CN218565863U - Horizontal wind-cooling refrigerator - Google Patents

Abstract

The utility model discloses a horizontal wind-cooling cabinet, include: the heat preservation cabinet body comprises a shell, an inner container and an air duct assembly, wherein the inner container is provided with an air outlet and an air return inlet and is arranged in the shell; the air duct assembly comprises a first cover plate, a second cover plate and an installation shell, an air outlet and an air inlet are formed in the installation shell, and an installation opening is formed in one end face of the installation shell; the refrigerating unit comprises a mounting frame, an evaporation fan, a condensation fan and a refrigerating loop, wherein the refrigerating loop comprises a compressor, a condenser, a throttling device and an evaporator which are connected together, a heat-preservation partition is arranged on the mounting frame, the evaporation fan and the evaporator are arranged on one side of the heat-preservation partition, and the compressor, the condenser, the throttling device and the condensation fan are arranged on the other side of the heat-preservation partition. The air tightness between the refrigerating unit and the heat preservation cabinet body is improved, the leakage of cold air is reduced to reduce energy consumption, and the refrigerating effect of the horizontal air cooling cabinet is improved.

Description

Horizontal wind-cooling refrigerator

Technical Field

The utility model relates to a refrigeration technology field especially relates to a horizontal wind-cooling cabinet.

Background

The refrigerator is widely popularized and used due to large storage capacity. The conventional refrigerator generally adopts a refrigeration mode, and the horizontal refrigerator adopting an air cooling mode is gradually put into the market along with the technical progress. For example: chinese patent publication No. CN 207501524U discloses a horizontal refrigerator, in which, in order to facilitate later maintenance, an independent refrigerating unit is used and an air duct is provided in a box body to meet the requirements of air supply and air return. During actual assembly, air inlets and air outlets of the refrigerating unit need to be butted with air inlets and air outlets arranged on the box body, so that the requirement that air in the box body circularly flows into the refrigerating unit to be circularly refrigerated is met. However, due to the influence of the machining precision, the joint between the refrigeration unit and the box body is likely to leak air, and the leakage of cold energy is caused, which results in high energy consumption. In view of this, how to design a technology of reducing energy consumption in order to improve refrigeration effect is the technical problem that the utility model aims to solve.

SUMMERY OF THE UTILITY MODEL

The utility model provides a horizontal forced air cooling cabinet realizes improving the gas tightness between the refrigerating unit and the heat preservation cabinet body, reduces air conditioning leakage in order to reduce the energy consumption, has improved horizontal forced air cooling cabinet refrigeration effect.

In order to achieve the above purpose, the utility model adopts the following technical scheme:

the utility model provides a horizontal wind-cooling cabinet, include:

the heat preservation cabinet body comprises a shell, an inner container and an air duct assembly, wherein the inner container is provided with an air outlet and an air return inlet and is arranged in the shell; the air duct assembly comprises a first cover plate, a second cover plate and an installation shell, an air outlet and an air inlet are formed in the installation shell, an installation opening is further formed in one end face of the installation shell, the first cover plate covers the outer wall of the liner and forms an air supply channel with the outer wall of the liner, the second cover plate covers the outer wall of the liner and forms an air return channel with the outer wall of the liner, the air supply channel is respectively communicated with the air outlet and the air outlet, and the air return channel is respectively communicated with the air return inlet and the air inlet;

the refrigeration unit comprises a mounting frame, an evaporation fan, a condensation fan and a refrigeration loop, wherein the refrigeration loop comprises a compressor, a condenser, a throttling device and an evaporator which are connected together;

the evaporation fan and the evaporator are arranged in the installation shell through the installation opening, and the heat-insulation partition is attached to the end face of the installation shell and covers the installation opening; the evaporation fan is configured to suck air from the air inlet, exchange heat through the evaporator and then discharge the air from the air outlet.

Further, the liner comprises a liner body and a lining, the liner body is provided with the air outlet and the air return opening, the lining is sleeved outside the liner body, a first ventilation opening and a second ventilation opening are arranged on the lining, the first ventilation opening is communicated with the air outlet, and the second ventilation opening is communicated with the air return opening;

the first cover plate is arranged on the bushing and covers the first ventilation opening, and the second cover plate is arranged on the bushing and covers the second ventilation opening.

Furthermore, the air outlet is arranged on the upper portion of the liner body, the air return port is arranged on the lower portion of the liner body, a sealing partition strip is further arranged between the liner body and the lining, and the sealing partition strip is transversely arranged and located between the air outlet and the air return port.

Furthermore, the air outlet and the air return opening are respectively provided with a baffle plate, and the baffle plate slants from bottom to top and extends towards the outer side of the liner body.

Furthermore, the air duct assembly comprises a liner body, the air outlet and the air return inlet are respectively arranged on the front side and the rear side of the liner body, and the first cover plate and the second cover plate are respectively arranged on the front side and the rear side of the liner;

the air duct assembly further comprises a flow distributing cover plate and a flow collecting cover plate, the flow distributing cover plate and the flow collecting cover plate are respectively arranged on the bushing, a flow distributing air passage is formed between the flow distributing cover plate and the bushing, a flow collecting air passage is formed between the flow collecting cover plate and the bushing, two end parts of the flow distributing air passage are respectively connected with the air supply channel, and two end parts of the flow collecting air passage are respectively connected with the air return channel; the flow distributing cover plate is provided with a first communicating port, the first communicating port is connected with the air outlet, the flow collecting cover plate is provided with a second communicating port, and the second communicating port is connected with the air inlet.

Furthermore, a concave part is arranged at one end part of the inner container, and the mounting shell is positioned below the concave part; the top of installation shell is provided with the air exit, the lateral part of installation shell is provided with the air intake.

Furthermore, the heat-insulation partition is provided with a first support, and one end of the evaporator is arranged on the first support.

Furthermore, a water pan is arranged on the heat-insulating partition and is arranged below the evaporator.

Furthermore, a second support is further arranged on the heat insulation partition, one end of the second support is arranged on the heat insulation partition, and the evaporation fan is arranged on the second support.

Furthermore, the edge of the heat-insulating partition is also provided with a sealing ring.

The technical scheme of the utility model relative prior art have following technological effect: through being provided with independent installation shell in the heat preservation cabinet body, the installation shell keeps good sealing connection state at the inner wall of the heat preservation cabinet body and air supply channel and return air channel, and after assembling refrigerating unit to the heat preservation cabinet body, the evaporimeter inserts in the installation shell and separates air exit and air intake via the installation opening, and simultaneously, the heat preservation wall will seal the installation opening on covering the installation shell, and then make and form relative confined evaporation cavity between heat preservation end cover and the installation shell, in the use, the installation opening is sealed by the heat preservation wall is good, can reduce the leakage of air conditioning, realize improving the gas tightness between refrigerating unit and the heat preservation cabinet body, reduce the air conditioning and leak in order to reduce the energy consumption, horizontal forced air cooling cabinet refrigeration effect has been improved.

Wherein, to the air outlet and the return air inlet that form on the inner bag, through set up the baffle respectively in the outside of air outlet and return air inlet, the baffle is arranged by the lower supreme slope to can block through the baffle that the internal article of thermal-insulating cabinet falls in the wind channel via air outlet and return air inlet, and then improve and use the reliability.

In addition, for the refrigerating unit, the evaporator and the evaporation fan are arranged on one side of the heat-insulation partition, and the compressor, the condenser and the condensation fan are arranged on the other side of the heat-insulation partition, so that the refrigerating unit is transversely arranged integrally, the integral height of the refrigerating unit is reduced, the requirement of compact design of the integral structure of the refrigerating unit is met, and the effective volume of the refrigerator is increased. In addition, after the refrigerating unit is pulled out, the related parts of the refrigerating unit are all in an exposed state, so that maintenance personnel can perform maintenance operation more conveniently, and the maintenance convenience is improved.

Drawings

FIG. 1 is a schematic structural view of the horizontal air cooler of the present invention;

FIG. 2 is a sectional view of the horizontal air-cooled cabinet of the present invention;

FIG. 3 is an enlarged view of a portion of area A of FIG. 2;

FIG. 4 is a sectional view taken along line B-B of FIG. 2;

FIG. 5 is an enlarged view of a portion of the area C in FIG. 4;

FIG. 6 is a schematic view of a partial structure of the heat-insulating cabinet in FIG. 1;

FIG. 7 is an exploded assembly view of the bladder and duct assembly of FIG. 1;

FIG. 8 is a schematic view of the structure of the inner container shown in FIG. 1;

FIG. 9 is a schematic view of the mounting housing of FIG. 1;

FIG. 10 is one of the schematic constructions of the refrigeration unit of FIG. 1;

fig. 11 is a second schematic diagram of the refrigeration unit of fig. 1.

Reference numerals:

a heat preservation cabinet body 1;

the air-conditioning cabinet comprises a shell 11, an inner container 12, an air duct assembly 13 and a cabinet opening 14;

the air conditioner comprises a partition plate 111, an air outlet 121, an air return opening 122, a liner body 123, a lining 124, a sealing division bar 125 and a baffle plate 126;

the air conditioner comprises a first cover plate 131, a second cover plate 132, a mounting shell 133, a flow dividing cover plate 134, a flow collecting cover plate 135, an air supply channel 101 and an air return channel 102;

the air guide structure comprises a first ventilation opening 1241, a second ventilation opening 1242, an air outlet 1331, an air inlet 1332, a mounting opening 1333, an outer convex part 1334 and an arc-shaped air guide surface 1335;

a refrigerating unit 2;

the device comprises a mounting frame 21, an evaporation fan 22, a condensation fan 23, a refrigeration loop 24, a heat insulation partition 25, a first support 26, a water pan 27, a second support 28 and a sealing ring 29;

compressor 241, condenser 242, evaporator 243, drain 271.

Detailed Description

As shown in fig. 1-11, the utility model provides a horizontal wind-cooling cabinet, include: a heat preservation cabinet body 1 and a refrigerating unit 2. Wherein, form storing cavity and machine storehouse in the heat preservation cabinet body 1, storing cavity is used for the storage to need cold-stored or frozen article, and refrigerating unit 2 then installs in the machine storehouse. The cold air that refrigerating unit produced is carried and is inputed the storing cavity from the air outlet through the air supply passageway in the heat preservation cabinet body 1, and the gas in the storing cavity returns to refrigerating unit 2 from the return air passageway through the return air inlet and carries out the refrigeration processing again.

The heat preservation cabinet body 1 comprises a shell 11, an inner container 12 and an air duct assembly 13, wherein the inner container 12 is provided with an air outlet 121 and an air return opening 122, and the inner container 12 is arranged in the shell 11; the air duct assembly 13 includes a first cover plate 131, a second cover plate 132 and a mounting shell 133, the mounting shell 133 is provided with an air outlet 1331 and an air inlet 1332, one end face of the mounting shell 133 is further provided with a mounting opening 1333, the first cover plate 131 covers the outer wall of the liner 12 and forms an air supply channel 101 with the outer wall of the liner 12, the second cover plate 132 covers the outer wall of the liner 12 and forms an air return channel 102 with the outer wall of the liner 12, the air supply channel 101 is respectively communicated with the air outlet 121 and the air outlet 1331, and the air return channel 102 is respectively communicated with the air return opening 122 and the air inlet 1332; a tank opening 14 is provided at the top of the outer case 11 and the top of the inner container 12, and the outer case 11 and the inner container 12 are assembled together through the tank opening 14.

In addition, for the refrigeration unit 2, the refrigeration unit includes a mounting frame 21, an evaporation fan 22, a condensation fan 23 and a refrigeration circuit 24, the refrigeration circuit includes a compressor 241, a condenser 242, a throttling device (not shown) and an evaporator 243 which are connected together, a thermal insulation partition 25 is arranged on the mounting frame 21, the evaporation fan 22 and the evaporator 243 are arranged on one side of the thermal insulation partition 25, and the compressor, the condenser, the throttling device and the condensation fan are arranged on the other side of the thermal insulation partition 25;

the evaporation fan 22 and the evaporator 243 are arranged in the mounting shell 133 through a mounting opening 1333, and the thermal insulation partition 25 abuts against the end face of the mounting shell 133 and covers the mounting opening 1333; the evaporator fan 22 is configured to draw air from the air inlet 1332, exchange heat with the evaporator 243, and then discharge the air from the air outlet 1331.

Specifically, since the refrigeration unit 2 can be detached from the thermal insulation cabinet 1, in order to ensure good connection airtightness between the refrigeration unit 2 and the thermal insulation cabinet 1 after the refrigeration unit is assembled in the thermal insulation cabinet 1, leakage of cold air at the assembly connection portion is reduced.

Therefore, the installation shell 133 is arranged in the heat preservation cabinet body 1, the air outlet 1331 formed on the installation shell 133 is communicated with the air outlet 121 on the inner container 12 through the air supply channel 101, the air inlet 1332 formed on the installation shell 133 is communicated with the air return opening 122 on the inner container 12 through the air return channel 102, and the air supply channel 101 and the air return channel 102 are integrated between the outer shell 11 and the inner container 12, so that the internal air path of the heat preservation cabinet body 1 can be ensured to keep good air tightness.

With the refrigeration unit 2 assembled into the insulated cabinet 1, the evaporator 243 and the evaporator fan 22 enter the mounting case 133 through the mounting opening 1333, and the evaporator 243 is disposed between the air outlet 1331 and the air inlet 1332. It is important that the mounting opening 1333 be covered by the thermal insulation partition 25 to improve the sealing reliability at the mounting opening 1333. Preferably, the edge of the thermal insulation partition 25 is also provided with a sealing ring 29. Specifically, after the refrigeration unit 2 is assembled to the insulated cabinet 1, the sealing ring is squeezed between the mounting case 133 and the insulated partition 25, and the sealing ring is used to seal and surround the periphery of the mounting opening 1333.

Compared with the prior art that the air port between the unit and the cabinet body is connected by adopting a butt joint mode, on one hand, the assembly precision can be simplified, and the assembly can be completed only by inserting the evaporator 243 and the evaporation fan into the mounting shell 133; on the other hand, the sealing reliability can be improved, and the heat-insulating partition plate is used for comprehensively and effectively blocking the whole installation opening 1333 so as to reduce the occurrence of cold air leakage.

In addition, the air supply duct 101 and the air return duct 102 formed in the heat insulating cabinet 1 are formed outside the inner container 12 by disposing a cover plate outside the inner container 12, and the volume of the inner container 12 is not occupied by the air supply duct 101 and the air return duct 102.

Further, in order to improve the uniformity of the air supply and the return air and make the temperature distribution in the inner container 12 uniform, a plurality of air outlets 121 and air return openings 122 are generally arranged on the inner container 12, and a plurality of air outlets 121 and air return openings 122 are generally arranged in sequence along the length direction of the inner container 12.

Correspondingly, the liner 12 comprises a liner body 123 and a lining 124, the liner body 123 is provided with an air outlet 121 and an air return opening 122, the lining 124 is sleeved outside the liner body 123, the lining 124 is provided with a first ventilation opening 1241 and a second ventilation opening 1242, the first ventilation opening 1241 is communicated with the air outlet 121, and the second ventilation opening 1242 is communicated with the air return opening 122;

here, the first cover plate 131 is disposed on the liner 124 and covers the first ventilation opening 1241, and the second cover plate 132 is disposed on the liner 124 and covers the second ventilation opening 1242.

Specifically, inner bag 12 adopts bilayer structure, forms the storing cavity and disposes a plurality of air outlets 121 and return air inlet 122 through the courage body 123, and set up bush 124 in the outside of the courage body 123, make and form the air interlayer between the courage body 123 and the bush 124, the heat preservation performance of the courage body 123 can be improved on the one hand to the air interlayer, on the other hand can further cushion the cold air that air supply channel 101 carried through the air interlayer, so that each air outlet 121 can be evenly dispersed to the cold air.

In order to improve the uniformity of the temperature distribution, a plurality of first ventilation openings 1241 may be arranged to match the air outlet 121, and similarly, a plurality of second ventilation openings 1242 may be arranged to match the air return openings 122.

In addition, in order to separate the air outlet 121 and the air return 122 in the air interlayer, the air outlet 121 is arranged at the upper part of the liner body 123, the air return 122 is arranged at the lower part of the liner body 123, and a sealing division bar 125 is further arranged between the liner body 123 and the lining 124, and the sealing division bar 125 is transversely arranged and positioned between the air outlet 121 and the air return 122.

Specifically, the sealing partition bar 125 is connected between the liner 123 and the liner 124, so that the air outlet 121 and the air return 122 are sealed and spaced in an air interlayer by the sealing partition bar 125. In the actual use process, the cold air delivered by the air delivery channel 101 enters the air interlayer through each first vent 1241 for buffering, and then is delivered into the storage cavity formed by the liner 123 from the air outlet 121. Air in the storage chamber may also flow into the return air channel 102 through the return air opening 122 at a different location to allow air to circulate between the storage chamber and the mounting shell 133.

Preferably, the air outlet 121 and the air return opening 122 are respectively provided with a baffle 126, and the baffle 126 extends from bottom to top towards the outer side of the container 123 in an inclined manner.

Specifically, the baffle 126 covers the air outlet 121 and the air return opening 122, so that in actual use, the objects in the container body 123 can be effectively prevented from falling into the air supply channel 101 and the air return channel 102. Moreover, the baffle 126 extends upwards and slantwise along the lower edges of the air outlet 121 and the air return opening 122, so that the upper edge of the baffle 126 and the upper edge of the air outlet 121 form an air outlet part, and similarly, the upper edge of the baffle 126 and the upper edge of the air return opening 122 form an air return part, so that articles can be prevented from falling into the air duct to the maximum extent.

In addition, due to the arrangement of the baffle 126, for the air outlet 121, after the cold air conveyed from the air supply channel 101 enters between the liner 123 and the bushing 124 and is shielded by the baffle 126, the cold air will bypass the top of the baffle 126 and be discharged from the air outlet part towards the bottom of the liner 123, and due to the guidance of the baffle 126 arranged in an inclined manner, the cold air is conveyed downwards in an inclined manner towards the middle position of the bottom of the liner 123, so that the air supply uniformity is improved to the maximum extent, and the temperature distribution uniformity in the storage cavity is optimized, so that the refrigeration effect is improved.

For the baffle 126, the baffle 126 and the container 123 are an integral structure. For example: the baffle 126 is formed on the liner 123 by punching.

In another embodiment, the air duct assembly 13 includes a liner 123 having an air outlet 121 and an air return 122 respectively disposed at the front side and the rear side thereof, and a first cover plate 131 and a second cover plate 132 respectively disposed at the front side and the rear side of the liner 124;

the air duct assembly 13 further includes a flow dividing cover plate 134 and a flow collecting cover plate 135, the flow dividing cover plate 134 and the flow collecting cover plate 135 are respectively disposed on the liner 124, a flow dividing air passage (not labeled) is formed between the flow dividing cover plate 134 and the liner 124, a flow collecting air passage (not labeled) is formed between the flow collecting cover plate 135 and the liner 124, two end portions of the flow dividing air passage are respectively connected to the air supply channel 101, and two end portions of the flow collecting air passage are respectively connected to the air return channel 102; the flow dividing cover plate 134 is provided with a first communicating port, which is connected to the air outlet 1331, and the flow collecting cover plate 135 is provided with a second communicating port, which is connected to the air inlet 1332.

Specifically, the air outlet 121 and the air return opening 122 are distributed on the front and rear sides of the inner container 12, and correspondingly, the air supply channel 101 and the air return channel 102 are distributed on the front and rear sides of the inner container 12. The two air supply channels 101 are connected to the diversion air passage to satisfy the condition that the cool air output from the air outlet 1331 of the mounting case 133 is diverted into the two air supply channels 101 through the diversion air passage. The two return air channels 102 are connected with the collecting air duct, so that return air on two sides of the container body 123 can enter the mounting shell 133 through the collecting air duct to be refrigerated.

In another embodiment, one end of the inner container 12 is provided with a recess, and the mounting case 133 is located below the recess; an air outlet 1331 is formed at the top of the mounting case 133, and an air inlet 1332 is formed at the side of the mounting case 133.

Specifically, because the related components in the refrigeration unit 2 are transversely arranged, the overall height is relatively low, and a recess is formed in the bottom area of one end of the inner container 12 to meet the installation requirements of the refrigeration unit 2.

A partition plate 111 is further arranged in the housing 11, the partition plate 111 is located below the recessed portion, a machine cabin is formed between the partition plate 111 and the housing 11, and an installation shell 133 is located in the machine cabin; a foamed layer is provided between the outer case 11, the inner container 12, and the partition 111, and the first cover plate 131 and the second cover plate 132 are embedded in the foamed layer.

Further, the side wall of the mounting case 133, which is provided with the air inlet 1332, is provided with an outer protrusion 1334, the air inlet 1332 is located on the end surface of the outer protrusion 1334, and the evaporation fan 22 is arranged inside the air inlet 1332.

Specifically, the outer protrusion 1334 formed at one side wall of the mounting case 133 forms a space for mounting the evaporation fan 22 inside the mounting case 133, and the mounting opening 1333 is correspondingly formed with an opening shape matched with the outer protrusion 1334, so that the evaporation fan 22 can be smoothly assembled into the mounting case 133 through the mounting opening 1333.

In order to improve the heat exchange efficiency, the inner wall of the outer protrusion 1334 forms an arc-shaped air guiding surface 1335, which extends toward the evaporator 243. In the using process, after the evaporation fan 22 is started, the airflow in the storage cavity in the liner 123 enters from the air inlet 1332 and then is guided and expanded to be distributed to the whole evaporation surface of the evaporator 243 through the arc-shaped air guide surface 1335, so that the airflow can be discharged from the air outlet 1331 after being sufficiently subjected to heat exchange with the evaporator 243, and the heat exchange efficiency is further improved.

The upper end and the lower end of the evaporation fan 22 are respectively provided with the arc-shaped guide surfaces, and the distance between the two arc-shaped guide surfaces gradually increases along the airflow direction generated by the evaporation fan 22.

In another embodiment, in order to further simplify the overall structure of the refrigeration unit 2 to meet the requirements of a compact design, the thermal insulation partition 25 is provided with a first bracket 26 on which one end of the evaporator 243 is arranged.

Specifically, the evaporator 243 is exposed as a whole, and in order to facilitate installation and fixation of the evaporator 243, the first bracket is disposed on the thermal insulation partition 25, so that the evaporator 243 is fixed on the first bracket, and the free end of the evaporator 243 is in a suspended state, so as to meet the assembly requirement of being directly inserted into the installation shell 133. A water pan 27 may be disposed on the thermal insulation partition 25, and the water pan is disposed below the evaporator 243. And the bottom of the water pan is provided with a drain pipe 271 which penetrates through the heat-insulating partition 25.

Similarly, a second support 28 is further disposed on the thermal insulation partition 25, the second support is disposed on the thermal insulation partition 25, and the evaporation fan 22 is disposed on the second support.

Specifically, the evaporation fan 22 is fixed on the thermal insulation partition 25 by the second bracket of the cantilever structure, and when the assembly is performed, the evaporation fan 22 is assembled in place by inserting the second bracket into the mounting shell 133.

The above is only a specific embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any changes or substitutions that can be easily conceived by those skilled in the art within the technical scope of the present invention should be covered within the protection scope of the present invention. Therefore, the protection scope of the present invention shall be subject to the protection scope of the claims.

Claims (10)

1. The utility model provides a horizontal wind freezer which characterized in that includes:

the heat preservation cabinet body comprises a shell, an inner container and an air duct assembly, wherein the inner container is provided with an air outlet and an air return inlet, and is arranged in the shell; the air duct assembly comprises a first cover plate, a second cover plate and an installation shell, an air outlet and an air inlet are formed in the installation shell, an installation opening is further formed in one end face of the installation shell, the first cover plate covers the outer wall of the liner and forms an air supply channel with the outer wall of the liner, the second cover plate covers the outer wall of the liner and forms an air return channel with the outer wall of the liner, the air supply channel is communicated with the air outlet and the air outlet respectively, and the air return channel is communicated with the air return inlet and the air inlet respectively;

the refrigeration unit comprises a mounting frame, an evaporation fan, a condensation fan and a refrigeration loop, wherein the refrigeration loop comprises a compressor, a condenser, a throttling device and an evaporator which are connected together;

the evaporation fan and the evaporator are arranged in the installation shell through the installation opening, and the heat-insulation partition is attached to the end face of the installation shell and covers the installation opening; the evaporation fan is configured to suck air from the air inlet, exchange heat through the evaporator and then discharge the air from the air outlet.

2. The horizontal air cooler according to claim 1, wherein the inner container comprises a container body and a bushing, the container body is provided with the air outlet and the air return opening, the bushing is sleeved outside the container body, the bushing is provided with a first vent opening and a second vent opening, the first vent opening is communicated with the air outlet, and the second vent opening is communicated with the air return opening;

the first cover plate is arranged on the bushing and covers the first ventilation opening, and the second cover plate is arranged on the bushing and covers the second ventilation opening.

3. The horizontal air cooler according to claim 2, wherein said air outlet is arranged at the upper part of said liner body, said air return opening is arranged at the lower part of said liner body, a sealing parting strip is further arranged between said liner body and said bushing, said sealing parting strip is transversely arranged and located between said air outlet and said air return opening.

4. The horizontal air cooler according to claim 2, wherein said air outlet and said air return inlet are each provided with a baffle plate, said baffle plates extending from bottom to top obliquely towards the outer side of said container.

5. The horizontal air cooler according to claim 2, wherein the air duct assembly comprises the air outlet and the air return opening respectively arranged on the front side and the rear side of the liner body, and the first cover plate and the second cover plate are respectively arranged on the front side and the rear side of the liner;

the air duct assembly further comprises a flow distributing cover plate and a flow collecting cover plate, the flow distributing cover plate and the flow collecting cover plate are respectively arranged on the bushing, a flow distributing air passage is formed between the flow distributing cover plate and the bushing, a flow collecting air passage is formed between the flow collecting cover plate and the bushing, two end parts of the flow distributing air passage are respectively connected with the air supply channel, and two end parts of the flow collecting air passage are respectively connected with the air return channel; the flow distributing cover plate is provided with a first communicating port, the first communicating port is connected with the air outlet, the flow collecting cover plate is provided with a second communicating port, and the second communicating port is connected with the air inlet.

6. The horizontal wind refrigerator according to claim 1, wherein a recessed portion is provided at one end of the inner container, and the mounting case is located below the recessed portion; the top of the installation shell is provided with the air outlet, and the side of the installation shell is provided with the air inlet.

7. The horizontal wind refrigerator according to claim 1, wherein the thermal insulation partition is provided with a first bracket, and one end of the evaporator is arranged on the first bracket.

8. The horizontal wind refrigerator according to claim 7, wherein a water pan is arranged on the thermal insulation partition, and the water pan is arranged below the evaporator.

9. The horizontal wind refrigerator according to claim 1, wherein a second bracket is further disposed on the thermal insulation partition, one end of the second bracket is disposed on the thermal insulation partition, and the evaporation fan is disposed on the second bracket.

10. The horizontal wind-cooling refrigerator according to claim 1, wherein the edge of the thermal insulation partition is further provided with a sealing ring.

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