CN209978481U

CN209978481U - Refrigerating unit and refrigerating equipment

Info

Publication number: CN209978481U
Application number: CN201920577595.5U
Authority: CN
Inventors: 陈延星; 王学利; 褚永兴; 吴福民; 侯代民; 刘冬斌
Original assignee: Qingdao Haier Special Refrigerator Co Ltd; Qingdao Haier Co Ltd
Current assignee: Qingdao Haier Special Refrigerator Co Ltd; Qingdao Haier Co Ltd
Priority date: 2019-04-25
Filing date: 2019-04-25
Publication date: 2020-01-21
Anticipated expiration: 2029-04-25

Abstract

The utility model discloses a refrigerating unit and refrigeration plant. The refrigerating unit includes: the water receiving plate is positioned between the air outlet and the air return inlet; the refrigeration assembly is arranged on the bottom plate and comprises a compressor, a condenser, a throttling device and an evaporator which are connected together; the cover is arranged on the bottom plate and covers the air outlet, the air return inlet and the water receiving disc, the cover and the bottom plate form an evaporation cavity, the evaporator is arranged in the evaporation cavity and positioned above the water receiving disc, and the cover is also provided with an opening; the anti-cold leakage component is arranged in the opening, and a plurality of first water discharge gaps for discharging water in the water pan outwards are arranged on the anti-cold leakage component. The refrigeration effect is improved and the energy consumption is reduced by reducing the leakage of the cold quantity in the evaporation cavity under the condition that the defrosting water is smoothly discharged.

Description

Refrigerating unit and refrigerating equipment

Technical Field

The utility model belongs to the technical field of the refrigeration, especially, relate to a refrigerating unit and refrigeration plant.

Background

Refrigeration equipment (e.g., a refrigerator or freezer) is a household appliance commonly used in people's daily life. In order to increase the storage space, a top-mounted press cabin is generally adopted, so that a user can conveniently access the articles at the bottom of the refrigeration equipment. Under the general condition, a refrigeration assembly consisting of a compressor, a condenser and an evaporator, a fan and other components are installed on a bottom plate of the press cabin, an evaporation cavity is formed by arranging a housing on the bottom plate, and the evaporator is positioned in the evaporation cavity. In the actual use process, the evaporator needs to be subjected to defrosting treatment periodically, and defrosting water generated in the defrosting process is collected into a water receiving tray arranged at the bottom of the evaporator. The water in the water pan needs to be discharged to the outside from the evaporation cavity formed by the housing in time, and the defrosting water is usually discharged outside by the water pan in a mode of externally connecting a drain pipe. However, in the normal refrigeration process, the cold in the evaporation cavity is easy to leak from the drain pipe, and the cold leakage condition occurs, so that the refrigeration effect of the refrigeration equipment is poor and the energy consumption is high. How to design a refrigeration plant who reduces cold volume and reveal in order to improve refrigeration effect and reduce the energy consumption is the utility model aims to solve the technical problem.

SUMMERY OF THE UTILITY MODEL

The utility model discloses to the technical problem who exists among the prior art, provide a refrigerating unit and refrigeration plant, satisfying under the smooth and easy exhaust condition of defrosting water, reduce revealing of cold volume in the evaporation cavity to improve refrigeration effect and reduce the energy consumption.

In order to realize the purpose of the utility model, the utility model adopts the following technical scheme to realize:

the utility model provides a refrigerating unit, include:

the water receiving tray is positioned between the air outlet and the air return inlet;

the refrigerating unit is arranged on the bottom plate and comprises a compressor, a condenser, a throttling device and an evaporator which are connected together;

the cover is arranged on the bottom plate and covers the air outlet, the air return inlet and the water receiving tray, the cover and the bottom plate form an evaporation cavity, the evaporator is arranged in the evaporation cavity and positioned above the water receiving tray, and the cover is also provided with an opening;

the anti-cold leakage component is arranged in the opening, and a plurality of first drainage gaps for draining water to the outer side of the evaporation cavity are formed in the anti-cold leakage component.

Furthermore, a water flow channel is formed between the cold leakage prevention component and the bottom plate, the cold leakage prevention component is provided with a first shielding part located at the outer end part of the water flow channel, and the first shielding part is provided with the first drainage gap.

Furthermore, cold-proof part configuration of leak protection is located the inside second shelter portion of flowing water passageway, be provided with the second gap of draining on the second shelter portion.

Further, the cold leakage prevention member includes: a top plate; the two side plates are connected to the corresponding side edges of the top plate and are positioned below the top plate; the first baffle is connected to one end part of the top plate and located below the top plate, the first baffle is arranged on the outer side of the evaporation cavity, the first drainage gap is formed in the first baffle, and the first baffle forms the first shielding part; the second baffle is connected to the middle of the top plate and located below the top plate, the second baffle is provided with a second water discharge gap, and the second baffle forms the second shielding portion.

Further, a third drainage gap is formed between the first baffle and the corresponding end part of the side plate; and a fourth drainage gap is formed between the second baffle and the inner surface of the side plate.

Further, an air guide ring is arranged on the air return inlet, an evaporation fan is arranged in the air guide ring, and the air guide ring and the evaporation fan are positioned in the evaporation cavity; the refrigeration unit further includes: the flow guide assembly is arranged on the bottom plate and located in the evaporation chamber, and is used for guiding condensed water formed on the housing to the water receiving tray.

Furthermore, the flow guide assembly comprises two flow guide bodies, the two flow guide bodies are arranged on two sides of the air guide ring, and the flow guide bodies are clamped between the air guide ring and the housing; the flow guide body comprises a first side wall, a second side wall, a third side wall and a flow guide surface, the flow guide surface is respectively connected and intersected with the first side wall, the second side wall and the third side wall, the first side wall is abutted against the outer peripheral wall of the air guide ring, the second side wall is abutted against the side wall of the water receiving disc, the third side wall is abutted against the inner wall of the housing, the connection intersection position of the first side wall and the flow guide surface is higher than the end face of the air guide ring, and the connection intersection position of the second side wall and the flow guide surface is higher than the side wall of the water receiving disc; the condensed water dropping on the flow guide body flows into the water receiving tray through the flow guide surface.

Furthermore, the flow guide surface is of an inclined surface structure, and the flow guide surface gradually decreases from the direction away from the side of the water pan to the side close to the water pan and gradually decreases from the direction close to the side of the air guide ring to the side far away from the air guide ring.

Furthermore, one side of the flow guide surface, which is close to the air guide ring, is provided with a water retaining rib.

The utility model also provides a refrigerating device, which comprises a cabinet body, wherein a storage cavity is formed in the cabinet body, and the refrigerating device unit is also provided; the refrigerating unit is arranged at the top of the cabinet body, and an air outlet and an air return inlet of the refrigerating unit are respectively communicated with the storage cavity.

Compared with the prior art, the utility model discloses an advantage is with positive effect: the evaporation cavity is communicated with the outside through the opening by arranging the opening on the housing, the opening is internally provided with a cold leakage prevention part, and the cold leakage prevention part is provided with a water drainage gap to meet the requirement that water in the water pan is drained to the outside of the evaporation cavity; simultaneously, leak protection cold component inserts in the opening after in order to plug up the opening, because the drainage gap is less, under the prerequisite that satisfies the drainage, the scattering and disappearing of cold volume in the evaporation cavity can effectually be reduced in the drainage gap, realizes satisfying under the smooth and easy exhaust condition of defrosting water, reduces the revealing of cold volume in the evaporation cavity to improve refrigeration effect and reduce the energy consumption.

Other features and advantages of the present invention will become more apparent from the following detailed description of the invention when read in conjunction with the accompanying drawings.

Drawings

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

Fig. 1 is a schematic structural diagram of an embodiment of the refrigeration apparatus of the present invention;

fig. 2 is a schematic structural diagram of a refrigerating unit in an embodiment of the refrigerating apparatus of the present invention;

FIG. 3 is an exploded view of the assembly of the base plate, the housing and the cold leakage prevention member in an embodiment of the refrigeration apparatus of the present invention;

fig. 4 is a schematic structural view of a cold leakage prevention part in an embodiment of the refrigeration equipment of the present invention;

fig. 5 is an assembly view of the bottom plate and the guide assembly in the embodiment of the refrigeration apparatus of the present invention;

fig. 6 is one of the schematic structural diagrams of the baffle in the embodiment of the refrigeration apparatus of the present invention.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention will be described in further detail with reference to the accompanying drawings and embodiments.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are merely for convenience of description, and do not indicate or imply that the device or element 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" and "second" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

As shown in fig. 1 to 4, the refrigeration apparatus of the present embodiment includes a cabinet 1 and a refrigeration unit 2. A storage cavity is formed in the cabinet body 1, and a door body 10 is further arranged on the cabinet body 1 to open and close the storage cavity. The refrigerating unit 2 comprises a base plate 21, a refrigerating assembly 22 and a casing 23, wherein the refrigerating assembly 22 is mounted on the base plate 21, and the refrigerating assembly 22 comprises a compressor 221, a condenser 222, a throttling device (not shown) and an evaporator (not shown) which are connected together; the bottom plate 21 is provided with an air outlet 211 and an air return opening 212, the bottom plate 21 is also provided with a water receiving disc 213, and the water receiving disc 213 is positioned between the air outlet 211 and the air return opening 212; the cover 23 is installed on the bottom plate 21 and covers the air outlet 211, the air return inlet 212 and the water-receiving tray, the cover 23 and the bottom plate 21 form an evaporation cavity, and the evaporator is arranged in the evaporation cavity and positioned above the water-receiving tray 213. In order to ensure that the water in the water pan 213 is smoothly output to the outside of the evaporation cavity and reduce the dissipation of cold in the evaporation cavity, an opening 231 is further formed in the housing 23; meanwhile, a cold leakage preventing part 3 is arranged in the opening 231, and a plurality of first water draining gaps 301 for draining water in the water receiving tray 213 outwards are arranged on the cold leakage preventing part 3.

Particularly, the refrigeration unit 2 is set up at 1 top of the cabinet body of this embodiment refrigeration plant, refrigeration unit 2 passes through bottom plate 21 and fixes at the top of the cabinet body 1, and, air outlet 211 and return air inlet 212 on the bottom plate 21 communicate with the storage cavity in the cabinet body 1, in order to realize that the air circulates between evaporation cavity and storage cavity, wherein, dispose evaporation fan 24 in the evaporation cavity, under evaporation fan 24's effect, the air in the storage cavity enters into the evaporation cavity and forms cold air with the evaporimeter heat transfer through return air inlet 212, cold air will be inputed to the storage cavity through air outlet 211, in order to realize the article refrigeration in the storage cavity. During defrosting of the evaporator, defrosting water generated by defrosting of the evaporator is collected in the water pan 213 at the bottom, the water pan 213 is provided with a drainage channel 2131 extending towards the opening 231, and water in the water pan 213 is guided to flow towards the opening 231 through the drainage channel 2131 and finally discharged to the outside of the evaporation cavity from the opening 231. While the water output from the water receiving tray 213 passes through the cold leakage preventing member 3 in the process of being output through the opening 231, the water enters the cold leakage preventing member 3 through the opening 231 and is finally discharged from the first water discharge slit 301. The first drainage slits 301 of the cold leakage preventing member 3 can satisfy the requirement of outward drainage. Meanwhile, because the size of the first drainage gap 301 is smaller, under the normal refrigeration working condition, because the cold leakage prevention part 3 is inserted into the opening 231 to block the opening 231, the cold quantity leaked outwards from the first drainage gap 301 of the evaporation cavity is very small, thereby effectively reducing the leakage quantity of the cold quantity and improving the refrigeration effect.

A water flow channel is formed between the cold leakage preventing component 3 and the drainage channel 2131 on the bottom plate 21, the cold leakage preventing component 3 is provided with a first shielding part positioned at the outer end part of the water flow channel, and the first shielding part is provided with a first drainage gap 301. Specifically, the cold leakage prevention part 3 is inserted into the opening 231 and covers the drainage channel 2131, and the first shielding part arranged outside the cold leakage prevention part 3 can shield the port of the drainage channel outside the evaporation cavity, so that the dissipation of cold energy can be reduced more effectively. Preferably, the cold leakage prevention component 3 is configured with a second shielding portion located inside the water flowing channel, the second shielding portion is provided with a second water draining gap 302, specifically, the second shielding portion configured inside the water flowing channel can realize double-layer blocking, water of the water receiving tray 213 is discharged through the second water draining gap 302 and the first water draining gap 301 in sequence, cold energy in the evaporation cavity is blocked by the two layers of shielding portions, and the external discharge amount of the cold energy is more effectively limited, so as to further improve the refrigeration effect.

In addition, concrete entities for the cold leakage prevention part 3 may include: a top plate 31; two side plates 32, a first baffle plate 33 and a second baffle plate 34, wherein the side plates 32 are connected to the corresponding side edges of the top plate 31 and are positioned below the top plate 31; the first baffle plate 33 is connected to one end part of the top plate 31 and is positioned below the top plate 31, the first baffle plate 33 is arranged outside the evaporation cavity, a first drainage gap 301 is arranged on the first baffle plate 33, and the first baffle plate 33 forms a first shielding part; the second baffle 34 is connected to the middle of the top plate 31 and located below the top plate 31, a second water discharge slit 302 is provided on the second baffle 34, and the second baffle 34 forms a second shielding portion. Specifically, the whole anti-cold leakage component 3 is of a cover type structure with an open end, and the anti-cold leakage component 3 can effectively cover the drainage channel 2131 on one hand and can be attached to the edge of the opening 231 more tightly to block the opening 231 on the other hand. In order to assemble the anti-cold leakage component 3, the side plate 32 is provided with a clamping port 321, the bottom plate 21 is provided with a raised rib 214 for limiting the installation of the cover 23, and the drainage channel 2131 penetrates through the rib 214 and extends to the outside of the evaporation cavity. The curb plate 32 of cold-proof part 3 passes through joint interface 321 card on rib 214, simultaneously for drainage 2131 presss from both sides between two curb plates 32, like this, can utilize cold-proof part 3 to live drainage 2131 parcel, can ensure on the one hand that the water from drainage 2131 drainage smoothly discharges, and on the other hand can more effectual reduction cold volume reveals the outside from drainage 2131. In addition, in order to improve the drainage efficiency, a third drainage gap 303 is formed between the first baffle 33 and the corresponding end of the side plate 32; a fourth water discharge slit 304 is formed between the second barrier 34 and the inner surface of the side plate 32.

In addition, water discharged from the evaporation chamber may directly flow onto the bottom plate 1, and the water is automatically evaporated by heat generated from the compressor 221 and the condenser 222 outside the evaporation chamber, but naturally, a drain hole (not shown) may be provided in the bottom plate 1, a drain pipe may be connected to a position of the drain hole that is lower than the bottom plate 1, and water discharged from the evaporation chamber may flow to the drain hole and be discharged through the drain pipe. The embodiment does not limit the way in which the water discharged from the evaporation chamber is subsequently treated.

The evaporation cavity is communicated with the outside through the opening by arranging the opening on the housing, the opening is internally provided with a cold leakage prevention part, and the cold leakage prevention part is provided with a water drainage gap to meet the requirement that water in the water pan is drained to the outside of the evaporation cavity; simultaneously, leak protection cold component inserts in the opening after in order to plug up the opening, because the drainage gap is less, under the prerequisite that satisfies the drainage, the scattering and disappearing of cold volume in the evaporation cavity can effectually be reduced in the drainage gap, realizes satisfying under the smooth and easy exhaust condition of defrosting water, reduces the revealing of cold volume in the evaporation cavity to improve refrigeration effect and reduce the energy consumption.

Based on the above technical solution, optionally, as shown in fig. 1 to 6, in the process of the refrigeration operation of the evaporator, the temperature in the evaporation cavity is low, and the air in the storage cavity is affected by the moisture contained in the articles in the storage cavity, after entering the evaporation cavity from the air return opening 212, the air in the storage cavity is condensed into water drops after contacting with the housing 23 with a low temperature, and the condensed water flows down onto the bottom plate 21 along the housing 23. In order to ensure that condensed water flowing down along the casing 23 is smoothly guided to the water receiving tray 213 for discharge, so as to prevent the accumulated water from overflowing from the air return opening 212 due to the accumulated water on the bottom plate 21, on one hand, the air guide ring 215 is arranged on the air return opening 212, and on the other hand, a flow guide component is arranged on the bottom plate 21 in the evaporation cavity and is used for guiding the condensed water formed on the casing 23 to the water receiving tray 213. Specifically, the condensed water formed on the housing 23 flows downward to the diversion assembly under the action of gravity, and then the condensed water is guided by the diversion assembly to flow into the water receiving tray 213. In this way, the condensed water can be collected through the water receiving tray 213 and discharged to the outside of the evaporation chamber. One side wall of the flow guide assembly abuts against the peripheral wall of the air guide ring 215, one side wall of the flow guide assembly abuts against the water receiving tray 213, and one side wall of the flow guide assembly abuts against the inner wall of the housing 23. The condensed water condensed on the housing 23 flows onto the flow guide member along the inner wall of the housing 23, and the flow guide member guides the condensed water dropping thereon into the water receiving tray 213.

Further, the flow guide assembly may include two flow guides 100, the two flow guides 100 are distributed on two sides of the wind guide ring 215, a certain space is provided between the water pan 213 and the wind guide ring 215, a space between the water pan 213 and one side of the wind guide ring 215 is denoted as a space a 10, and a space between the water pan 213 and the other side of the wind guide ring 215 is denoted as a space B20. One of the flow guiding bodies 100 is disposed in the space a 10, and the other flow guiding body 100 is disposed in the space B20, and is configured to guide the condensed water flowing down along the inner wall of the housing 23 to the water receiving tray 213, so that the condensed water can be discharged in time. The outer contour of current carrier 100 is determined by the specific shape of space a 10 and space B20.

The baffle 100 includes a first sidewall 110, a second sidewall 120, a third sidewall 130 and a baffle 140, the baffle 140 connects and intersects with the first sidewall 110, the second sidewall 120 and the third sidewall 130, the first sidewall 110 is adapted to abut against the outer side of the wind-guiding ring 215, the second sidewall 120 is adapted to abut against the sidewall of the drain pan 213, and the third sidewall 130 is adapted to abut against the inner wall of the housing 23. The surface of the baffle 100 opposite to the baffle plane 140 is called a bottom surface, which is a planar structure and abuts against the bottom plate 21. In order to achieve the flow guiding effect, the flow guiding surface 140 is configured as an inclined surface structure, which gradually decreases from the direction away from the water pan 213 side to the side close to the 250 water pan, and gradually decreases from the direction close to the air guiding ring 215 side to the side far from the air guiding ring 215.

One side of the housing 23 abutting against the third side wall 130 is an arc-shaped structure, and correspondingly, the third side wall 130 is also provided with the arc-shaped structure, so that the third side wall 130 can be abutted against the inner wall of the housing 23 in a matching manner, and condensed water flowing down along the housing 23 can flow onto the flow guide surface 140.

In order to prevent the condensed water dropping on the flow guide surface 140 from flowing out of the air return opening 212, the meeting intersection position (marked as S) of the first side wall 110 and the flow guide surface 140 is set to be higher than the air guide ring 215. In order to prevent the condensed water dropping on the diversion surface 140 from smoothly flowing into the water receiving tray 213, a position (marked as P) where the second side wall 120 meets the diversion surface 140 is set higher than the side wall of the water receiving tray 213. The condensed water condensed on the housing 23 flows down to the flow guide surface 140 along the inner wall of the housing 23, and flows into the water receiving tray 213 under the flow guide effect of the flow guide surface.

The inclination angle of the flow guide surface 140 from the side far away from the water collector 213 to the side close to the water collector 213 is 8-12 degrees, preferably 10 degrees; the angle of inclination of the deflector surface 140 from the side close to the wind-guiding collar 215 to the side remote from the wind-guiding collar 215 is 8-12 °, preferably 10 °.

In order to prevent condensed water dropping on the flow guide surface 140 near the air return opening 212 from leaking out of the air return opening 212 due to splashing, in this embodiment, a water blocking rib 141 is disposed on one side of the flow guide surface 140 near the air guide ring 215, and the water blocking rib 141 extends and is distributed along the meeting intersection position of the flow guide surface 140 and the first side wall 110.

When the two diversion bodies 100 are installed on the bottom plate 21, one side of the diversion surface 140, which is far away from the air guide ring 215, is retracted into the side wall of the water receiving tray 213, which is abutted against the diversion surface, so that condensed water on the diversion surface 140 can flow into the water receiving tray 213 and cannot flow out of the water receiving tray 213.

The two flow conductors 100 are made of high-density heat-insulating foam, so that the flow conductors 100 have the functions of heat insulation and heat preservation while realizing the flow guiding function, and the loss of cold in the evaporation cavity is reduced.

The above embodiments are only used to illustrate the technical solution of the present invention, and not to limit it; although the present invention has been described in detail with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described in the foregoing embodiments, or that equivalents may be substituted for elements thereof; such modifications and substitutions do not depart from the spirit and scope of the present invention, which is claimed.

Claims

1. A refrigeration unit, comprising:

2. The refrigeration unit as set forth in claim 1 wherein a flow passage is defined between the cold leakage prevention member and the base plate, the cold leakage prevention member being provided with a first curtain portion at an outer end of the flow passage, the first curtain portion being provided with the first drainage gap.

3. The refrigeration unit as set forth in claim 2 wherein the cold leak prevention member is provided with a second curtain portion inside the flow passage, the second curtain portion being provided with a second water discharge slit.

4. The refrigeration unit as set forth in claim 3 wherein said cold leak prevention member comprises:

a top plate;

the two side plates are connected to the corresponding side edges of the top plate and are positioned below the top plate;

the first baffle is connected to one end part of the top plate and located below the top plate, the first baffle is arranged on the outer side of the evaporation cavity, the first drainage gap is formed in the first baffle, and the first baffle forms the first shielding part;

the second baffle is connected to the middle of the top plate and located below the top plate, the second baffle is provided with a second water discharge gap, and the second baffle forms the second shielding portion.

5. The refrigeration unit as set forth in claim 4 wherein a third drainage gap is formed between the first baffle and the corresponding end of the side panel; and a fourth drainage gap is formed between the second baffle and the inner surface of the side plate.

6. The refrigeration unit according to any one of claims 1 to 5, wherein a wind guide ring is arranged on the return air inlet, an evaporation fan is arranged in the wind guide ring, and the wind guide ring and the evaporation fan are positioned in the evaporation cavity;

the refrigeration unit further includes:

the flow guide assembly is arranged on the bottom plate and located in the evaporation chamber, and is used for guiding condensed water formed on the housing to the water receiving tray.

7. The refrigeration unit as set forth in claim 6 wherein the baffle assembly includes two baffles disposed on opposite sides of the wind-directing collar, the baffles being sandwiched between the wind-directing collar and the housing;

the flow guide body comprises a first side wall, a second side wall, a third side wall and a flow guide surface, the flow guide surface is respectively connected and intersected with the first side wall, the second side wall and the third side wall, the first side wall is abutted against the outer peripheral wall of the air guide ring, the second side wall is abutted against the side wall of the water receiving disc, the third side wall is abutted against the inner wall of the housing, the connection intersection position of the first side wall and the flow guide surface is higher than the end face of the air guide ring, and the connection intersection position of the second side wall and the flow guide surface is higher than the side wall of the water receiving disc;

the condensed water dropping on the flow guide body flows into the water receiving tray through the flow guide surface.

8. The refrigeration unit as set forth in claim 7 wherein the deflector surface is a sloped surface that tapers away from the drip pan toward the drip pan and tapers away from the deflector ring toward the deflector ring.

9. The refrigeration unit as set forth in claim 7 wherein a water dam is disposed on the flow directing surface adjacent the air deflector.

10. Refrigeration equipment comprising a cabinet body in which a storage chamber is formed, characterized by further comprising a refrigeration unit as claimed in any one of claims 1 to 9; the refrigerating unit is arranged at the top of the cabinet body, and an air outlet and an air return inlet of the refrigerating unit are respectively communicated with the storage cavity.