along the guiding path of the guiding surface 2222, that is, the part of the air flows along the curved surface of the guiding surface 2222, the flow direction of the part of the air is changed by the guiding surface 2222, the part of the air flows along the extending direction of the partition portion 2221, the air flowing along the air inlet direction of the first air inlet 201 is reduced, and the air volume of the two parts of the air entering the first air inlet 201 and the second air inlet 202 for contact heat exchange is reduced.

In some cases, a second end of the guide surface 2222 is perpendicular to the first wall surface defining the first inlet vent 201, so that the inlet air of the first inlet vent 201 flows along the guide surface 2222 toward the partition portion 2221. Of course, the second end of the guiding surface 2222 may also form an obtuse angle or an acute angle with the first wall surface, so that the intake air flows along the guiding surface 2222, and the specific structure of the guiding surface 2222 may be selected according to the requirement.

Referring to fig. 37 and 38, the guide surface 2222 includes a flat surface portion 22222 and a curved surface portion 22221, one end of the curved surface portion 22221 is connected to the partition portion 2221, the other end of the curved surface portion 22221 is connected to the flat surface portion 22222 and is tangent to the flat surface portion 22222, the flat surface portion 22222 extends toward the first wall surface, the curved surface portion 22221 functions to change the flow direction of the wind, the flat surface portion 22222 guides the wind toward the curved surface portion 22221, the flat surface portion 22222 is matched with the curved surface portion 22221, and the wind from the first wind inlet 201 is more smoothly introduced.

In some cases, the flat portion 22222 extends to be connected to the first wall surface. However, the planar portion 22222 may be spaced apart from the first wall surface, and the specific positional relationship between the planar portion 22222 and the first wall surface is not limited.

The air duct component 220 is provided with a second air inlet portion, the second air inlet portion forms a second air inlet 202, two ends of the second air inlet portion are respectively provided with a separation portion 2221, the first side comprises two side faces adjacent to the second side, namely, the two sides adjacent to the second air inlet 202 are respectively provided with a first air inlet 201, and partial inlet air of the corresponding first air inlet 201 can be respectively separated through the separation portions 2221 at the two ends of the second air inlet portion, so that the structure is simple, and the symmetry is good.

Air duct component 220 is provided with guide plate 2223, guide plate 2223 connects the border and the partition portion 2221 of air duct component 220, guide plate 2223 is located the below of partition portion 2221 and guiding surface 2222, guide plate 2223 can play the effect of supporting partition portion 2221 to make partition portion 2221 keep at preset height position, guarantee the corresponding relation of the air inlet of first air intake 201 and partition portion 2221, simultaneously, the air inlet of first air intake 201 can also flow to the direction of air exit along guide plate 2223.

The height of the separating portion 2221 is less than or equal to 1/3 of the height of the first air inlet 201, so that part of the air entering in the direction of the separating height of the separating portion 2221 has less influence on the air entering effect of the first air inlet 201, and the air entering efficiency of the first air inlet 201 can be ensured.

The length of the separating portion 2221 is less than or equal to 1/3 of the length of the first air inlet 201, so that the part of the air that is separated by the separating portion 2221 in the length direction enters the air, the influence on the air inlet effect of the first air inlet 201 is small, and the air inlet efficiency of the first air inlet 201 can be ensured. Here, the length of the partition 2221 is a length extending in the direction of the air duct member 220 toward the evaporator 230.

The air duct part 220 is integrally formed with the separating part 2221, and the separating part 2221 does not need to be independently processed and installed, so that the assembling process of the air duct assembly 200 can be simplified, and the assembling time can be saved. Or, the air duct member 220 is detachably connected to the partition portion 2221, and the structure and shape of the partition portion 2221 may be selected or changed according to actual needs, so that the structure of the air duct assembly 200 is more flexible and various.

The air duct part 220 includes a support plate and an insulating layer, the support plate plays a role of supporting the insulating layer and its upper parts, and the support plate is configured with the second air inlet 202. In some cases, the partition 2221 is integrally formed with or detachably connected to the support plate, in which case the guide surface 2222 is also a part of the surface of the support plate; of course, the case where the partition 2221 is integrally formed with the insulating layer or detachably connected is not excluded.

The above-described embodiment of the partition portion 2221, and the guide surface 2222 and the baffle plate 2223 related to the partition portion 2221 may be provided in the partition member 210, and at least one of the partition member 210 and the air passage member 220 may have the above-described function.

Based on the above description of the drain plate 100, the air duct member 220 may support the drain plate 100 of one of the above embodiments. The air duct member 220 includes a support plate and an insulating layer positioned above the support plate; the support plate includes the first support portion 222 and the second support portion 225, the insulating layer includes the second insulating layer 221 and the third insulating layer 224, the second insulating layer 221 is disposed above the first support portion 222, and the drain plate 100 is disposed above the second insulating layer 221.

Referring to fig. 20 to 25, when the drain board 100 has a structure of: including a drain part 110 and a water guide part, the drain part 110 being configured with an outlet 114, the drain part 110 being recessed with respect to the top surface of the drain plate 100; the water guide part is communicated with the water drainage part 110, the water guide part is sunken relative to the top surface of the water drainage plate 100, a fifth included angle is formed between the extending direction of the water guide part and the air outlet direction above the water drainage plate 100, the bottom of the water guide part inclines along the first direction towards the direction of the water drainage part 110, and a sixth included angle theta is formed between the first direction and the top surface of the water drainage plate 100 ₂ . The water guide may be understood as the first water guide 120 in the above embodiments.

The upper surface of the second insulating layer 221 is adapted to the lower surface of the drain plate 100, when the drain plate 100 is a corrugated plate, the upper surface of the second insulating layer 221 is a corrugated surface, and the shape of the lower surface of the second insulating layer 221 can be set as required, such that the lower surface of the air duct component 220 is also configured as a plane extending in the horizontal direction, and the lower surface of the air duct component 200 has a regular shape and a simple appearance structure.

Referring to fig. 37, the lower surface of the second insulating layer 221 is configured with a first support inclined surface inclined in the first direction, the first support 222 is configured with a second support inclined surface 2224 adapted to the first support inclined surface, and the first support inclined surface and the second support inclined surface 2224 are processed easily and can play a role in reducing the thickness of the air duct assembly 200.

The second insulating layer 221 is further configured with a first supporting groove adapted to the drain part 110, the first supporting part 222 is configured with a second supporting groove 2225 adapted to the first supporting groove, and a rear end opening 170 of the second supporting groove 2225 is communicated with the drain structure, so that the defrosted water received by the drain plate 100 is conveniently guided out.

The evaporator 230 above the drain plate 100 will be explained.

Referring to fig. 18-20, the evaporator 230 is positioned transversely within the first cavity 282 of the air duct assembly 200, and the drain plate 100 is positioned below the evaporator 230. The top surface of the drain plate 100 is parallel to the bottom surface of the evaporator 230. Here, the evaporator 230 is placed above the drain board 100 of fig. 1, 2, 10 and 11, but the structure of the evaporator 230 is not illustrated.

The evaporator 230 is transverse, and it is understood that the evaporator 230 has a height less than its length and width.

The water draining plate 100 is located below the evaporator 230, the water draining plate 100 is provided with a water guiding part which is concave relative to the top surface, and an included angle between the evaporator 230 and the horizontal direction is smaller than or equal to a preset included angle.

The angle between the evaporator 230 and the horizontal direction is smaller than or equal to the predetermined angle, which can be understood 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 connection line between the end of the evaporator 230 facing the air outlet and the end facing the air inlet forms the predetermined angle with the horizontal plane, and the connection line can be located on the bottom surface of the evaporator 230 or the symmetry plane in the height direction. When the evaporator 230 has a rectangular parallelepiped shape, both the bottom surface and the symmetrical plane of the evaporator 230 form a predetermined angle with the horizontal direction.

In some cases, the preset angle may be up to 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 predetermined angle is defined to be less than or equal to 7 ° in order to reduce the height of the air duct assembly 200, and the predetermined angle may be increased appropriately without strictly limiting the height of the air duct assembly 200.

Alternatively, the drain plate 100 may be provided with a water guide portion recessed with respect to the top surface, and the evaporator 230 may be horizontally disposed in the first cavity 282, in which case the height of the air duct assembly 200 may be sufficiently reduced.

The included angle formed by the evaporator 230 and the horizontal direction is smaller than or equal to a preset angle, so that the height direction space occupied by the evaporator 230 is reduced, the overall height of the air duct assembly 200 can be reduced, and the purpose of expanding the capacity of the refrigeration equipment is achieved.

In combination with the drainage plate 100 shown in fig. 3 to 14, the preset angle may be 7 °, so as to meet the defrosting and drainage requirements of the evaporator 230, and reduce the overall height of the air duct assembly 200.

It can be understood that, but evaporimeter 230 horizontal installation is in drain bar 100 top, can understand that the bottom surface of evaporimeter 230 is on a parallel with the horizontal plane, for the condition that evaporimeter 230 slope set up, the required installation space's of the evaporimeter 230 of horizontal setting highly diminishes, then wind channel subassembly 200 direction of height size can diminish thereupon, and then the space in the box courage body that wind channel subassembly 200 was occupied diminishes, under the unchangeable condition of external dimension of box courage body, can effectively improve the capacity of box courage body, so as to provide the refrigeration plant of a large capacity.

At this time, the installation state of the drain plate 100 is not limited, and the top surface of the drain plate 100 is parallel to the bottom surface of the evaporator 230, or the top surface of the drain plate 100 is inclined obliquely downward from front to rear with respect to the bottom surface of the evaporator 230.

It is understood that the top surface of the drain plate 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 drain plate 100 are horizontally disposed. 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 is reduced, so that the wind in the first cavity 282 is prevented from directly flowing to the ventilation opening 244 from the gap between the evaporator 230 and the drain plate 100, and the wind is assisted to exchange heat sufficiently in the first cavity 282.

It should be noted that, the gap between the evaporator 230 and the drain plate 100 is minimized, the speed of the wind flowing from the gap between the evaporator 230 and the drain plate 100 to the vent 244 is slowed, and the staying time of the wind in the first cavity 282 is prolonged, so that the wind can fully exchange heat with the evaporator 230 in the first cavity 282 and then flow out, and the heat exchange efficiency is ensured.

In the above embodiment, the evaporator 230 is a part of a refrigeration system in the refrigeration equipment, the refrigeration system includes a compressor, a condenser, a throttling element and the evaporator 230, and a refrigerant in the refrigeration system evaporates in the evaporator 230 to absorb heat, so as to provide a refrigeration environment for the wind in the first cavity 282.

The structure of the evaporator 230 will be explained. Although the evaporator 230 is mounted to the air duct assembly, the evaporator 230 is not limited to the air duct assembly 200, and may be mounted in other applicable environments.

The evaporator 230 includes a heat exchanging pipe 233 and a heat dissipating fin 234 connected to the heat exchanging pipe 233, and the heat dissipating fin 234 is configured with a ventilation portion 23421 through which the intake air of the first intake port 201 passes, so that the intake air of the first intake port 201 flows toward the inside of the evaporator 230 through the ventilation portion 23421, so that the intake air of the first intake port 201 exchanges heat sufficiently.

It should be noted that the ventilation portions 23421 may be provided on part of the fins 234, or the ventilation portions 23421 may be provided on all the fins 234, which may be specifically selected as needed.

Next, a description will be given of an example in which the ventilation portion 23421 is formed in part of the heat sink 234.

The evaporator 230 comprises a heat exchange tube 233, a first cooling fin 2341 and a second cooling fin 2342, the first cooling fin 2341 and the second cooling fin 2342 are connected to the heat exchange tube 233, the first cooling fins 2341 are arranged in parallel to form a first cooling portion, at least one side of the first cooling portion is provided with the second cooling fin 2342 (when the evaporator is installed in the air duct assembly, the second cooling fin 2342 is arranged between the first cooling fin 2341 and the first air inlet 201), the second cooling fin 2342 is provided with a ventilation portion 23421 through which the inlet air of the first air inlet 201 can pass, so that part of the inlet air of the first air inlet 201 is divided into the evaporator 230 through the ventilation portion 23421, the air quantity of the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 are in cross contact with each other to achieve heat exchange is reduced, and frost condensed due to the fact that the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 are in contact with each other to achieve heat exchange is reduced.

The air inlet of the first air inlet 201 is divided by the second cooling fin 2342 of the evaporator 230, the influence on the overall structure of the air duct assembly 200 is small, only part of the cooling fins 234 need to be replaced by the second cooling fin 2342 with the ventilation portion 23421, the structure is simple, and the air inlet division effect is good.

Wherein, second fin 2342 is located at least one side of first fin 2341, and one side of wind channel subassembly 200 sets up first air intake 201 promptly, then second fin 2342 is located one side that corresponds, and the both sides that wind channel subassembly 200 is relative all set up first air intake 201, then the both sides of first fin 2341 all set up second fin 2342. 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, and the air outlet is located at the other end of the second heat sink 2342.

The number of the second heat sinks 2342 may be set as desired, and one or more second heat sinks 2342 may be provided. When the second heat sink 2342 is provided with one, part of the intake air from the first intake opening 201 flows between the second heat sink 2342 and the first heat sink 2341 through the ventilation part 23421, and flows in the direction of the air outlet along the space between the second heat sink 2342 and the first heat sink 2341; when the plurality of second heat dissipation fins 2342 are provided, the wind passes through the ventilation parts 23421 of the second heat dissipation fins 2342 and flows along the space between the adjacent second heat dissipation fins 2342 and the space between the second heat dissipation fins 2342 and the first heat dissipation fins 2341 to flow toward the air discharge opening, and the flowing space of the wind is larger and the fluidity is better.

The ventilation parts 23421 of the adjacent second heat dissipation fins 2342 pass through in a straight line, that is, in the two adjacent second heat dissipation fins 2342, the orthogonal projection of the ventilation part 23421 of one second heat dissipation fin 2342 overlaps the orthogonal projection of the ventilation part 23421 of the other second heat dissipation fin 2342, so that part of the wind can smoothly pass through the ventilation part 23421 and flow in the direction of the first heat dissipation fin 2341.

The ventilation parts 23421 of the adjacent second heat dissipation fins 2342 are communicated with each other in an offset manner, that is, in the adjacent two second heat dissipation fins 2342, the orthographic projection of the ventilation part 23421 of one second heat dissipation fin 2342 overlaps a part of the orthographic projection of the ventilation part 23421 of the other second heat dissipation fin 2342, or the orthographic projections of the ventilation parts 23421 of the adjacent two second heat dissipation fins 2342 do not intersect, so that part of the wind can flow in the extending direction of the second heat dissipation fins 2342.

The two adjacent second fins 2342 may have straight through ventilation portions 23421 and staggered through ventilation portions 23421, and the structure is more diversified.

When the second heat dissipation fins 2342 are provided in plurality, the cross-sectional area of the ventilation portion 23421 may gradually decrease in the direction from the outside of the evaporator 230 toward the first heat dissipation fin 2341, the amount of intake air passing through the ventilation portion 23421 in the direction toward the first heat dissipation fin 2341 decreases, the cross-sectional area of the ventilation portion 23421 decreases, the influence on the flow of wind is small, and the heat dissipation area of the second heat dissipation fin 2342 can be ensured.

The ventilation part 23421 includes at least one of a through hole having a closed loop and a through hole having an opening, and the ventilation part 23421 has various structures and is easy to manufacture.

The shape of the ventilation part 23421 is at least one of rectangle, circle, ellipse, trapezoid and triangle, and the ventilation part 23421 has various shapes and a simple structure.

The shape of the ventilation portion 23421 is at least one of a closed rectangle, a circle, an ellipse, a trapezoid and a triangle, or the shape of the ventilation portion 23421 is at least one of a rectangle, a circle, an ellipse, a trapezoid and a triangle with an opening, such as a rectangle with an opening 170 at one end, a circle with a notch, an ellipse with a notch, etc.

Of course, the shape of the ventilation part 23421 is not limited to the aforementioned shape, and the specific shape of the ventilation part 23421 may be provided as needed.

The both sides of evaporimeter 230 all set up first air intake 201, and a plurality of first fin 2341 set up side by side and form first heat dissipation portion, and the bilateral symmetry of first heat dissipation portion sets up second fin 2342, and evaporimeter 230 all is provided with ventilation portion 23421 corresponding to the position of two first air intakes 201, guarantees that the part air inlet of two first air intakes 201 all can be shunted through ventilation portion 23421.

Referring to fig. 13, air return components 430 are disposed on both left and right sides of the air duct assembly 200, and the air return components 430 are communicated with the first air inlets 201 to supply air to both sides of the air duct assembly 200.

The first and second heat dissipation fins 2341 and 2342 are disposed above the drain plate 100 to receive the defrosting water of the evaporator 230 through the drain plate 100, and the evaporator 230 is simply structured and conveniently installed.

The evaporator 230 may further be provided with a gravity sensor, by which a weight change of the evaporator 230 is obtained to determine whether the evaporator 230 needs defrosting according to the weight change. The evaporator 230 may further include a vibrator, which provides a vibration force to assist in defrosting.

A heating structure for defrosting inside the air duct assembly 200 will be described.

As shown in fig. 20, in some cases, a first heater 231 is disposed above the drain plate 100, that is, the first heater 231 is disposed between the drain plate 100 and the evaporator 230, and when the evaporator 230 needs defrosting, the first heater 231 is turned on, and heat generated by the first heater 231 is used to heat the frost attached to the surface of the evaporator 230. In some cases, the heat sink 234 of the evaporator 230 is provided with a clamping groove for installing the first heater 231, the first heater 231 is clamped to the heat sink 234 through the clamping groove, and the clamping groove can be arranged at a position below the heat sink 234, so that the first heater 231 is located between the drain board 100 and the heat exchange pipe 233, and at this time, the first heater 231 is easy to install and has a good defrosting effect.

Of course, the heating structure for defrosting is not limited to be disposed between the drain board 100 and the evaporator 230, and in some cases, the heating structure may be disposed between the heat exchanging pipes 233 of the evaporator 230, for example, the heating structure is the second heater 232 inserted into the heat dissipating fins 234 of the evaporator 230, and the inserted 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 inserted into the mounting hole 2343, so that the structure is simple and the assembly and disassembly are simple and convenient.

The second heater 232 extends along a first end of the evaporator 230 to a second end, the first end and the second end being opposite ends, to provide heat to the evaporator 230 sufficiently, where the second end and the first end are two ends forming an 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 inserted between the two rows of heat exchange tubes 233 to uniformly heat and defrost the upper and lower rows of heat exchange tubes 233, and at this time, the heat exchange efficiency of the second heater 232 and the heat exchange tubes 233 and the heat dissipation fins 234 on the second heater 232 and the heat exchange tubes 233 is higher, and the defrosting heating efficiency can be improved.

The second heaters 232 are distributed in multiple layers in the height direction of the evaporator 230 to heat a plurality of positions of the evaporator 230.

The second heater 232 comprises a plurality of fixedly connected heating rods which are fixedly connected into a whole, and the heating rods are directly and integrally inserted into the radiating fins 234 in the assembling process, so that the assembly is simple and convenient, and the assembly efficiency is high.

The second heater 232 comprises a plurality of independent heating rods, the positions of the heating rods are flexible, the heating rods can be conveniently and independently replaced, and the heating rods can be more conveniently disassembled and assembled.

When the second heater 232 includes a plurality of independent heating rods, the heating rods may be distributed along the height direction of the evaporator 230 in a staggered manner, so that the number of the heating rods may be reduced, and the overall defrosting of the evaporator 230 may be fully performed.

When heating structure does not set up between drain bar 100 and evaporimeter 230, evaporimeter 230 can directly be placed on drain bar 100, can effectively reduce the clearance between evaporimeter 230 and the drain bar 100, plays the effect that slows down the wind speed, also can play the effect that improves heat exchange efficiency.

The heating structure can be set up as heating member 160, heating member 160 sets up on the surface of drain plate 100, heating member 160 can be integrated into the structure of integral type with drain plate 100, the drain plate 100 mountable that has heating member 160 is in multiple structure evaporimeter 230 below, this drain plate 100 can accept and discharge the defrosting water, can heat the defrosting again, drain plate 100 has dual function, this drain plate 100 is installed in wind channel subassembly 200, can reduce wind channel subassembly 200's height.

It should be noted that the drain board 100 having the heating members 160 may be disposed below the horizontal evaporator 230. Alternatively, the drain board 100 having the heating member 160 may be disposed under the evaporator 230 vertically installed in the cabinet 400, and the application of the drain board 100 is not limited herein.

The heating member 160 may be integrally formed with the drain board 100 of any of the above embodiments. Alternatively, the heating member 160 may be integrally formed with the other drain board 100 that may function to receive and discharge the defrost water, so that the drain board 100 may be widely used in various applications.

The heating element 160 covers the lower surface of the drain plate 100, the upper surface of the drain plate 100 is used for receiving defrosting water, the heating element 160 positioned on the lower surface of the drain plate 100 can avoid direct contact with water, the occurrence of electric leakage accidents due to circuit faults can be avoided, and the safety performance of the refrigeration equipment is better.

Of course, in the case of ensuring the waterproof performance of the heating member 160, the heating member 160 may cover the upper surface of the drain board 100.

The heating member 160 may be a heating wire or a heating film provided on the surface of the drain board 100.

The following description will be given taking a heating member as an example of a heating film.

Heating member 160 includes the insulating layer and sets up in the composite heating layer of insulating layer lower surface, and the insulating layer is connected in drain bar 100's lower surface, carries out insulation protection through the insulating layer between drain bar 100 and the composite heating layer, can reduce the electric leakage risk. At this time, the material of the drain board 100 is not limited, the drain board 100 may be made of steel, the processing is simple, and the heat conduction effect of the drain board 100 can be ensured.

The heating member 160 includes the composite heating layer, and the drain bar 100 is the insulating heat conduction structure, and the composite heating layer sets up in the lower surface of drain bar 100, and the drain bar 100 has heat conduction and insulating function simultaneously, then can save the insulating layer for the course of working of drain bar 100 is more simple and convenient, helps promoting production efficiency. The drainage plate 100 may be a structure formed by combining ceramic and glass fiber materials.

Wherein, the composite heating layer of the heating member 160 can be a graphene heating layer, a nano heating layer or a carbon fiber heating layer and a heating layer formed by compounding various electric heating materials. When the composite heating layer is electrified, the electric energy can be converted into the heat energy of the heating element 160, so as to provide heat for defrosting. Taking the composite heating layer as a graphene heating layer as an example, the graphene heating layer is a hexagonal honeycomb-lattice planar film composed of carbon atoms, and the thickness of the heating element 160 can be controlled by only one atom.

It should be noted that, when the heating element 160 is disposed on the lower surface of the drainage plate 100, an insulating layer is further disposed below the composite heating layer, so that the downward diffusion of heat can be reduced, and the heating efficiency can be ensured. The composite heating layer and the insulating layer, the composite heating layer and the drainage plate 100 and the insulating heat-insulating layer and the composite heating layer are bonded by the heat-conducting adhesive layers, and the heat-conducting adhesive layers can realize reliable connection between the layers while realizing the heat-conducting effect.

The heating member 160 includes a plurality of heating zones distributed along a set direction, heating power per unit area of the heating zones increases gradually along the set direction, heating power of the corresponding heating zones can be adjusted according to different frosting amounts at different positions, rapid and sufficient defrosting can be realized, and power consumption can be reduced.

When the composite heating layer adopts the graphene heating layer, the grid distribution of the graphene heating layers in different heating zones is different, so that the resistance distribution of the graphene heating layers in different heating zones is different. The lower surface of the drainage plate 100 may be distributed with two graphene heating layers with different resistances, or may be distributed with any number of graphene heating layers with different resistances. In addition, the graphene heating layers with different resistances can be connected in series or in parallel, and can be connected into different circuits.

The heating element 160 in the above embodiment is applied to the air duct assembly 200, and is used for defrosting the evaporator 230, so that the space occupied by the heater can be reduced, the height of the air duct assembly 200 can be reduced, the volume of the air duct assembly 200 can be further reduced, and the refrigerating equipment with the air duct assembly 200 can appropriately increase the storage space and expand the capacity of the refrigerating equipment.

The drain board 100 having the heating member 160 in the above embodiment may be used in combination with at least one of the first heater 231 and the second heater 232 to improve defrosting efficiency.

It should be noted that the above is that the heating member 160 may be applied to the drain board 100 of the above embodiment, but is not limited thereto, and the heating member 160 may also be applied to drain boards of other structures.

The heating structure for defrosting needs to be electrically connected with a power supply outside the air duct assembly 200 through a wire, the wire can be wired through a wiring hole formed in the fan guard 240, and the heating structure is simple in structure and convenient to assemble.

The structure of the partition member 210 will be explained below.

The partition plate 210 and the air duct 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, the inlet air of the air inlet exchanges heat in the first cavity 282 and then is discharged from the air outlet, and the air outlet sends air into the compartment to provide a refrigeration environment for the refrigeration equipment. When the air inlets include the first air inlet 201 and the second air inlet 202, the first air inlet 201 and the second air inlet 202 include the inlet air with different temperatures.

The partition member 210 may be fixedly connected to the tank body, for example, the edge of the partition member 210 is fixed to the tank body by welding, clamping, or fastening. Referring to fig. 6 and 20, the partition board 210 includes a first board body 211 and a second board body 212, the first board body 211 and the second board body 212 are provided with a first heat preservation layer 213, the first heat preservation layer 213 is detachably disposed between the first board body 211 and the second board body 212, or the first heat preservation layer 213 is integrally formed with the first board body 211 and the second board body 212 by foaming.

When the first heat preservation layer 213 is formed by foaming the first plate 211 and the second plate 212, the first plate 211 and the second plate 212 can be fixedly mounted on the tank body, the first heat preservation layer 213 is formed by foaming the first heat preservation layer and the cabinet body 400, the sealing performance between the partition board 210 and the tank body is better, and the wind leakage between the first compartment 410 and the second compartment 420 can be avoided.

Referring to fig. 6 and 20, the partition member 210 further includes a third plate body 214, the third plate body 214 and the first and second plate bodies 211 and 212 define an installation space, the third plate body 214 is located in front of the air duct assembly 200, the installation space is located in front of the partition member 210, and the installation space is used for installing functional components, such as a controller, a lighting module, an interaction module, and a display module. When the second intake vent 202 is disposed at the front side of the air duct assembly 200, the portion of the partition member 210 that limits the installation space is located at the front end of the second intake vent 202, and the portion that limits the installation space plays a role of covering the second intake vent 202, so that the second intake vent 202 is hidden, and the lower portion of the second intake vent 202 is communicated with the second compartment 420.

It should be noted that the second air inlet 202 is not limited to be disposed at the front side of the air duct assembly 200, and the second air inlet 202 may also be disposed at a position forward of the lower side of the air duct assembly 200.

Referring to fig. 26 to 28, the partition member 210 and the air duct member 220 define a first cavity 282, a first inlet 201, a second inlet 202 and an outlet, wherein the first inlet 201 and the second inlet 202 comprise inlets with different temperatures; the first air inlet 201 is located at a first side of the air duct assembly 200, the second air inlet 202 is located at a second side of the air duct assembly 200, the first side and the second side are adjacent, or the first air inlet 201 and the second air inlet 202 are located at the same side; the partition plate part 210 is configured with an inner concave part which is concave towards the inner side of the partition plate part 210, and the inner concave part is suitable for guiding part of the inlet air of at least one of the first air inlet 201 and the second air inlet 202 to flow into the inner concave part, that is, part of the inlet air of at least one of the first air inlet 201 and the second air inlet 202 to flow into the respective corresponding inner concave part, so as to reduce the cross contact air quantity in the inlet air of the first air inlet 201 and the second air inlet 202, reduce the frosting quantity of the cross contact area of the inlet air, further prolong the time interval between two times of defrosting, reduce the defrosting times and reduce the defrosting power consumption.

Taking the first air inlet 201 and the second air inlet 202 located at different sides and the air inlet directions are intersected with each other as an example, in the air inlet process, a part of air of the first air inlet 201 is guided along the extending direction of the corresponding concave portion, and a part of air continuously flows along the air inlet direction, when the first air inlet 201 and the second air inlet 202 simultaneously supply air, the air continuously flowing along the air inlet direction is intersected with the air of the second air inlet 202, so that the amount of air in the air inlet of the first air inlet 201 and the amount of air in the air inlet of the second air inlet 202 which are intersected with each other are reduced. The principle of the concave portion arranged in the corresponding area of the second air inlet 202 is the same, and the description is omitted here.

For example, the first air inlet 201 and the second air inlet 202 are located at the same side (if both are located at the front side), and the air inlet directions are the same, the extending direction of the concave portion is the same as the extending direction of the corresponding air inlet, part of the inlet air of the first air inlet 201 flows along the extending direction of the corresponding concave portion, and the other part of the inlet air of the first air inlet 201 continues to flow along the flowing direction thereof.

Referring to fig. 26, the concave portion includes a first concave portion 2121, the first concave portion 2121 extends a first predetermined length L2 along a second side of the partition member 210 to a third side with a first predetermined width L1, the second intake vent 202 is located at the second side, the third side is a side not adjacent to the second side, the third side may be a side where the exhaust vent is located, the first concave portion 2121 is close to a first side edge of the partition member 210, and the first intake vent 201 is located at the first side.

The air entering the first cavity 282 from the first air inlet 201 flows partially 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 flows partially along the extending direction of the first concave portion 2121, and the first concave portion 2121 plays a role in guiding and shunting to reduce the air volume of the intersection of the air inlet of the first air inlet 201 and the air inlet of the second air inlet 202, thereby reducing the frosting amount.

The first preset width L1 may 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 may be set to be less than or equal to the length of the evaporator 230, and the length direction of the evaporator 230 is the direction from the air inlet to the air outlet.

Referring to fig. 26, the first concave portion 2121 is configured with a first top surface 2123 and a first guide surface 2122 connected to the first top surface 2123, the first guide surface 2122 is inclined downward in a direction away from the first top surface 2123, the first guide surface 2122 is located on a side away from the first air inlet 201, and the first guide surface 2122 guides the air toward the air outlet to prevent the wind from being trapped in a groove defined by the first concave portion 2121, thereby ensuring a circulating flow effect of the wind.

When the first side of the first cavity 282 includes two or more sides, if the first side is set as the opposite left side and right side, the first air inlets 201 are disposed on the left side and right side of the air duct assembly 200, the two sides of the partition plate component 210 are symmetrically provided with the first concave portions 2121, each of the first concave portions 2121 corresponds to one of the first air inlets 201, and it is ensured that the inlet air of each of the first air inlets 201 flows through a part of the air flowing through the first concave portion 2121.

Among them, the first guide surface 2122 may be provided at a rear side, a left side, or a right side of the first concave portion 2121. As shown in fig. 26, one first guide surface 2122 is illustrated on the rear side of the first concave portion 2121, and the other first guide surface 2122 is illustrated on the left side of the first concave portion 2121. Fig. 26 illustrates the first guide surface 2122 at different positions, and in practical applications, the two first concave portions 2121 are generally symmetrically arranged.

Referring to fig. 27 and 28, the concave portion includes a second concave portion 2124, and a side of the second concave portion 2124 faces the second air inlet 202, so that the second concave portion 2124 can guide part of the inlet air of the second air inlet 202 to flow along the groove defined by the second concave portion 2124, and the second air inlet 202 also branches part of the inlet air, thereby reducing the amount of air at the intersection of the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202, and also reducing the amount of frost formation.

The second concave recess 2124 extends along a second side of the baffle section 210 to a third side by a second predetermined length L4 with a second predetermined width L3, the second predetermined length L4 being less than the length of the evaporator 230 in the first cavity 282, the length of the evaporator 230 being along the second side to the third side. The second and third sides herein can be referred to the explanations above. The length of the second concave portion 2124 is smaller than the length of the evaporator 230, so as to prevent the wind in the first concave portion 2121 from directly flowing to the air outlet, and ensure that the wind in the first concave portion 2121 exchanges heat with the evaporator 230 and then is exhausted from the air outlet.

The second 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 in a direction away from the second top surface 2126, the second guide surface 2125 faces the side of the exhaust port, and the wind is guided downward by the inclined surface of the second guide surface 2125 so that the wind sufficiently flows toward the evaporator 230.

In some cases, the first and second concave portions 2121 and 2124 may be used in combination, that is, the separator member 210 is provided with both the first and second concave portions 2121 and 2124, and in this case, the second concave portion 2124 is separated from the first concave portion 2121 by the third wall plate 215, and the concave depths of the first and second concave portions 2121 and 2124 are the same, which is simple in structure and convenient to machine.

In the case that the partition member 210 is provided with the first concave portion 2121 and the second concave portion 2124 at the same time, the first predetermined length L2 is greater than or equal to the second predetermined length L4, the first concave portion 2121 guides the inlet air of the first air inlet 201 to the direction of the air outlet, and the second concave portion 2124 guides the inlet air of the second air inlet 202 to the direction of the air outlet, so as to ensure the heat exchange effect between the air and the evaporator 230.

It should be noted that the wind in the second concave portion 2124 may also include wind obtained by mixing the wind from the first wind inlet 201 and the wind from the second wind inlet 202.

The evaporator 230 includes a heat exchanging pipe 233 and a heat dissipating fin 234 connected to the heat exchanging pipe 233, the heat dissipating fin 234 extends along a side of the second air inlet 202 toward a side of the air outlet, and the heat dissipating fin 234 guides the air flowing from the side of the air inlet toward the side of the air outlet.

The heat sink 234 is configured with a protrusion that extends into the second concave recess 2124 to ensure that the wind in the second concave recess 2124 can exchange heat with the heat sink 234 sufficiently.

Referring to fig. 29, the partition plate member 210 is configured with a third concave portion 2127, one side of the third concave portion 2127 faces the first air inlet 201, the other side of the third concave portion 2127 faces the second air inlet 202, and the first air inlet 201 and the second air inlet 202 are located at two adjacent sides, so that the third concave portion 2127 is located at an intersection region where the first air inlet 201 and the second air inlet 202 correspond to each other, and the third concave portion 2127 increases a space of an air inlet intersection region of the first air inlet 201 and the second air inlet 202, increases a frost accommodating space, extends a time period during which air can be supplied at an end of the air inlet, reduces a number of times of defrosting, extends a defrosting period, and saves power consumption of defrosting.

Referring to fig. 5, the first air inlet 201 and the second air inlet 202 are located at two adjacent sides, the first air inlet 201 is located at the left and right sides of the air duct assembly 200 and is communicated with the first compartment 410 through the air return component 430, the second air inlet 202 is located at the front side of the air duct assembly 200, and both the first air inlet 201 and the second air inlet 202 are located at a position near the front of the air duct assembly 200.

The first air inlet 201 and the second air inlet 202 may also be located on opposite sides (not shown), for example, 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 right side of the air duct assembly 200, at this time, a larger intersection space may be provided for the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 by the third concave portion 2127. The first air inlet 201 and the second air inlet 202 can also be positioned at two opposite sides, and the distance between the first air inlet 201 and the second air inlet 202 can also be increased, so that the air quantity of cross heat exchange is properly reduced.

The third concave portion 2127 extends by a third predetermined width L5 along the side of the second air inlet 202 where the side of the air outlet is located, by a third predetermined length L6, the third predetermined length L6 is smaller than the length of the evaporator 230 in the first cavity 282, and the length of the evaporator 230 is along the side of the second air inlet 202 where the side of the air outlet is located.

Referring to fig. 29, the width direction of the third concave portion 2127 is perpendicular to the direction from the second air inlet 202 to the air outlet, the third predetermined width L5 is a dimension of the third concave portion, and the third predetermined length L6 is a length of the third concave portion in the direction from the second air inlet 202 to the air outlet.

The third 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 in a direction away from the third top surface 2128, and the third guide surface 2129 faces the side where the air discharge opening is located. The third guide surface 2129 guides the wind in the third concave portion 2127 toward the evaporator 230, so that the wind is discharged after sufficient heat exchange.

The following structure of the air duct assembly 200 is proposed based on the above-described embodiments of the drain plate 100, the fan cover 240, the fan 270, the air duct member 220, the heating structure for defrosting, the partition member 210, and the like, but the air duct assembly 200 is not limited to the following structure.

Referring to fig. 1 to 13, the air duct assembly 200 includes a partition member 210 and an air duct member 220, the partition member 210 and the air duct member 220 form a first cavity 282, an air inlet and an air outlet, the air inlet is divided into a first air inlet 201 and a second air inlet 202, a drain plate 100 is disposed in the first cavity 282, the drain plate 100 is configured with a water guiding portion recessed downward relative to a top surface of the drain plate 100, the water guiding portion extends to edges of the drain plate 100 towards two sides of a predetermined surface, so that the edges of the drain plate 100 form an opening 170, and the opening 170 faces the side of the first air inlet 201, so that part of the inlet air of the first air inlet 201 is suitable to flow into the first cavity 282 through the opening 170 and along an extending direction of the water guiding portion. Part of the inlet air of the first air inlet 201 passes through the opening 170 and is guided into the first cavity 282 along the extending direction of the water guide part, so that part of the inlet air of the first air inlet 201 can be divided, the air quantity in cross contact with the inlet air of the second air inlet 202 is reduced, further, the condensed frost caused by the cross contact between the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 is reduced, the defrosting times are reduced, the defrosting period is prolonged, the power consumption required by defrosting is reduced, and the power consumption of the refrigeration equipment is reduced.

The water conveying part has at least one structure shown in fig. 1 to 13, that is, the water conveying part may be at least one of the second water conveying part 130 and the third water conveying part 140.

It will be appreciated that the air duct assembly 200 further includes a first drain member 260 on the first side, the first drain member 260 being in communication with the opening 170 of the drain plate 100, the first drain member 260 being configured with a drain opening. The first drain part 260 has both functions of draining and supplying air.

It can be understood that the air duct assembly 200 further includes a fan guard 240, the fan guard 240 defines a second cavity 281, the fan 270 is disposed in the second cavity 281, and a rotation axis of the fan 270 forms a first included angle α with a vertical direction ₁ The fan guard 240 defines a vent 244, and an inlet of the fan 270 faces the vent 244. The fan 270 is transversely arranged in the fan cover 240, so that the height of the fan 270 can be reduced, the height of the air duct assembly 200 is further reduced, and a drawer is conveniently arranged below the air duct assembly 200.

It can be understood that the evaporator 230 is disposed in the first cavity 282, the drain plate 100 is located below the evaporator 230, an included angle between the evaporator 230 and the horizontal direction is smaller than or equal to a preset angle, or the evaporator 230 is parallel to the horizontal direction, the evaporator 230 is horizontal, and an angle of downward inclination thereof may be smaller than or equal to 7 ° or horizontal, a space in a height direction occupied by the evaporator 230 is reduced, and a height of the air duct assembly 200 is also reduced, which is beneficial to increasing a space of the refrigeration apparatus.

The partition member 210, the air duct member 220, the first water discharging member 260, the fan 270, the fan guard 240, the water discharging plate 100, the evaporator 230, and the like may all adopt the structure of the above embodiments, and the description thereof is omitted.

As shown in fig. 10 to 25, the air duct assembly 200 includes a partition member 210, an air duct member 220, an evaporator 230, and a drain plate 100, the partition member 210 and the air duct member 220 form a first cavity 282, a first air inlet 201, a second air inlet 202, and an air outlet, the first air inlet 201 is located on a first side of the first cavity 282, the second air inlet 202 is located on a second side of the first cavity 282, and the first side is adjacent to the second side; the evaporator 230 is disposed in the first chamber 282; the drain plate 100 is located in the first cavity 282; the water discharging plate 100 is located below the evaporator 230, and is configured with a water guiding portion and a water discharging portion 110 which are recessed downward relative to the top surface of the water discharging plate 100, the water discharging portion 110 is configured with an outlet 114 and is communicated with the water guiding portion, a fifth included angle is formed between the extending direction of the water discharging portion 110 and the extending direction of the water guiding portion, an opening 170 is configured at the end of the water guiding portion, and the opening 170 faces the first air inlet 201, so that the wind of the first air inlet 201 is suitable for flowing into the first cavity 282 along the extending direction of the water guiding portion. The water guide part plays a role in guiding the air entering the first air inlet 201, so that a part of the air entering the first air inlet 201 flows into the first cavity 282 along the water guide part, the air quantity of the cross contact in the air entering of the first air inlet 201 and the second air inlet 202 is reduced, the frost condensed due to the contact of the air with different temperatures is reduced, the time of a defrosting interval is further prolonged, the defrosting frequency is reduced, the power consumption of defrosting is saved, and the effects of saving power and energy are achieved.

At this time, the water conveying part may be configured as the third water conveying part 140.

It can be understood that the outlet 114 of the drain plate 100 and the air outlet are located at the same side of the first cavity 282, and the heat of the defrosting water flowing to the outlet 114 of the drain plate 100 can act as defrosting for the fan 270 at the same side.

It is understood that the top surface of the drain plate 100 and the bottom surface of the evaporator 230 are both inclined obliquely downward by a predetermined angle, or the top surface of the drain plate 100 and the bottom surface of the evaporator 230 are both parallel to the horizontal plane. The evaporator 230 is horizontal and the downward inclination angle thereof 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 is helpful for increasing the space of the refrigeration equipment.

The air duct assembly 200 further includes a first drain 260 on the first side, the first drain 260 surrounding the opening 170 and communicating with the opening 170, the first drain 260 being configured with a first drain opening 262. The first drainage part 260 may be disposed within a foaming layer of the cabinet 400 to increase the space of the compartment.

The air duct assembly 200 further includes a fan guard 240, the fan guard 240 defines a second cavity 281, a fan 270 is disposed in the second cavity 281, and a first included angle α is formed between a rotation axis of the fan 270 and a vertical direction ₁ The fan guard 240 defines a vent 244, and an inlet of the fan 270 faces the vent 244. The fan 270 is positioned laterally within the fan guard 240, and the height of the fan 270 is reduced, thereby reducing the overall height of the duct assembly 200.

The partition 210, the air duct 220, the first water discharging 260, the fan 270, the fan cover 240, the water discharging plate 100, the evaporator 230, and other components may all adopt the structure of the above embodiments, and the details are not repeated herein.

As shown in fig. 10 to 25, the air duct assembly 200 includes a partition member 210, an air duct member 220, an evaporator 230, and a drain plate 100, the partition member 210 and the air duct member 220 form a first cavity 282, a first air inlet 201, a second air inlet 202, and an air outlet, the first air inlet 201 is located at a first side of the first cavity 282, the second air inlet 202 is located at a second side of the first cavity 282, and the first side is adjacent to the second side; the evaporator 230 is disposed in the first chamber 282; the drain plate 100 is located in the first cavity 282; the top surface of the water discharging plate 100 is located below the evaporator 230, the water discharging plate 100 is configured with a water guiding part and an outlet 114, the water guiding part is recessed relative to the top surface of the water discharging plate 100 and is communicated 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.

In this case, the water conveying part may be at least one of the second water conveying part 130 and the third water conveying part 140.

The angle between the evaporator 230 and the horizontal direction is less than or equal to a predetermined angle, or the evaporator 230 is disposed along the horizontal direction. The evaporator 230 is horizontal and the downward inclination angle thereof 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 is helpful for increasing the space of the refrigeration equipment.

The air duct assembly 200 also includes a fan 270 located on one side of the first cavity 282, with the outlet 114 of the drain plate 100 facing the side of the fan 270. The outlet 114 of the drain plate 100 is offset from the inlet of the fan 270 to prevent water from flowing toward the fan 270.

The second inlet 202 is located at the front side of the air duct assembly 200 and is communicated with the second compartment 420, the first inlet 201 is located at least one of the left side and the right side of the air duct assembly 200 and is close to the front end, and the first inlet 201 is communicated with the first compartment 410 so as to return air through the front end of the air duct assembly 200.

The partition 210, the air duct 220, the first water discharging 260, the second water discharging 290, the fan 270, the fan cover 240, the water discharging plate 100, the evaporator 230, etc. may all adopt the structure of the above embodiments, and the details are not described herein.

Referring to fig. 1 to 25, the air duct assembly 200 includes a partition member 210, an air duct member 220, a fan 270, an evaporator 230, and a drain plate 100, the partition member 210 and the air duct member 220 form a first cavity 282, a first air inlet 201, a second air inlet 202, and an air outlet, the first air inlet 201 is located on a first side of the first cavity 282, the second air inlet 202 is located on a second side of the first cavity 282, and the first side is adjacent to the second side; the evaporator 230 is disposed in the first chamber 282; the drain board 100 is located in the first cavity 282; the top surface of the drain plate 100 is positioned below the evaporator 230, the drain plate 100 is configured with a water guide portion recessed downward with respect to the top surface of the drain plate 100, the water guide portion extends to both sides of a preset surface to the edge of the drain plate 100 such that the edge of the drain plate 100 forms an opening 170 adapted to drain water, the opening 170 facing a first side; the fan 270 is located at a third side of the first cavity 282. That is, the drainage positions of the fan 270 and the drainage plate 100 are located at different sides, so that the space occupied by the side where the fan 270 is located can be reduced, and the compartment space in the refrigeration apparatus can be increased, thereby providing a refrigeration apparatus with a large capacity.

The air duct assembly 200 further includes a first drain feature 260 on the first side, the drain channel of the first drain feature 260 being in communication with the opening 170, the first drain feature 260 being configured with a drain opening. The first drainage part 260 may be formed in the foam layer of the cabinet 400, does not occupy the space of the compartment, and effectively enlarges the capacity of the compartment. The opening 170 side of the drain plate 100 is drained by 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 smaller than or equal to a preset angle, the horizontal angle of the evaporator 230 and the downward inclination angle thereof can be smaller than or equal to 7 degrees, the space of the evaporator 230 in the height direction is reduced, the height of the air duct assembly 200 is also reduced, and the space of the refrigeration equipment is increased.

The second inlet 202 is located on the second side of the first cavity 282, the first side is adjacent to the second side, the second inlet 202 and the first inlet 201 have inlet air with different temperatures, and the compartments through which the first inlet 201 and the second inlet 202 are communicated have different ambient temperatures.

The first side is at least one of left and right sides, and the first intake vent 201 and the first drain part 260 are located at least one of left and right sides; the second side is the front side, 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.

When the first compartment 410 is a refrigerating compartment, the second compartment 420 is a freezing compartment, the first air inlet 201 communicated with the refrigerating compartment is arranged on the left side and the right side of the air duct assembly 200, the second air inlet 202 communicated with the freezing compartment is arranged on the front side of the air duct assembly 200, the front end of the second air inlet 202 is shielded by the partition plate component 210, the second air inlet 202 is communicated with the freezing compartment through the lower part of the partition plate component 210, the rear side of the air duct assembly 200 is provided with the fan 270, and the fan 270 discharges air from the air outlet.

The air duct assembly 200 further includes a fan guard 240 disposed between the partition member 210 and the air duct member 220, the fan guard 240 forms a second cavity 281, a fan 270 is disposed in the second cavity 281, the fan guard 240 forms a ventilation opening 244, an inlet of the fan 270 faces the ventilation opening 244, and the fan guard 240 protects the fan 270.

The rotation axis of the fan 270 forms a first angle α with the vertical direction ₁ The size in the height direction occupied by the fan 270 can be reduced. The ventilation opening 244 is positioned above the fan 270 such that the fan 270 is supported by the air duct member 220, and the position above the fan 270 corresponds to the position of the evaporator 230. The central axis of the vent 244 is collinear with the axis of rotation of the fan 270 to ensure that the air in the first cavity 282 is smoothly directed out of the exhaust vent by the fan 270.

The fan guard 240 is configured with a deflector surface 2411 above the fan 270 and facing the fan 270, the deflector surface 2411 sloping upwardly or downwardly along a side facing the drain plate 100, the deflector surface 2411 acting to collect water vapor and drain the collected water from the fan guard 240 side.

The partition member 210, the air duct member 220, the first water discharging member 260, the fan 270, the fan guard 240, the water discharging plate 100, the evaporator 230, and the like may all adopt the structure of the above embodiments, and the description thereof is omitted.

Referring to fig. 1 to 13, the air duct assembly 200 includes a partition member 210, an air duct member 220, a fan 270, an evaporator 230, and a drain plate 100, the partition member 210 and the air duct member 220 form a first cavity 282, a first air inlet 201, a second air inlet 202, and an air outlet, the first air inlet 201 is located on a first side of the first cavity 282, the second air inlet 202 is located on a second side of the first cavity 282, and the first side is adjacent to the second side; the evaporator 230 is disposed in the first chamber 282; the drain plate 100 is located in the first cavity 282; the drain plate 100 is located below the evaporator 230, the drain plate 100 is configured with an opening 170 and an outlet 114, the opening 170 is directed to a first side, and the outlet 114 is directed to a third side; the first drain part 260 is positioned at a first side and is configured with a drain passage communicating with the opening 170 so that water on the drain plate 100 is introduced into the first drain part 260 through the opening 170; the second drain part 290 is located at a third side and is configured with a water guide passage communicating with the outlet 114. The first water discharging part 260 is matched with the second water discharging part 290, so that the air duct assembly 200 can discharge water from different sides, the water discharging path is increased, the defrosting water received by the water discharging plate 100 can be discharged from multiple directions, and the defrosting and water discharging efficiency can be improved.

The duct assembly 200 also includes a fan guard 240 and a fan 270 disposed within the fan guard 240. A second drain 290 is disposed within the fan guard 240 or below the fan guard 240. The fan guard 240 is configured with a vent 244, the axis of rotation of the fan 270 forming a first angle with the vertical, the inlet of the fan 270 facing the vent 244. The fan 270 is mounted transversely to help reduce the height of the duct assembly 200.

The included angle between the evaporator 230 and the horizontal direction is smaller than or equal to a preset angle, the horizontal angle of the evaporator 230 and the downward inclination angle thereof can be smaller than or equal to 7 degrees, the space of the evaporator 230 in the occupied height direction is reduced, the height of the air duct assembly 200 is also reduced, and the space of the refrigeration equipment is increased.

The partition member 210, the air duct member 220, the first water discharging member 260, the second water discharging member 290, the fan 270, the fan guard 240, the water discharging plate 100, the evaporator 230, etc. may adopt the structure of the above embodiments, and the description thereof is omitted.

Referring to fig. 10 to 16, the air duct assembly 200 includes a partition member 210, an air duct member 220, a fan 270, an evaporator 230, and a drain plate 100, wherein the partition member 210 and the air duct member 220 form a first cavity 282, an air inlet and an air outlet, and the evaporator 230 is disposed in the first cavity 282; the drain plate 100 is located in the first cavity 282; the drain plate 100 is positioned below the evaporator 230, the drain plate 100 is configured with a drain portion 110 and a water guide portion, the drain portion 110 is configured with an outlet 114, and the drain portion 110 is recessed with respect to a top surface of the drain plate 100; the water guide part is communicated with the water discharge part 110, the water guide part is recessed relative to the top surface of the water discharge plate 100, and a fifth included angle is formed between the extending direction of the water guide part and the air outlet direction of the first cavity 282; the fan cover 240 forms a ventilation opening 244, a second cavity 281 and a water guide channel, the second cavity 281 is communicated with the first cavity 282 through the ventilation opening 244, and the water guide channel is communicated with the outlet 114; the fan 270 is located in the second cavity 281, a rotation axis of the fan 270 forms a first included angle with the vertical direction, and an inlet of the fan 270 is communicated with the first cavity 282 through the ventilation opening 244. The fan cover 240 used for installing the fan 270 is used for draining water, so that the structure of the air duct assembly 200 is more compact, the number of parts of the air duct assembly 200 is reduced, and the assembly is simpler and more convenient; the fan 270 is transverse and also reduces the height of the air duct assembly 200.

In a direction away from the outlet 114, the water guide passage is inclined downward to guide water through an inclined angle so that the water is rapidly and completely discharged.

The included angle between the evaporator 230 and the horizontal direction is smaller than or equal to a preset angle, the horizontal angle of the evaporator 230 and the downward inclination angle thereof can be smaller than or equal to 7 degrees, the space of the evaporator 230 in the occupied height direction is reduced, the height of the air duct assembly 200 is also reduced, and the space of the refrigeration equipment is increased.

The air duct member 220 and the partition member 210 form an air inlet and an air outlet communicated with the first cavity 282, and the water discharging portion 110 extends along the direction from the air inlet to the air outlet, so that the water at the outlet 114 of the water discharging plate 100 is discharged through the water guiding channel of the fan guard 240.

The air inlets include a first air inlet 201 and a second air inlet 202, the first air inlet 201 and the second air inlet 202 have inlet air with different temperatures, and the first air inlet 201 and the second air inlet 202 are located on different sides of the first cavity 282. The first air inlet 201 is located at a first side of the first cavity 282, the second air inlet 202 is located at a second side of the first cavity 282, the first side is adjacent to the second side, and the first air inlet 201 is located near the front side to provide air from the front end of the air duct assembly 200.

The partition 210, the air duct 220, the first water discharging 260, the second water discharging 290, the fan 270, the fan cover 240, the water discharging plate 100, the evaporator 230, etc. may all adopt the structure of the above embodiments, and the details are not described herein.

Referring to fig. 1 to 38, 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 flow dividing portion, the partition member 210 and the air duct member 220 form a first cavity 282, an air inlet and an air outlet, the evaporator 230 is disposed in the first cavity 282; the drain board 100 is located in the first cavity 282; the drain plate 100 is located below the evaporator 230, and the flow dividing portion is provided at least one of the partition member 210 and the air duct member 220, for guiding a portion of the intake air from the first intake port 201 to flow along a guiding direction of the flow dividing portion. The shunting part has the function of shunting partial inlet air of the first air inlet 201, so that the air quantity of the intersection of the inlet air of the first air inlet 201 and the inlet air of the second air inlet 202 is reduced, frost generated due to different temperatures is reduced, the time of a twice defrosting interval is prolonged, and the power consumption of defrosting is reduced.

The structure of the shunt part can be seen in fig. 21 to 38.

The flow dividing portion is a first concave portion 2121 formed in the separator element 210, the first concave portion 2121 is concave toward the inner side of the separator element 210, the first concave portion 2121 is adapted to guide a portion of the intake air of the first intake vent 201 to flow into the first concave portion 2121, and the first intake vent 201 is located at least one of the left side and the right side of the first cavity 282.

The air duct assembly 200 further comprises an evaporator 230 disposed in the first cavity 282, wherein the evaporator 230 comprises a heat exchange tube 233 and a heat sink 234; the heat dissipation fins 234 include a first heat dissipation fin 2341 and a second heat dissipation fin 2342, the first heat dissipation fin 2341 is connected to the heat exchange pipe 233, and a first heat dissipation part is formed by the plurality of first heat dissipation fins 2341; the second heat sink 2342 is connected to the heat exchange tube 233, the second heat sink 2342 is disposed on at least one side of the first heat sink portion, the shunting portion is a ventilation portion 23421 formed on the second heat sink 2342, a projection of the first heat sink 2341 on the second heat sink 2342 covers the ventilation portion 23421, a projection of the first air inlet 201 on the second heat sink 2342 covers the ventilation portion 23421, the first heat sink 2341 and the second heat sink 2342 both extend along a second side to a third side, and the third side is a side where the air outlet is located. The specific implementation and effect of the ventilation portion 23421 can refer to the above-mentioned embodiment of the evaporator 230, and will not be described herein again.

The included angle between the evaporator 230 and the horizontal direction is smaller than or equal to a preset angle, the horizontal angle of the evaporator 230 and the downward inclination angle thereof can be smaller than or equal to 7 degrees, the space of the evaporator 230 in the height direction is reduced, the height of the air duct assembly 200 is also reduced, and the space of the refrigeration equipment is increased.

The partition member 210, the air duct member 220, the first water discharging member 260, the second water discharging member 290, the fan 270, the fan guard 240, the water discharging plate 100, the evaporator 230, etc. may adopt the structure of the above embodiments, and the description thereof is omitted.

Referring to fig. 1 to 25, an air duct assembly 200 includes a partition 210, an air duct 220, an evaporator 230, and a drain plate 100, wherein the air duct 220 is located below the partition 210, and a first cavity 282, an air inlet, and an air outlet are configured to communicate with the partition 210; the evaporator 230 is disposed in the first cavity 282, and an included angle between the evaporator 230 and the horizontal direction is smaller than or equal to a preset angle; the water draining board 100 is arranged in the first cavity 282, the water draining board 100 is located below the evaporator 230, the water draining board 100 is provided with an outlet 114 and a water guiding part which is recessed relative to the top surface of the water draining board 100, the water guiding part is communicated with the outlet 114, and a fourth included angle is formed between the extending direction of the water guiding part and the direction from the air inlet to the air outlet; the heating member 160 is provided on the surface of the drain board 100. By arranging the evaporator 230 transversely in the air duct assembly 200 and controlling the angle of the evaporator 230 inclined downward with respect to the horizontal direction within a preset angle, the height occupied by the evaporator 230 can be reduced, and the height of the air duct assembly 200 can be reduced by the evaporator 230; the drainage plate 100 is provided with a water guide part, so that the drainage requirement and the air supply heat exchange requirement can be met through the water guide part, and the air in the first cavity 282 is discharged after being fully exchanged heat with the evaporator 230; the water discharge plate 100 having the water guide part is engaged with the evaporator 230, so that the inclination angle of the evaporator 230 can be reduced; the heating member 160 is disposed on the drain plate 100 to save the height occupied by the heating defrosting structure, thereby further reducing the height of the air duct assembly 200.

In combination with the above, the evaporator 230, the drain plate 100, and the heating members 160 cooperate to substantially reduce the height of the duct assembly 200.

The heating member 160 covers the lower surface of the drain plate 100, so that direct contact between the heating member 160 and defrosting water received above the drain plate 100 can be avoided, and potential safety hazards are reduced.

The partition plate 210, the air duct 220, the first water discharging unit 260, the second water discharging unit 290, the fan 270, the fan cover 240, the water discharging plate 100, the heating unit 160, the evaporator 230, and other components may all adopt the structure in the above embodiments, and the details are not repeated herein.

When the air duct assembly 200 in the above embodiment is applied to the cabinet and the refrigeration equipment, the cabinet and the refrigeration equipment have the above advantages.

Embodiments of refrigeration appliances are provided below in conjunction with the above-described air duct assembly.

The refrigeration equipment comprises a cabinet body and an air duct assembly, wherein the air duct assembly is positioned in the cabinet body and is divided into a first chamber and a second chamber, the air duct assembly comprises a partition plate part, an air duct part, an evaporator and a drain plate, the partition plate part and the air duct part limit a first cavity, a first air inlet, a second air inlet, a first air exhaust port and a second air exhaust port, the first air inlet, the first cavity, the first air exhaust port and the first chamber are suitable for being communicated, and the second air inlet, the first cavity, the second air exhaust port and the second chamber are suitable for being communicated; set up evaporimeter and drain bar in the first cavity, air duct component supports the drain bar, and the drain bar is located the below of evaporimeter, and the contained angle of evaporimeter and horizontal plane is less than or equal to and predetermines the angle, or, evaporimeter and horizontal plane parallel. The evaporimeter is horizontal in the wind channel subassembly, and the evaporimeter is steerable within presetting the angle for the angle of horizontal plane downward sloping, or the evaporimeter can the level set up, can reduce the shared high space of evaporimeter, and then reduces the whole height of wind channel subassembly, can reduce the internal space of the shared cabinet of wind channel subassembly, and the internal storing space of cabinet can corresponding increase, can provide the refrigeration plant of a large capacity.

In some cases, the first compartment is located above the second compartment, the first compartment being a refrigerator compartment and the second compartment being a freezer compartment.

The first air inlet is positioned 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 is communicated with the first compartment above the air duct assembly. The second air inlet is positioned at the front side of the air duct assembly and communicated with the second compartment below the air duct assembly.

The drainage plate may have one or more of the above structures, which are specifically referred to above and will not be described herein again. The drainage structure of the air duct assembly may be the drainage method described above, 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 further includes a fan 270, the fan 270 is disposed on one side of the evaporator, and the fan 270 may be disposed horizontally or vertically, as specifically described above with reference to the fan 270. The duct assembly 200 further includes a fan guard, a fan cover 243, etc. for cooperating with the fan, as also described above, and will not be described further herein.

The tank, the partition 210, the air duct 220 and other structures can be referred to above, and are not described herein.

The above embodiments are merely illustrative, and not restrictive, of the present invention. Although the present invention has been described in detail with reference to the embodiments, those skilled in the art should understand that various combinations, modifications or equivalent substitutions may be made to the technical solution of the present invention without departing from the spirit and scope of the technical solution of the present invention, and all of them should be covered by the scope of the claims of the present invention.

Claims (11)

1. An air duct assembly, comprising:

a partition member;

the air duct component is communicated with the partition plate component to define a first cavity, a first air inlet, a second air inlet and an air outlet, the first air inlet is positioned on the first side of the first cavity, the second air inlet is positioned on the second side of the first cavity, and the first side is adjacent to the second side;

at least one of the partition plate component and the air duct component is provided with a partition part, the orthographic projection of the partition part at the first air inlet covers the local area of the first air inlet, the orthographic projection is positioned at one end, close to the second side, of the first air inlet, and a preset interval is arranged between the partition part and the first air inlet.

2. An air duct assembly according to claim 1, wherein the partition member or the air duct member having the partition portion is provided with a guide surface in a direction from the first air inlet to the partition portion, the guide surface is a curved surface, the partition portion is located at a first end of the guide surface and is tangent to the first end, and a second end of the guide surface extends toward a first wall surface that bounds the first air inlet.

3. The air duct assembly of claim 2, wherein the guide surface includes a planar portion and a curved portion, one end of the curved portion being connected to the divider portion, the other end of the curved portion being connected to and tangent to the planar portion, the planar portion extending in a direction toward the first wall.

4. The air duct assembly of claim 1, wherein the air duct component is provided with a second air inlet portion, the second air inlet portion defines the second air inlet, the partition portion is provided at both ends of the second air inlet portion, and the first air inlet is provided at both sides adjacent to the second side.

5. The air duct assembly of claim 1, wherein the air duct component is integrally formed with the partition.

6. The air duct assembly of claim 1, wherein a height of the partition is less than or equal to 1/3;

and/or the height of the partition part is less than or equal to 1/3 of the length of the first air inlet.

7. The air duct assembly according to claim 1, wherein an evaporator is disposed in the first cavity, and the heat sink and the partition of the evaporator both extend along the second air inlet toward the air outlet.

8. The air duct assembly of claim 1, wherein an evaporator is disposed in the first cavity, and an included angle between the evaporator and a horizontal direction is smaller than or equal to a preset angle, or the evaporator and the horizontal direction are parallel.

9. The air duct assembly according to any one of claims 1-8, wherein the air duct component supports a drain plate,

the drain board includes:

a drain part configured with an outlet recessed with respect to a top surface of the drain plate;

the water guide portion, with the water drainage portion intercommunication, for the top surface of drain bar is sunken, the extending direction of water guide portion with the air-out direction of drain bar top forms first contained angle, orientation the direction of water drainage portion, the first direction slope is followed to the bottom of water guide portion, first direction with the top surface of drain bar forms the sixth contained angle.

10. The air duct assembly according to claim 9, wherein the air duct member includes a first support portion and a second insulating layer located above the first support portion, an upper surface of the second insulating layer is fitted to a lower surface of the drain plate, a lower surface of the second insulating layer is configured with a first support slope inclined in the first direction, and the first support portion is configured with a second support slope fitted to the first support slope.

11. Refrigeration equipment, characterized by, including the cabinet body and the air duct assembly of any one of claims 1 to 10, the air duct assembly is arranged in the storage space of the cabinet body and divides a first compartment and a second compartment, the first air inlet is communicated with the first compartment, and the second air inlet is communicated with the second compartment.

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