CN117847910A - Freezing and refrigerating equipment - Google Patents

Abstract

The invention belongs to the technical field of freezing and refrigerating equipment, and particularly provides freezing and refrigerating equipment. The invention aims to solve the problem that a shell structure at an air supply outlet of the existing refrigeration module is easy to deform under the action of the weight of a box module. The refrigeration and freezing equipment comprises a box body module and a refrigerating module, wherein the box body module is limited with a storage compartment, an air supply channel and an air return channel. The refrigeration module comprises a shell, a refrigeration system, a heat dissipation fan and an air supply fan. The junction of posterior lateral plate and roof of casing is provided with the back inclined plane, and the casing has press storehouse, refrigeration room, with return air channel fluid connection's return air inlet and form on the back inclined plane and with air supply channel fluid connection's supply-air outlet. The refrigeration system includes an evaporator disposed within the refrigeration compartment, a compressor disposed within the press housing, and a condenser. The heat dissipation fan is arranged in the press bin. The air supply fan is arranged in the refrigerating compartment. The refrigerating and freezing equipment of the invention overcomes the technical problems.

Description

Freezing and refrigerating equipment

Technical Field

The invention belongs to the technical field of freezing and refrigerating equipment, and particularly provides freezing and refrigerating equipment.

Background

The whole shape, the number of internal compartments and the volume of the internal compartments of the existing refrigerator of the same series are the same, and the refrigerators of different models are often different only in color and the material of the shell. The existing refrigerator cannot meet the demands of wide users due to different families, different decoration styles and different favorites of different users. And manufacturers cannot provide customized refrigerators for users according to the demands of the users. The refrigerator is characterized in that the existing refrigerator generally integrates a refrigerating system on the refrigerator body of the refrigerator, so that manufacturers need to redesign the structure and layout of the refrigerator according to the needs of users, and more molds are needed to be newly opened, so that the production cost of the refrigerator is higher, and the production period is longer.

In order to overcome the above problems, the prior art proposes a modular refrigerator. Specifically, the refrigerator is designed into two independent modules, namely a refrigerator body module and a refrigerating module. The refrigerating module can adapt to various different box modules so as to assemble the refrigerating module and the corresponding box modules together according to the custom-made demands of users.

In order to realize the refrigeration of the refrigeration module to the box module, cold air in the refrigeration module needs to be introduced into the box module. In the conventional design, the air supply port of the cooling module is generally disposed at the top side of the cooling module, but this will cause the following problems. The air supply port of the refrigeration module is easy to deform under the action of the weight of the box body module, the sealing of the air supply port is affected, and even the air supply fan in the box body module can be extruded when serious, so that the shell of the air supply fan deforms, and further the impeller of the air supply fan rubs against the shell of the air supply fan, and noise is increased.

Disclosure of Invention

The invention aims to solve the problem that a shell structure at an air supply outlet of the existing refrigeration module is easy to deform under the action of the weight of a box module.

It is a further object of the present invention to avoid deformation of the housing of the blower in the refrigeration module due to the extrusion by the weight of the housing module.

In order to achieve the above object, the present invention provides a refrigeration and freezing apparatus, which includes a box module and a refrigerating module, wherein the box module defines a storage compartment, an air supply channel communicated with the storage compartment, and an air return channel communicated with the storage compartment; the refrigeration module includes:

the shell is internally provided with a press bin and a refrigeration compartment, the shell is provided with an air return port and an air supply port which are communicated with the refrigeration compartment, the air return port is in fluid connection with the air return channel, and the air supply port is in fluid connection with the air supply channel; a rear inclined plane is arranged at the joint of the rear side plate of the shell and the top plate of the shell, and the air supply outlet is formed on the rear inclined plane;

a refrigeration system including a compressor and a condenser disposed within the press bin, the refrigeration system further including an evaporator disposed within the refrigeration compartment;

A heat dissipation fan disposed within the press bin;

and the air supply fan is arranged in the refrigerating compartment.

Optionally, an upper inclined plane matched with the rear inclined plane is arranged on the box module, an air inlet of the air supply channel is formed on the upper inclined plane, and the upper inclined plane is abutted with the rear inclined plane so as to enable the air supply port and the air inlet to be opposite to each other; the box module is further provided with a bottom surface matched with the top surface of the top plate of the shell, which is positioned on the front side of the rear inclined surface, and the bottom surface is abutted to the top surface.

Optionally, the bottom surface of the case module and the top surface of the housing are both disposed horizontally.

Optionally, in a state that the bottom surface is abutted against the top surface, a gap is formed between the upper inclined surface and the rear inclined surface; at least one of the upper inclined surface and the rear inclined surface is attached with a compressible gasket so that the gasket fills the gap and the upper inclined surface and the rear inclined surface are abutted together by the gasket.

Optionally, the air supply port is arranged in the center of the rear inclined plane; and/or the air supply port is a rectangular opening extending transversely.

Optionally, the air supply fan comprises an air outlet part with a fan outlet, and the air outlet part and a side plate where the rear inclined plane is located are connected together in a sealing mode through a sealing component, so that cold air blown out from the fan outlet completely flows through the air supply opening.

Optionally, the sealing member is a sealing cotton; and/or a part of the air outlet part is embedded into the air supply outlet.

Optionally, the side plate where the rear inclined plane is located is provided with at least one reinforcing rib.

Optionally, the reinforcing ribs are arranged on the inner side of the side plate where the rear inclined surface is located at least one part of the circumferential edge of the air supply port.

Optionally, the refrigeration appliance is a refrigerator.

Based on the foregoing description, it can be understood by those skilled in the art that in the foregoing technical solution of the present invention, by setting the joint between the rear side plate and the top plate of the refrigeration module housing as a rear inclined plane, and forming the air supply opening on the rear inclined plane, the air outlet direction of the air supply opening is ensured to be upward, and meanwhile, the sealing at the air supply opening is changed from the sealing in the existing horizontal mode to the sealing in the inclined mode, so that the sealing at the air supply opening can be realized by extruding the rear inclined plane of the box module in the horizontal direction. Therefore, the refrigeration and freezing equipment can effectively avoid the deformation of the air supply port of the shell due to the gravity of the box body module.

At the same time, the rear inclined surface enables the box module to move forward from the rear side of the refrigeration module while ensuring that the air supply opening thereon is sealed, and thus is mounted together with the refrigeration module. Meanwhile, the rear inclined plane can also play a role in guiding and limiting the box module in the up-down direction in the process that the box module moves forwards from back to back so as to ensure that an air inlet on the box module is opposite to an air supply outlet on the refrigerating module.

Further, through the top surface butt on making the bottom surface on the box module and the refrigerating module to consequently make the refrigerating module bear the weight of the whole of box module through its top surface, avoided the weight of box module to press on the back inclined plane, thereby ensured that the supply-air outlet department of casing can not take place deformation, and then ensured that the casing of air supply fan can not appear because of receiving the extrusion of box module gravity and the situation of deformation.

The above, as well as additional objectives, advantages, and features of the present invention will become apparent to those skilled in the art from the following detailed description of a specific embodiment of the present invention when read in conjunction with the accompanying drawings.

Drawings

In order to more clearly illustrate the technical solution of the present invention, some embodiments of the present invention will be described hereinafter with reference to the accompanying drawings. It will be understood by those skilled in the art that components or portions thereof identified in different drawings by the same reference numerals are identical or similar; the drawings of the invention are not necessarily to scale relative to each other.

In the accompanying drawings:

FIG. 1 is an isometric view of a refrigeration unit (door not shown) in accordance with some embodiments of the present invention;

FIG. 2 is a cross-sectional view of the ice-cold storage device of FIG. 1 taken along the direction A-A;

FIG. 3 is a side view of a tank module (not shown in the housing) of the ice-cold storage device of FIG. 1;

FIG. 4 is a right front upper isometric view of the tank module of FIG. 3;

FIG. 5 is a left front upper isometric view of the bottom of the tank module of FIG. 3;

FIG. 6 is a right front upper isometric view of the refrigeration module of the ice refrigeration apparatus of FIGS. 1 and 2;

FIG. 7 is a schematic diagram of the internal construction of a refrigeration module according to some embodiments of the invention;

FIG. 8 is a schematic view of the main space defined by the housing of the refrigeration module of FIG. 6 (front left upper isometric view);

fig. 9 is a schematic view of the main space defined by the housing of the refrigeration module of fig. 6 (front right upper isometric view);

FIG. 10 is a left rear upper isometric view of a refrigeration module in some embodiments of the invention;

FIG. 11 is an isometric cross-sectional view of the refrigeration module of FIG. 10 taken along the direction B-B;

FIG. 12 is a plan cross-sectional view of the refrigeration module of FIG. 10 taken along the direction B-B;

FIG. 13 is a left front lower isometric view of a refrigeration module in some embodiments of the invention;

figure 14 is an isometric cross-sectional view of the refrigeration module of figure 12 taken along the direction C-C;

Figure 15 is an isometric cross-sectional view of the refrigeration module of figure 12 taken along direction D-D;

FIG. 16 is a plan cross-sectional view of the refrigeration module of FIG. 12 taken along the direction D-D;

FIG. 17 is an isometric view of a blower fan in some embodiments of the invention;

fig. 18 is a cross-sectional view of a housing of the refrigeration module of fig. 10-16;

figure 19 is an isometric cross-sectional view of the refrigeration module of figure 16 taken along the direction E-E;

FIG. 20 is a front view of a refrigeration module in some embodiments of the invention;

FIG. 21 is a first isometric view of an air guide member of the refrigeration module of FIG. 16;

fig. 22 is a second isometric view of an air guide member of the refrigeration module of fig. 16.

Detailed Description

It should be understood by those skilled in the art that the embodiments described below are only some embodiments of the present invention, but not all embodiments of the present invention, and the some embodiments are intended to explain the technical principles of the present invention and are not intended to limit the scope of the present invention. All other embodiments, which can be obtained by a person skilled in the art without any inventive effort, based on the embodiments provided by the present invention, shall still fall within the scope of protection of the present invention.

It should be noted that, in the description of the present invention, terms such as "center", "upper", "lower", "top", "bottom", "left", "right", "vertical", "horizontal", "inner", "outer", and the like indicate directions or positional relationships, which are based on the directions or positional relationships shown in the drawings, are merely for convenience of description, and do not indicate or imply that devices or elements must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting 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.

Further, it should also be noted that, in the description of the present invention, unless explicitly specified and limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; can be directly connected, can be indirectly connected through an intermediate medium, and can also be communicated with the inside of two elements. The specific meaning of the above terms in the present invention can be understood by those skilled in the art according to the specific circumstances.

In addition, it should be noted that, in the description of the present invention, the terms "cooling capacity" and "heating capacity" are two descriptions of the same physical state. That is, the higher the "cooling capacity" of a certain object (for example, evaporator, air, condenser, etc.), the lower the "heat" of the object, and the lower the "cooling capacity" of the object, the higher the "heat" of the object. Some object absorbs the cold and releases the heat, and the object releases the cold and absorbs the heat. A target maintains "cold" or "heat" to maintain the target at a current temperature. "refrigeration" and "heat absorption" are two descriptions of the same physical phenomenon, i.e., a target (e.g., an evaporator) absorbs heat while it is refrigerating.

In the present invention, the refrigerating and freezing apparatus may have both the refrigerating function and the freezing function, may have only the refrigerating function, and may have only the freezing function. The freezing and refrigerating device may be a refrigerator, freezer or ice chest.

As shown in fig. 1 and 2, in some embodiments of the present invention, a refrigerator-freezer includes a cabinet module 100 and a refrigeration module 200. The refrigeration module 200 serves to receive gas from the tank module 100, cool the received gas, and then supply the cooled gas to the tank module 100.

In the manufacturing process, the tank module 100 and the refrigeration module 200 may be manufactured separately and then assembled and fixed together.

As shown in fig. 1 and 2, in some embodiments of the present invention, the case module 100 defines a storage compartment 101, and the storage compartment 101 is configured to receive cold air from the cooling module 200 to cool food materials therein. Further, the storage compartment 101 includes a first storage compartment 1011 and a second storage compartment 1012.

In some embodiments of the invention, the first storage compartment 1011 is a refrigerated compartment and the second storage compartment 1012 is a freezer compartment.

In addition, in other embodiments of the present invention, one skilled in the art may set the first storage compartment 1011 as a freezer compartment and the second storage compartment 1012 as a refrigerator compartment as desired; alternatively, the first storage compartment 1011 and the second storage compartment 1012 are all provided as a freezing compartment or a refrigerating compartment; alternatively, at least one of the first storage compartment 1011 and the second storage compartment 1012 may be provided as a temperature changing compartment.

As shown in fig. 2, a first air outlet 10111 is provided on a side wall of the first storage room 1011, so that air in the first storage room 1011 flows to the refrigeration module 200 through the first air outlet 10111. Air within the second storage compartment 1012 flows from the opening of the second storage compartment 1012 to the refrigeration module 200.

Further, although not shown, in some embodiments of the invention, the case module 100 further includes a first door corresponding to the first storage compartment 1011 and a second door corresponding to the second storage compartment 1012. The first door is used for shielding the first storage room 1011 to prevent external air from entering the first storage room 1011. The second door is used for shielding the second storage compartment 1012 to prevent external air from entering the second storage compartment 1012; the second door also serves to shield the top of the refrigeration module 200, and in particular, the front return 21021 of the refrigeration module 200 (as shown in fig. 6). Further, the inner side of the second door is provided with a sink having a portion aligned with and communicating with the second storage compartment 1012 and a portion aligned with and communicating with the front return air inlet 21021 of the refrigeration module 200, so that air in the second storage compartment 1012 flows to the refrigeration module 200 through the sink.

Furthermore, in other embodiments of the present invention, a person skilled in the art may also provide a channel on the second door, as desired, with one end of the channel aligned with and in communication with the second storage compartment 1012, and the other end of the channel aligned with and in communication with the front return air inlet 21021 of the refrigeration module 200.

As shown in fig. 2-5, in some embodiments of the present invention, the tank module 100 includes a first liner 110, a second liner 120, an air supply line 130, and an air return line 140 disposed within its housing (not labeled). Wherein, a first storage compartment 1011 is formed in the first liner 110, and a second storage compartment 1012 is formed in the second liner 120. In other words, the first storage compartment 1011 is defined by the first liner 110, and the second storage compartment 1012 is defined by the second liner 120. An air supply channel 1301 is defined in the air supply pipe 130, and the air supply channel 1301 is respectively communicated with the first storage compartment 1011 and the second storage compartment 1012, so that the box module 100 receives cold air from the refrigeration module 200 through the air supply channel 1301 and delivers the cold air to the first storage compartment 1011 and the second storage compartment 1012.

As shown in fig. 4 and 5, a first return air channel 1401 (shown by a dotted line in fig. 4) is formed in the return air duct 140, and a top end of the first return air channel 1401 is communicated with a first air outlet 10111, or the first air outlet 10111 forms an inlet of the first return air channel 1401; the bottom end of the first return air channel 1401 is provided with an air outlet 14011 which is in butt joint with the refrigeration module 200, so that the box module 100 can convey the air in the first storage compartment 1011 to the refrigeration module 200 through the first return air channel 1401.

As can be seen from fig. 2 to 4, the supply duct 130 and the return duct 140 are arranged in a vertical direction as a whole to reduce wind resistance. And the air supply duct 130 includes a portion located in the first liner 110 and a portion located in the second liner 120.

Furthermore, in other embodiments of the present invention, the blower line 130 and/or the return line 140 may be angled as desired by one skilled in the art. And, the blower duct 130 may be provided outside the first and second liners 110 and 120 as required by those skilled in the art.

Furthermore, in still other embodiments of the present invention, one skilled in the art may arrange the storage compartments 101 in any other feasible number, such as one, three, five, six, etc., as desired. Those skilled in the art may also include other numbers of bladders, such as one, three, four, etc., as desired. For example, the housing module 100 may include only one liner and the liner may define one or more storage compartments. When the liner defines only one storage compartment, the storage compartment may be configured to deliver air therein to the refrigeration module 200 in the manner of the first storage compartment 1011 or the second storage compartment 1012 as described above. When the liner defines a plurality of storage compartments, the bottom storage compartment delivers air therein to the refrigeration module 200 in the manner of the second storage compartment 1012 as described above; the other storage compartments adopt the first storage compartment 1011 as described above to convey the air therein to the refrigeration module 200, and each storage compartment may correspond to one return air duct 140 (each return air duct 140 corresponds to one side return air port 21022 (as shown in fig. 6), or may share one return air duct 140.

As shown in fig. 4, in some embodiments of the present invention, the tank module 100 further defines a receiving chamber 102 at a bottom thereof, the receiving chamber 102 for receiving the refrigeration module 200. The receiving chamber 102 has a front opening (not shown) and a bottom opening (not shown) for moving the case module 100 from the rear side of the refrigerating module 200 to above the refrigerating module 200 so as to fix the case module 100 and the refrigerating module 200 together after the case module 100 is moved to a position matched with the refrigerating module 200.

As shown in fig. 6 and 7, in some embodiments of the present invention, the refrigeration module 200 includes a housing 210, and the refrigeration module 200 further includes a refrigeration system 220, a heat dissipation fan 230, a blower fan 240, and an evaporation pan 250 within the housing 210.

As shown in fig. 6, the casing 210 is provided with an air supply port 2101 and an air return port 2102. Wherein return air inlet 2102 includes a front return air inlet 21021 and a side return air inlet 21022.

As shown in fig. 2, in the assembled state of the refrigerating apparatus, the air supply port 2101 is abutted with the air supply pipeline 130 on the box module 100, so that the refrigerating module 200 supplies air to the air supply pipeline 130 through the air supply port 2101, and the air supply pipeline 130 supplies the cold air received by the air supply pipeline to the storage compartment 101.

As shown in fig. 2 and 3, in the assembled state of the refrigerator, the front return air inlet 21021 and the second storage compartment 1012 are both positioned on the front side of the refrigerator, and both are communicated through a sink or channel formed on the second door (as described above) such that the refrigeration module 200 receives air from the second storage compartment 1012 through the front return air inlet 21021. The side return 21022 interfaces with the return air duct 140 on the cabinet module 100 such that the refrigeration module 200 receives air from the first storage compartment 1011 through the side return 21022.

As shown in fig. 7-9, in some embodiments of the invention, a press bin 2103, a refrigeration compartment 2104, a heat dissipation air intake channel 2105, and a heat dissipation air outlet channel 2106 are defined within the housing 210. Wherein the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 are respectively communicated with the press bin 2103 and respectively extend from the press bin 2103 to the front end of the shell 210.

It should be noted that, for the sake of understanding by those skilled in the art, fig. 8 and fig. 9 schematically show the relative positional relationship and distribution of four spaces of the press cabin 2103, the refrigeration compartment 2104, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106.

As can be readily seen from fig. 8 and 9, the press bin 2103, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 are all located below the refrigerating compartment 2104, and the outer contour of the projections of the press bin 2103, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 on the horizontal plane is located outside the projections of the refrigerating compartment 2104 on the horizontal plane. In other words, if the press house 2103, the heat dissipation air intake passage 2105 and the heat dissipation air outlet passage 2106 are regarded as one whole, the projection of the refrigerating compartment 2104 on the horizontal plane is located inside the projection on the one whole horizontal plane.

As shown in fig. 8 and 9, the supply-air port 2101, the front return port 21021 and the side return port 21022 are respectively communicated with the refrigerating compartment 2104. Wherein the supply-air port 2101 is located at the rear upper side of the refrigerating compartment 2104, the front return air port 21021 is located at the front upper side of the refrigerating compartment 2104, and the side return air port 21022 is located at the side upper side of the refrigerating compartment 2104.

As shown in fig. 7, in some embodiments of the invention, the refrigeration system 220 includes a compressor 221, a high temperature line 222, a condenser 223, a dry filter 224, a capillary tube 225, an evaporator 226, and an air return 227, which are connected end to end in sequence and thus form a closed loop.

As shown in fig. 7, 10 to 12, the compressor 221, the condenser 223 and the dry filter 224 are all disposed in the press housing 2103, the high-temperature pipeline 222 is distributed in the press housing 2103 and the heat radiation air outlet passage 2106, and the evaporator 226 is disposed in the refrigerating compartment 2104. Most of the tube sections of the capillary tube 225 and the return air tube 227 are located outside the press bin 2103 and the refrigeration compartment 2104. Alternatively, one skilled in the art may also dispose all of the capillaries 225 and/or the return air tubes 227 outside of the press bin 2103 and refrigeration compartment 2104 as desired.

As shown in fig. 7 and 14 to 19, the heat radiation fan 230 is disposed in the press housing 2103, the air supply fan 240 is disposed in the cooling compartment 2104, and the evaporation pan 250 is disposed in the heat radiation air outlet passage 2106. At least a portion of the high temperature conduit 222 located within the heat dissipation air outlet channel 2106 is located within the evaporation pan 250 such that the high temperature conduit 222 is capable of heating water within the evaporation pan 250 to facilitate evaporation of the water.

As shown in fig. 14 to 19, in some embodiments of the present invention, a lateral gap 21071 is formed between the top plate of each of the press bin 2103, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 and the bottom plate of the refrigeration compartment 2104, and the lateral gap 21071 is filled with a thermal insulation material (such as a foaming agent or thermal insulation cotton). A front gap 21072 is formed between the bottom of the front plate of the refrigerating compartment 2104 and the outer plate of the casing 210 adjacent thereto, and the front gap 21072 is filled with a heat insulating material (e.g., a foaming agent or heat insulating cotton). A longitudinal gap 21073 is formed between the left and right side plates of the refrigerating compartment 2104 and the outer side plates of the respective adjacent housings 210, and the longitudinal gap 21073 is filled with a heat insulating material (e.g., a foaming agent or heat insulating cotton). Those skilled in the art will appreciate that the insulating material outside the refrigerated compartment 2104 is effective to insulate the refrigerated compartment 2104 from cold leakage.

Further, the top plates of the press bin 2103, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 are parallel to the bottom plate of the refrigeration compartment 2104, so that the heat insulation materials in the transverse gap 21071, the front gap 21072 and the longitudinal gap 21073 are uniformly filled with the heat insulation materials with the same thickness, and the refrigeration compartment 2104 is uniformly insulated.

Optionally, the portions of the capillary tube 225 and the air return tube 227 outside the press bin 2103 and the refrigeration compartment 2104 are disposed in the longitudinal gap 21073 and are surrounded by insulation. Preferably, capillary tube 225 and return air tube 227 abut to allow the two to exchange heat. Further, since the temperature of the heat dissipation air intake passage 2105 is lower than the temperature of the heat dissipation air output passage 2106, the capillary tube 225 and the air return tube 227 are preferably arranged in one of the two longitudinal gaps 21073 close to the heat dissipation air intake passage 2105.

As shown in fig. 15 and 16, the refrigeration module 200 further includes a platen 260 disposed between the evaporator 226 and the ceiling of the refrigeration compartment 2104, the platen 260 being used to compress the evaporator 226 against the floor of the refrigeration compartment 2104, thereby securing the evaporator 226 obliquely within the refrigeration compartment 2104.

In some embodiments of the present invention, the evaporator 226 is disposed obliquely upward in a front-to-rear direction, and the included angle of the evaporator 226 with the horizontal plane ranges from 8 ° to 45 °, such as 8 °, 12 °, 15 °, 20 °, 30 °, 45 °, and so on.

Furthermore, in other embodiments of the present invention, the evaporator 226 may be placed horizontally, as desired, with the projected area of the evaporator 226 on a horizontal plane being larger than the projected area of the evaporator on a vertical plane.

With continued reference to fig. 15 and 16, in some embodiments of the invention, the floor of the refrigerated compartment 2104 is provided with a drain hole 2108 below the front of the evaporator 226. The refrigeration module 200 further includes a drain pipe 270 communicating with the drain hole 2108 and extending from above down into the evaporation pan 250 so that the drain pipe 270 can rapidly drain the defrost water in the refrigeration compartment 2104 into the evaporation pan 250.

With continued reference to fig. 15 and 16, the blower fan 240 is located between the evaporator 226 and the air supply port 2101 in the air flow path, and both the evaporator 226 and the blower fan 240 are disposed obliquely within the refrigeration compartment 2104.

As shown in fig. 15, the floor of the refrigerating compartment 2104 includes, on the rear side of the drain hole 2108, an evaporator support section 21041 and a blower support section 21042 extending obliquely rearward and upward, and the inclination angle of the blower support section 21042 is larger than that of the evaporator support section 21041 so that the inclination angle of the blower 240 is larger than that of the evaporator 226.

As shown in fig. 17, the blower fan 240 is preferably a centrifugal fan, and includes a housing 241 and an impeller 242 mounted within the housing 241. Wherein, the distance between the position on the top surface of the shell 241 aligned with the rotation axis of the impeller 242 and the top plate of the refrigerating chamber 2104 is not less than 30 mm, so as to reduce the wind resistance when the centrifugal fan sucks air. Wherein the pitch is a distance in the direction in which the axis of the impeller extends.

As shown in fig. 15 to 17, the casing 241 of the blower fan 240 includes an air outlet portion 2411, and the air outlet portion 2411 has a fan outlet 24111. The portion of the air outlet 2411 adjacent to the fan outlet 24111 is embedded in the air supply port 2101.

Further, although not shown, in some embodiments of the present invention, a sealing member is provided between the side plate of the housing 210 where the air supply port 2101 is located and the air outlet portion 2411, so that the two are connected in a sealing manner, so that all the cool air blown out from the fan outlet 24111 flows through the air supply port 2101. The sealing member may be any available member, and for example, there is an annular structure made of any material such as sealing cotton, foam cotton, foaming agent, rubber, etc.

In addition, the blower fan 240 may be any other possible fan, such as a cross-flow fan, an axial flow fan, etc., as desired by those skilled in the art.

Returning to fig. 6, in some embodiments of the present invention, the top of the front side plate of the housing 210 has an inwardly recessed structure 211, the bottom wall of the recessed structure 211 is inclined from bottom to top to back, and the front return air inlet 21021 is formed on the bottom wall of the recessed structure 211. Preferably, the front return air inlet 21021 is a laterally extending strip-shaped opening.

Optionally, a spoiler (not labeled in the figure) is provided on the front side plate of the housing 210, and the spoiler is inclined backward from top to bottom from the top end of the front return air inlet 21021.

As shown in fig. 6, 10 and 19, the junction between the left side plate of the housing 210 and the top plate of the housing 210, and the junction between the right side plate of the housing 210 and the top plate of the housing 210 are each provided as a side slope 212. The side return air inlet 21022 is formed on the side slope 212 on the right side of the housing 210 and is located at the front of the housing 210.

Correspondingly, the outlet end of the return air duct 140 of the tank module 100 is also inclined such that the outlet end of the return air duct 140 is parallel to the right side incline 212 of the housing 210.

As will be appreciated by those skilled in the art, by changing the edges of the refrigeration module 200 that are in contact with the tank module 100 on the left and right sides to a surface (i.e., the side bevel 212), the contact area of the wire joint where the surface contacts the opposite edge is larger, the pressure is smaller, and the deformation is less likely to occur. Meanwhile, the side inclined surface 212, the left side plate or the right side plate of the shell 210 and the top plate of the shell 210 together form a triangular structure, so that the structure corresponding to the side inclined surface 212 on the shell 210 is more stable and is less prone to deformation.

As shown in fig. 20, the angle between the side slope 212 and the horizontal (dashed line in fig. 20) is denoted as α. Preferably, the α > 45 ° to reduce the component force that the side slope 212 receives in the vertical direction. The force is the weight of the food material within the tank module 100.

Returning to fig. 6, 10 and 19, the side return air inlet 21022 is configured as a strip-shaped opening extending in a front-to-back direction to ensure that the side return air inlet 21022 has a sufficiently large flow area. Further, the minimum distance between the edge of the side return 21022 and the edge of the side slope 212 is not less than 1mm. That is, the minimum distance between the top side edge of the side return 21022 and the top side edge of the side slope 212, the minimum distance between the bottom side edge of the side return 21022 and the bottom side edge of the side slope 212, the minimum distance between the front side edge of the side return 21022 and the front side edge of the side slope 212, and the minimum distance between the rear side edge of the side return 21022 and the rear side edge of the side slope 212 are all no less than 1mm to ensure that the side return 21022 is enclosed and sealed in the circumferential direction of the side return 21022 when the outlet end of the return duct 140 on the tank module 100 abuts the side slope 212 on the right side of the housing 210. The minimum distance may be any feasible size of 1mm, 3mm, 8mm, etc.

Further, although not shown in the drawings, a gasket is attached to the side slope 212 having the side return air port 21022 (i.e., the side slope 212 on the right side of the refrigeration module 200) so that the side slope 212 is sealingly abutted with the tank module 100 through the gasket. Optionally, a gasket is also attached to the other side bevel 212 to make the two side bevels 212 equal in height, ensuring that the tank module 100 does not tilt to the left or right. In addition, one skilled in the art may also attach gaskets to the tank module 100 at locations corresponding to the side ramps 212 as desired; alternatively, gaskets are attached to the case module 100 and the refrigeration module 200, respectively.

In the present invention, the gasket may be any viable sealing structure having a sealing effect and capable of being deformed, such as a rubber pad, foam, silica gel pad, or the like.

Furthermore, in other embodiments of the present invention, the side return 21022 may be disposed in the middle or rear of the housing 210 as desired by one skilled in the art; and the side return air inlet 21022 is formed on the side inclined surface 212 on the left side of the casing 210 as required, and the first air outlet 10111 and the return air duct 140 on the tank module 100 are arranged on the left side of the tank module 100.

In still other embodiments of the present invention, it is also possible for those skilled in the art to provide the side return air inlet 21022 on the left side inclined surface 212 and the side return air inlet 212 on the right side of the housing 210, respectively, and the first air outlet 10111 and the return air duct 140 on the left and right sides of the cabinet module 100, respectively, as desired. Optionally, the two first air outlets 10111 and the two air return lines 140 correspond to the same storage compartment, or each first air outlet 10111 and each air return line 140 respectively correspond to one storage compartment.

In still other embodiments of the present invention, one skilled in the art may provide only one of the junction between the top plate of the housing 210 and the left side plate and the junction between the top plate of the housing 210 and the right side plate with the side slope 212 and provide the side return 21022 on the side slope 212 as desired.

As shown in fig. 19-22, in some embodiments of the invention, the housing 210 further includes a wind-guiding member 280, the wind-guiding member 280 being configured to communicate the side return 21022 with the refrigerated compartment 2104. Specifically, the air guide members 280 extend through the longitudinal gap 21073, and the air outlet ends of the air guide members 280 extend to the front side of the evaporator 226.

In some embodiments of the invention, the side return air inlet 21022 may be in communication with the air inlet end of the air guide member 280 or may be formed on the air inlet end of the air guide member 280.

As shown in fig. 21 and 22, the air guide member 280 includes a lateral opening portion 281 and a longitudinal opening portion 282, and an air intake opening is provided at the top of the lateral opening portion 281, and the opening direction of the air intake opening is inclined upward in the lateral direction (the left-right direction of the refrigeration module 200). The air inlet is also provided as a rectangular or strip-shaped opening extending in the front-rear direction. An air outlet is provided at one side of the longitudinal opening 282 in the lateral direction, and is provided as a rectangular opening or a strip-shaped opening extending in the vertical direction. The air outlet of the air guide 280 extends to the front side of the evaporator 226 so that the air flow blown out of the air guide 280 is entirely blown toward the front side of the evaporator 226.

As shown in fig. 6, 10, 14, 15 and 19, a rear inclined surface 213 is provided at a junction of the rear side plate of the housing 210 and the top plate of the housing 210, the air supply port 2101 is formed in the center of the rear inclined surface 213, and the air supply port 2101 is a rectangular opening extending laterally. In addition, the air supply port 2101 may be arranged at other positions on the rear inclined surface 213 and in any other possible structure as required by those skilled in the art. For example, the air supply port 2101 is provided at the left or right side of the rear inclined surface 213, and the air supply port 2101 is provided as an elliptical opening, a circular opening, or a square opening.

As shown in fig. 6, 10 and 18, the top plate of the housing 210 also has a top surface 214 on the front side of the rear inclined surface 213. Preferably, the top surface 214 is horizontally disposed.

As shown in fig. 5, the box module 100 is provided with an upper inclined surface 151 (located at the rear upper side of the accommodating cavity 102) adapted to the rear inclined surface 213, and an air inlet 13011 of the air supply channel 1301 is formed on the upper inclined surface 151, and the upper inclined surface 151 abuts against the rear inclined surface 213 so that the air supply port 2101 and the air inlet 13011 are abutted together. Further, the bottom surface 152 (top wall of the accommodating cavity 102) adapted to the top surface 214 is further disposed on the box module 100, and the top surface 214 is abutted to the bottom surface 152, so that the refrigeration module 200 bears all the gravity of the box module 100 through the top surface 214, the weight of the box module 100 is prevented from being pressed onto the rear inclined surface 213, the edge of the air supply port 2101 is prevented from being deformed, and the sealing between the air supply port 2101 and the air inlet 13011 is ensured.

Further, although not explicitly shown, a gap is formed between the upper inclined surface 151 and the rear inclined surface 213 in a state where the bottom surface 152 is in contact with the top surface 214. And at least one of the upper inclined surface 151 and the rear inclined surface 213 is attached with a gasket that can be compressed such that the gasket fills the gap and is pressed by the upper inclined surface 151 and the rear inclined surface 213, thereby abutting the upper inclined surface 151 and the rear inclined surface 213 together by means of the gasket.

As will be appreciated by those skilled in the art, by changing the edge of the rear side of the refrigeration module 200 abutting against the tank module 100 to a surface (i.e. the rear inclined surface 213), the contact area of the line where the surface contacts the opposite edge is larger, the pressure is smaller, and the deformation is less likely to occur. Meanwhile, the rear inclined plane 213, the rear side plate of the housing 210 and the top plate of the housing 210 together form a triangle structure, so that the structure corresponding to the rear inclined plane 213 on the housing 210 is more stable and is less prone to deformation.

In some embodiments of the present invention, the included angle between the rear inclined plane 213 and the horizontal plane is smaller than 45 °, so as to avoid the weight of the box module 100 pressing on the rear inclined plane 213, thereby reducing the pressure of the air blower 240 in the refrigeration module 200 in the vertical direction, and preventing the case 241 of the air blower 240 from deforming; and the air-sending port 2101 can blow the air flow obliquely upward, and the air flow is upward as much as possible.

Further, as shown in fig. 18, at least one reinforcing rib 2131 is provided on the side plate where the rear inclined surface 213 is located, and the reinforcing rib 2131 serves to reinforce the structural strength at the edge of the air supply port 2101. Preferably, the reinforcing rib 2131 is provided at least at a part of the circumferential edge of the air outlet 2101 on the inner side of the side plate where the rear inclined surface 213 is located. Specifically, the left, right, and rear sides of the air supply port 2101 are provided with reinforcing ribs 2131, respectively, and the reinforcing ribs 2131 at the three positions are in contact with each other and respectively abut against the bottom wall of the refrigerating compartment 2104. The bottom surfaces of the ribs 2131 located on the left and right sides of the air blowing port 2101 are inclined downward from the rear to the front to ensure contact with the bottom wall of the refrigerating compartment 2104.

It will be appreciated by those skilled in the art that the reinforcing ribs 2131 at the edge of the air supply port 2101 can support the structure at the edge of the air supply port 2101 in the vertical direction, so that the rear inclined plane 213 can have enough supporting force when being pressed by the gravity of the box module 100, and further avoid deformation. Thereby ensuring that the casing 241 of the blower fan 240 is not compressed and deformed.

As shown in fig. 11 and 12, in the left-right direction of the refrigeration module 200, the compressor 221, the heat radiation fan 230, and the condenser 223 are sequentially arranged between the heat radiation air outlet passage 2106 and the heat radiation air inlet passage 2105, and the heat radiation fan 230 and the condenser 223 are disposed in close proximity to reduce the size in the lateral direction of the refrigeration module 200.

Optionally, the refrigeration module 200 further includes a fixed housing 201 disposed within the press bin 2103, and the heat dissipation fan 230 and the condenser 223 are fixedly connected to the fixed housing 201. Further alternatively, at least a part of at least one of the heat radiation fan 230 and the condenser 223 is embedded in the stationary case 201. Preferably, at least a portion of each of the heat radiation fan 230 and the condenser 223 is embedded in the fixing case 201 such that the air flow passing through the heat radiation fan 230 entirely passes through the condenser 223, thereby improving the heat radiation efficiency of the heat radiation fan 230 to the condenser 223.

As can be seen in fig. 11 and 13, the bottom plates of the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 are respectively provided with a gap between the bottom plates and a bearing surface (such as a ground or a floor).

As shown in fig. 11 to 14, the heat dissipation air intake passage 2105 includes a plurality of front air intake openings 21051 formed on a front side plate of the housing 210 so that outside air can enter the heat dissipation air intake passage 2105 from the plurality of front air intake openings 21051. Further, the heat dissipation air intake passage 2105 further includes a plurality of bottom side air inlets 21052 formed on a bottom plate of the heat dissipation air intake passage 2105 so that outside air can enter the heat dissipation air intake passage 2105 through gaps below the heat dissipation air intake passage 2105 and the plurality of bottom side air inlets 21052.

As will be appreciated by those skilled in the art, since the heat dissipation air intake duct 2105 has both the plurality of front air inlets 21051 located at the front side thereof and the plurality of bottom air inlets 21052 located at the bottom side thereof, the air intake capability of the heat dissipation air intake duct 2105 is improved and the wind resistance is reduced. Not only avoiding the unsmooth air intake caused by the limitation of the area of the front side plate of the heat dissipation air intake channel 2105 when the heat dissipation air intake channel 2105 is only provided with a plurality of front air intakes 21051; it is also avoided that the heat dissipation air intake channel 2105 has only a plurality of bottom side air intake holes 21052, and impurities such as dust, flock and the like accumulate at the bottom side air intake holes 21052, so that the bottom side air intake holes 21052 are blocked, and further, the heat dissipation air intake channel 2105 cannot obtain enough air.

With continued reference to fig. 11 to 14, the heat dissipation air outlet channel 2106 includes a plurality of front air outlets 21061 formed on a front side plate of the housing 210 so that the hot air in the heat dissipation air inlet channel 2105 can flow out from the plurality of front air outlets 21061 to the outside. Optionally, the heat dissipation air outlet channel 2106 includes a plurality of bottom side air outlets (not shown) formed in a bottom plate thereof.

As shown in fig. 13, the housing 210 further includes a wind deflector 215 provided at the bottom side of the bottom plate of the press magazine 2103, the wind deflector 215 serving to prevent the bottom side air intake 21052 from sucking in the hot air blown out from the front air outlet 21061.

With continued reference to fig. 11-13, the bottom plate of the press bin 2103 is provided with a plurality of bin bottom air inlets 21031 on the windward side of the condenser 223, and the bottom plate of the press bin 2103 is provided with a plurality of bin bottom air outlets 21032 on the side of the heat dissipation fan 230 away from the condenser 223. And the plurality of bottom side air inlets 21052 and the plurality of bin bottom air inlets 21031 are positioned on one side of the wind deflector 215 and the plurality of bin bottom air outlets 21032 are positioned on the other side of the wind deflector 215. Based on this, it will be appreciated by those skilled in the art that ambient air can also enter the press cabin 2103 through the cabin bottom air inlet 21031, and that a portion of the hot air in the press cabin 2103 will flow from the cabin bottom air outlet 21032 to the ambient.

As can be seen in fig. 11-13, in some embodiments of the invention, a portion of the plurality of bin bottom outlets 21032 is located below the compressor 221 and another portion of the plurality of bin bottom outlets 21032 is located on a front side of the compressor 221.

As shown in fig. 11 to 13, 15 and 16, a plurality of bin bottom outlets 21032 located at the front side of the compressor 221 are adjacent to the evaporating dish 250.

It will be appreciated by those skilled in the art that the air flow blocked by the rear side plate of the evaporating dish 250 can be reflected to the plurality of bin bottom outlets 21032 on the front side of the compressor 221, and further flows from the plurality of bin bottom outlets 21032 to the outside (as shown in fig. 15 and 16). This kind of structure is for the structure that evaporation pan 250 rear side does not have storehouse bottom air outlet 21032, can avoid evaporation pan 250 rear side board effectively to the shielding effect of air current, and then avoid the air current to appear the cyclone in evaporation pan 250 rear side board department effectively. Thus, in some embodiments of the present invention, the blocking effect of the rear side plate of the evaporating dish 250 on the air flow, and the corresponding noise, can be effectively eliminated.

In other embodiments of the invention, the plurality of bin bottom outlets 21032 may be arranged in any other feasible manner, as desired, such as, for example, arranging the plurality of bin bottom outlets 21032 on the front, right and bottom sides of the compressor 221, or on the front and/or right side of the compressor 221, by a person of ordinary skill in the art.

As shown in fig. 11 and 12, in some embodiments of the present invention, the structure of the evaporation pan 250 in the horizontal direction is adapted to the structure of the heat dissipation air outlet channel 2106 in the horizontal direction, that is, the opposite sides of the evaporation pan 250 and the heat dissipation air outlet channel 2106 are parallel to each other, so that the evaporation pan 250 can spread the whole heat dissipation air outlet channel 2106 as much as possible, thereby increasing the evaporation area of the evaporation pan 250 and increasing the evaporation rate of water in the evaporation pan 250.

Optionally, the size of the evaporation pan 250 in the front-rear direction is larger than the size of the evaporation pan 250 in the left-right direction, so that the evaporation pan 250 has a sufficient length in the path of the air flow in the heat dissipation air outlet channel 2106, thereby increasing the contact time of the water in the evaporation pan 250 with the air flow and increasing the evaporation rate of the water in the evaporation pan 250.

Further, the width of the front portion of the evaporating dish 250 is gradually reduced from the rear to the front, and the width of the front portion of the heat dissipation air outlet channel 2106 is also gradually reduced from the rear to the front, so that the flow area of the front portion of the heat dissipation air outlet channel 2106 is gradually reduced, and thus the flow rate of the air flow at the front portion of the evaporating dish 250 is gradually increased, so as to ensure the evaporation rate of the water in the front portion of the evaporating dish 250.

As will be appreciated by those skilled in the art, in the heat dissipation air outlet channel 2106, the air flow just enters the evaporation pan 250, due to the higher temperature, has good heating effect on the water in the evaporation pan 250; but as the air flow gets closer to the front air outlet 21061, the air flow absorbs more and more heat from the water and the temperature gets lower, resulting in a poorer heating effect on the water. By gradually decreasing the width of the evaporation pan 250 and the front portion of the heat dissipation air outlet channel 2106 from back to front, the flow area of the front portion of the heat dissipation air outlet channel 2106 is gradually decreased, and thus the flow rate of the air flow therein is gradually increased, so that the air flow can overcome the influence of low temperature on the water evaporation efficiency at a high flow rate. Thus, in some embodiments of the present invention, the evaporation efficiency of the air flow in the heat sink outlet channel 2106 to the water in the evaporation pan 250 is improved by gradually decreasing the width of the evaporation pan 250 and the front portion of the heat sink outlet channel 2106 from back to front.

Further, in the front-rear direction of the refrigeration module 200, the distance between the front surface of the evaporating dish 250 and the front side plate of the housing 210 is not less than 5mm, preferably not less than 15mm, to ensure a sufficient gap between the front surface of the evaporating dish 250 and the front side plate of the housing 210, reducing wind resistance thereto to the air flow.

As can be seen from fig. 13 to 15, the front air inlet 21051 and the front air outlet 21061 are each a bar-shaped hole extending in the up-down direction, and the top surface of the front end of the evaporating dish 250 is located at the middle upper portion of the bar-shaped hole in the vertical direction. That is, in the up-down direction of the refrigeration module 200, the tip of the front side plate of the evaporating dish 250 is located at the upper middle portion of the front air outlet 21061 to ensure that part of the air flow can be blown out from the front air outlet 21061 in the horizontal direction.

Further, in the up-down direction of the refrigeration module 200, the minimum distance between the top surface of the evaporation pan 250 (i.e., the top end of the front side plate of the evaporation pan 250) and the top wall of the heat dissipation air outlet channel 2106 is not less than 5mm, preferably not less than 15mm, so as to ensure that a sufficient gap exists between the front side plate of the evaporation pan 250 and the top wall of the heat dissipation air outlet channel 2106, and reduce the wind resistance to the air flow at the gap.

As shown in fig. 11, 12, 15 and 16, in some embodiments of the present invention, a water receiving pipe 251 extending upward from the bottom plate of the evaporation pan 250 is provided in the evaporation pan 250. The lower end of the drain pipe 270 is inserted into the water receiving pipe 251 with a gap between the water receiving pipe 251 and the drain pipe 270 so that water flowing out of the drain pipe 270 can flow out of the water receiving pipe 251 from the gap and into the evaporation pan 250.

As will be appreciated by those skilled in the art, since the lower end of the drain pipe 270 is inserted into the water receiving pipe 251, a small amount of water will be stored in the water receiving pipe 251 after the defrosting of the evaporator 226 is completed to liquid-seal the bottom end of the drain pipe 270, i.e., the liquid surface in the water receiving pipe 251 is located above the bottom end of the drain pipe 270. As will be further appreciated by those skilled in the art, the bottom end of the drain pipe 270 is closed by water such that hot air within the evaporating dish 250 cannot enter the refrigerating compartment 2104 from the drain pipe 270, thereby improving the refrigerating efficiency of the refrigerating module 200.

In addition, in other embodiments of the present invention, a sink may be provided in the evaporation pan 250 as required by those skilled in the art, and the lower end of the drain pipe 270 may be inserted into the sink. Specifically, the sink is formed on the bottom plate of the evaporation pan 250 and is recessed downward so that water can be secured in the sink even when the amount of water in the evaporation pan 250 is small, thereby ensuring that the drain pipe 270 can be water-sealed.

Thus far, the case module 100 and the refrigeration module 200 of the present invention have been described in detail with reference to the accompanying drawings. Based on the foregoing, it can be understood by those skilled in the art that in the present invention, by arranging the evaporator 226 to be inclined upward in the front-to-rear direction, the value of the included angle between the evaporator 226 and the horizontal plane is set to be 8 ° to 45 °, so that the evaporator 226 occupies a smaller space in the vertical direction and occupies a smaller space in the front-to-rear direction, so that the refrigerating room 2104 can reserve more space to arrange the air blower 240, and a sufficient gap is provided between the air blower 240 and the evaporator 226, thereby avoiding the excessive wind resistance and affecting the energy consumption of the refrigerating and freezing apparatus.

Further, by arranging the outer contours of the projections of the press bin 2103, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 on the horizontal plane outside the projection of the refrigerating compartment 2104 on the horizontal plane and filling the heat insulation materials in the transverse gap 21071, the front gap 21072 and the longitudinal gap 21073 outside the refrigerating compartment 2104, the top plates of the press bin 2103, the heat dissipation air inlet channel 2105 and the heat dissipation air outlet channel 2106 are parallel to the bottom plate of the refrigerating compartment 2104, and the refrigerating compartment 2104 is ensured not to leak cold and the structure of the refrigerating module 200 is more compact.

Further, by disposing the evaporation pan 250 in the heat dissipation air outlet channel 2106, the evaporation pan 250 can heat the water in the evaporation pan 250 by utilizing the heat of the whole press bin 2103, so that the evaporation rate of the water in the evaporation pan 250 is improved.

Further, by extending the drain pipe 270 from the top down into the evaporation pan 250, the defrost water in the refrigeration compartment 2104 can be quickly drained into the evaporation pan 250. By inserting the lower end of the drain pipe 270 into the water receiving pipe 251, a small amount of water is stored in the water receiving pipe 251 after the defrosting of the evaporator 226 is completed to liquid-seal the bottom end of the drain pipe 270. As will be appreciated by those skilled in the art, the bottom end of the drain pipe 270 is closed by water, so that hot air in the evaporating dish 250 cannot enter the refrigerating compartment 2104 from the drain pipe 270, thereby improving the refrigerating efficiency of the refrigerating module 200.

Meanwhile, the above-described structure of the refrigerating module 200 also makes the entire refrigerating module 200 flatter, leaving more space for the case module 100 thereon.

Thus far, the technical solution of the present invention has been described in connection with the foregoing embodiments, but it will be readily understood by those skilled in the art that the scope of the present invention is not limited to only these specific embodiments. The technical solutions in the above embodiments can be split and combined by those skilled in the art without departing from the technical principles of the present invention, and equivalent changes or substitutions can be made to related technical features, so any changes, equivalent substitutions, improvements, etc. made within the technical principles and/or technical concepts of the present invention will fall within the protection scope of the present invention.

Claims (10)

1. The refrigerating and refrigerating equipment is characterized by comprising a box body module and a refrigerating module, wherein the box body module is defined with a storage compartment, an air supply channel communicated with the storage compartment and an air return channel communicated with the storage compartment; the refrigeration module includes:

the shell is internally provided with a press bin and a refrigeration compartment, the shell is provided with an air return port and an air supply port which are communicated with the refrigeration compartment, the air return port is in fluid connection with the air return channel, and the air supply port is in fluid connection with the air supply channel; a rear inclined plane is arranged at the joint of the rear side plate of the shell and the top plate of the shell, and the air supply outlet is formed on the rear inclined plane;

A refrigeration system including a compressor and a condenser disposed within the press bin, the refrigeration system further including an evaporator disposed within the refrigeration compartment;

a heat dissipation fan disposed within the press bin;

and the air supply fan is arranged in the refrigerating compartment.

2. A refrigerating apparatus as recited in claim 1, wherein,

an upper inclined plane matched with the rear inclined plane is arranged on the box body module, an air inlet of the air supply channel is formed on the upper inclined plane, and the upper inclined plane is abutted with the rear inclined plane so that the air supply port and the air inlet are opposite to each other;

the box module is further provided with a bottom surface matched with the top surface of the top plate of the shell, which is positioned on the front side of the rear inclined surface, and the bottom surface is abutted to the top surface.

3. A refrigerating apparatus as recited in claim 2, wherein,

the bottom surface of the box body module and the top surface of the shell are both horizontally arranged.

4. A refrigerating apparatus as recited in claim 2, wherein,

a gap is formed between the upper inclined surface and the rear inclined surface in a state that the bottom surface is in contact with the top surface;

At least one of the upper inclined surface and the rear inclined surface is attached with a compressible gasket so that the gasket fills the gap and the upper inclined surface and the rear inclined surface are abutted together by the gasket.

5. The refrigerating apparatus as recited in claim 4, wherein,

the air supply port is arranged in the center of the rear inclined plane; and/or the number of the groups of groups,

the air supply port is a rectangular opening extending transversely.

6. The refrigerating apparatus as recited in any one of claims 1 to 5, wherein,

the air supply fan comprises an air outlet part with a fan outlet, and the air outlet part and a side plate where the rear inclined plane is arranged are connected together in a sealing mode through a sealing component, so that cold air blown out from the fan outlet completely flows through the air supply opening.

7. The refrigerating apparatus as recited in claim 6, wherein,

the sealing member is sealing cotton; and/or the number of the groups of groups,

and a part of the air outlet part is embedded into the air supply outlet.

8. The refrigerating apparatus as recited in claim 6, wherein,

the side plate where the rear inclined plane is located is provided with at least one reinforcing rib.

9. The refrigerating apparatus as recited in claim 8, wherein,

The inner side of the side plate where the rear inclined surface is located is provided with the reinforcing rib at least one part of the circumferential edge of the air supply outlet.

10. The refrigeration and chiller of any one of claims 1 to 5 wherein the refrigeration and chiller is a refrigerator.