CN216282224U - Refrigerator with sliding glass door - Google Patents

Abstract

The utility model relates to a translational glass door refrigerator, which comprises a refrigerator body, a translational glass door group and a flow guide cover, wherein the refrigerator body comprises a refrigerating chamber and an engine room; the translation glass door group is arranged on the front side of the refrigerating chamber and comprises a translation glass door I and a translation glass door II; the air guide sleeve is arranged on the front side of the engine room, and a hot air outlet is formed in the top of the air guide sleeve; the translational glass door group is arranged inwards relative to the box body to form an anti-condensation recess; the rear side of the engine room is provided with an air inlet grille, and a condenser, a heat dissipation fan and a compressor are arranged in the engine room from back to front, the heat dissipation fan is arranged to enable fresh air sucked in through the air inlet grille to enter the air guide sleeve after passing through the condenser and the compressor in sequence and to be guided into the condensation preventing recess through the hot air outlet, and therefore a hot air curtain is formed on the outer side of the translation glass door group. According to the utility model, the heat generated when the refrigerating unit does work is guided into the condensation preventing concave in front of the translation glass door group through the guide cover so as to form the hot air curtain upwards along the translation glass door group, thereby achieving the condensation preventing effect.

Description

Refrigerator with sliding glass door

Technical Field

The utility model relates to the technical field of freezers, in particular to a freezer with a translation glass door.

Background

Refrigerators with glass doors are sought after by many users for their visibility. The translation glass door refrigerator is usually applied to various occasions such as hospital pharmacies, mother and infant food special cabinets and the like, has compact structure and small occupied area, and is easy to accept by users. However, the translational glass door is designed to be opened in a left-right sliding mode, so that an electric heating function cannot be configured, the surface of glass is easy to dew during the use process of a user, and the display effect is seriously influenced.

SUMMERY OF THE UTILITY MODEL

To overcome the above-mentioned deficiencies, it would be advantageous to provide a translating glass door cooler that prevents condensation on the glass door.

To achieve the above objects, the present invention provides a refrigerator with a sliding glass door, comprising:

a cabinet including a refrigerating compartment and a cabin;

the translational glass door group is arranged on the front side of the refrigerating chamber and comprises a translational glass door I and a translational glass door II;

the air guide sleeve is arranged on the front side of the engine room, and a hot air outlet is formed in the top of the air guide sleeve;

the translational glass door group is arranged inwards relative to the box body to form an anti-condensation recess;

the rear side of the engine room is provided with an air inlet grille, and a condenser, a heat dissipation fan and a compressor are arranged in the engine room from back to front, the heat dissipation fan is arranged to enable fresh air sucked in through the air inlet grille to enter the air guide sleeve after passing through the condenser and the compressor in sequence and to be guided into the condensation preventing recess through the hot air outlet, and therefore a hot air curtain is formed on the outer side of the translation glass door group.

In the utility model, heat generated when a refrigerating unit (a condenser and a compressor) does work is guided to the lower part of the translational glass door group through the guide cover, hot air finally passing through the compressor is upwards and directly blown to the outer side surface of the glass door through wind pressure generated by a cooling fan of the refrigerating unit, and a hot air curtain is upwards formed along the condensation preventing recess, so that the vertical upwards distance of the hot air is effectively prolonged, the temperature of the outer side surface of the glass door is increased, and the condensation preventing effect is achieved.

Furthermore, a fresh air inlet is formed in the air inlet grille, and the periphery of the fresh air inlet is connected with the condenser in a sealing mode through a sealing ring. The fresh air inlet preferably comprises a plurality of air inlets which are regularly arranged.

Through the structure, the fresh air can orderly enter the engine room, the fresh air (namely the environmental air) entering the engine room through the air inlet grille can directly dissipate heat of the condenser, then the fresh air is blown to the compressor under the pumping of the cooling fan, and finally the hot air is discharged from the hot air outlet arranged on the air guide sleeve.

Still further, the hot air outlet comprises a plurality of air outlets which are transversely arranged, so that hot air from the cabin is orderly discharged upwards through the air outlets of the hot air outlet, and hot air flow is formed in front of the glass door, so that condensation on the outside of the glass door is avoided.

Furthermore, the box body further comprises a heat insulation cabinet opening positioned on the front side of the refrigerating chamber, and the translation glass door group further comprises a door frame used for installing the translation glass door I and the translation glass door II in a sliding mode, and the door frame is installed on the front side of the heat insulation cabinet opening.

The heat insulation cabinet opening on the door frame and the box body is connected, so that the heat of the glass door can be prevented from being conducted to the side plate of the box body.

Still further, the door frame is provided with a translation door mounting groove which is arranged around the heat insulation cabinet opening for one circle, and the first translation glass door and the second translation glass door are respectively installed in the translation door mounting groove in a sliding mode through glass door sliding frames.

Through above-mentioned structure setting, on the one hand can be so that translation glass door can smoothly slide from side to side in translation door mounting groove, and on the other hand can be in the box of comprehensive separation heat conduction in circumference.

Still further, the door frame is still installed with preventing the electric heating wire of condensation at its inside, should prevent that the electric heating wire of condensation distributes around adiabatic cabinet mouth a week.

Through the arrangement of the anti-condensation electric heating wires, condensation on the door frame is further avoided.

These and other aspects of the utility model are apparent from and will be elucidated with reference to the embodiments described hereinafter.

Drawings

The structure and further objects and advantages of the present invention will be better understood by the following description taken in conjunction with the accompanying drawings, in which like reference characters identify like elements, and in which:

FIG. 1 is a perspective view of the exterior configuration of a translating glass door cooler according to one embodiment of the present invention;

FIG. 2 is a perspective view of the exterior configuration of the translating glass door cooler of FIG. 1 from another angle;

FIG. 3 is a schematic plan view of the translating glass door cooler of FIG. 1 as viewed from the front;

FIG. 4 is a cross-sectional view of the translating glass door cooler of FIG. 3 taken along line A-A;

FIG. 5 is an enlarged view of a portion of the set of translating glass doors of the translating glass door cooler of FIG. 4.

Detailed Description

Embodiments of the present invention will be described below with reference to the accompanying drawings.

In this document, the directions used to explain the structure and/or actions of the various parts of the disclosed embodiments, such as "upper", "lower", "front", "rear", etc., are not absolute, but relative. These representations are suitable when the various parts of the disclosed embodiments are located in the positions shown in the figures, and if the position or frame of reference of the disclosed embodiments is changed, they are also changed according to the change in the position or frame of reference of the disclosed embodiments.

As shown in fig. 1 to 5, the sliding glass door refrigerator 100 according to one embodiment of the present invention includes a cabinet 1, a sliding glass door group 3, and a dome 5. The box 1 comprises a refrigerating chamber 10 and a cabin 20; the translation glass door group 3 is arranged on the front side of the refrigerating chamber 10 and comprises a first translation glass door 31 and a second translation glass door 32; the nacelle 20 is provided with a wind scooper 5 at the front side thereof and a hot wind outlet 50 at the top thereof.

As shown in fig. 4, the set of translating glass doors 3 is disposed inwardly with respect to the cabinet 1 to form a condensation-preventing recess 4. Specifically, as shown in fig. 4 and referring to fig. 1 to 3, two side plates 11 (i.e. left and right side plates) of the box body 1 extend forward a distance relative to the translational glass door group 3, and the glass door frame plane is recessed in the side plate plane by means of assembling the side plate plane (i.e. the plane where the front ends of the two side plates 11 are located) and the glass door frame plane, so as to form the condensation-preventing recess 4.

As shown in fig. 4, the nacelle 20 is provided with an air intake grille 21 on the rear side thereof, and refrigeration system components such as a condenser 23, a radiator fan 25, and a compressor 27 are arranged in the nacelle 20 from the rear to the front. The space in the engine room 20 is surrounded by left and right side plates 11, an air inlet grille 21, a press bottom plate 22 and a flow guide cover 5. The heat dissipation fan 25 is installed on the condenser 23 and located between the condenser 23 and the compressor 27, and is configured to enable fresh air sucked in through the air inlet grille 21 to sequentially pass through the condenser 23 and the compressor 27 and then enter the air guide sleeve 5, and to be upwards guided into the condensation preventing recess 4 through the hot air outlet 50 on the air guide sleeve 5, so that a hot air curtain 40 is formed outside the translation glass door group 3, and thus the vertical upward distance of the hot air is effectively prolonged.

It should be noted that, the cooling fan 25 is installed on the condenser 23, when the cooling fan 25 does work, the cooling fan 25 can absorb the hot air emitted from the condenser 23 and blow the hot air to the compressor 27, and finally the hot air is discharged upwards from the hot air outlet 50 installed on the air guide sleeve 5, and directly blow the outer side surfaces of the first sliding glass door 31 and the second sliding glass door 32 to form the hot air curtain 40 upwards along the condensation preventing recess 4, and the trend of the air is shown by the arrow in fig. 4, so that the outer side surfaces of the glass doors are heated, and the condensation preventing effect is achieved.

As shown in fig. 4, the air intake grille 21 is provided with a fresh air inlet 210, and the outer periphery of the fresh air inlet 210 is hermetically connected to the condenser 23 through a sealing ring 212, in other words, the sealing ring 212 surrounds the air inlet (not shown) of the condenser 23 and is abutted against the fresh air inlet 210 of the air intake grille 21, so that the hot air in the cabin 20 is prevented from entering the condenser 23 again, thereby ensuring that all the fresh air entering the condenser 23 comes from the air intake grille 21. Preferably, in this embodiment, the fresh air inlet 210 may include a plurality of air inlets 211 arranged regularly. As shown in fig. 4, and with reference to fig. 2, the hot air outlet 50 includes a plurality of air outlets 501 arranged in a transverse direction. With such an arrangement, fresh air (i.e. ambient air) entering the cabin 20 through the air inlet grille 21 can directly dissipate heat for the condenser 23, and then blow towards the compressor 27 under the pumping action of the heat dissipation fan 25, and finally, the hot air blows upwards from the air outlets 501 of the hot air outlets 50 at the top of the air guide sleeve 5 and orderly moves upwards to form the hot air curtain 40.

As shown in fig. 4 and 5, the cabinet 1 further includes an insulated cabinet opening 13 located at the front side of the refrigerating chamber 10, and the sliding glass door group 3 further includes a door frame 30 for slidably mounting a first sliding glass door 31 and a second sliding glass door 32, wherein the door frame 30 is mounted on the front side of the insulated cabinet opening 13, and the heat of the first sliding glass door 31 and the second sliding glass door 32 can be prevented from being transmitted to the two side plates 11 of the cabinet 1 by connecting the door frame 30 with the insulated cabinet opening 13.

As further shown in fig. 5, and with reference to fig. 4, the door frame 30 is provided with a sliding door mounting slot 33, the sliding door mounting slot 33 is arranged to surround the heat-insulating cabinet opening 13 by one turn, and the first sliding glass door 31 and the second sliding glass door 32 are each slidably mounted in the sliding door mounting slot 33 via a glass door carriage 34. As shown in fig. 5, the door frame 30 is preferably provided at an inner side thereof with an anti-condensation electric heating wire 35, and the anti-condensation electric heating wire 35 is arranged to surround the heat-insulating cabinet opening 13 by one circle. By arranging the anti-condensation electric heating wires 35, condensation on the door frame 30 can be effectively avoided.

While the utility model has been described with respect to the foregoing technical disclosure and features, it will be understood that various changes and modifications in the above structure, including combinations of features disclosed herein either individually or as claimed, and obviously including other combinations of such features, may be resorted to by those skilled in the art, without departing from the spirit of the utility model. Such variations and/or combinations are within the skill of the art to which the utility model pertains and are within the scope of the following claims.

Claims (7)

1. A translating glass door cooler, comprising:

a cabinet including a refrigerating compartment and a cabin;

the translational glass door group is arranged on the front side of the refrigerating chamber and comprises a translational glass door I and a translational glass door II;

the air guide sleeve is arranged on the front side of the engine room, and a hot air outlet is formed in the top of the air guide sleeve;

the translational glass door group is arranged inwards relative to the box body to form an anti-condensation recess;

the rear side of the engine room is provided with an air inlet grille, and a condenser, a heat dissipation fan and a compressor are arranged in the engine room from back to front, the heat dissipation fan is arranged to enable fresh air sucked in through the air inlet grille to enter the air guide sleeve after passing through the condenser and the compressor in sequence and to be guided into the condensation preventing recess through the hot air outlet, and therefore a hot air curtain is formed on the outer side of the translation glass door group.

2. The translating glass door cooler of claim 1, wherein said air intake grille has a fresh air inlet, and wherein an outer periphery of said fresh air inlet is sealingly connected to said condenser by a gasket.

3. The translating glass door cooler of claim 2, wherein said fresh air intake comprises a plurality of regularly spaced air intakes.

4. The translating glass door cooler of claim 1 wherein said hot air outlet comprises a plurality of laterally aligned air outlets.

5. The sliding glass door cooler of any one of claims 1-4, wherein said cabinet further comprises an insulated cabinet opening located at a front side of said refrigerated compartment, and said set of sliding glass doors further comprises a door frame for slidably mounting said first sliding glass door and said second sliding glass door, said door frame being mounted to a front side of said insulated cabinet opening.

6. The translating glass door cooler of claim 5 wherein said door frame is provided with a translating door mount slot disposed about a perimeter of said insulated cabinet opening and wherein each of said first translating glass door and said second translating glass door is slidably mounted within said translating door mount slot via a glass door carriage.

7. The translating glass door cooler of claim 6, wherein said door frame is further provided with an anti-condensation electric heating wire on the inside thereof, said anti-condensation electric heating wire being disposed around the circumference of said insulated cabinet opening.

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