CN113091380A - Condensing system and refrigerator - Google Patents

Abstract

The invention provides a condensing system and a refrigerator, which comprise a plurality of layers of reciprocating bent condensing pipes and a plurality of radiating fins arranged in the plurality of layers of reciprocating bent condensing pipes, and further comprise: the heat dissipation system comprises a water storage box, a water outlet pipe and a water pump connected with the water storage box and the water outlet pipe; the water storage box is arranged at the bottom of the condensation pipe and used for collecting accumulated water flowing to the bottom of the condensation pipe; the water pump is used for pumping accumulated water in the water storage box and conveying the accumulated water to the radiating fins at the top of the condenser pipe, so that the accumulated water flows through the radiating fins and/or the condenser pipe from top to bottom.

Description

Condensing system and refrigerator

Technical Field

The invention relates to a condensing system in a refrigerator and the refrigerator with the condensing system.

Background

The refrigerator walk-in can lead to outside hot-air to get into inside the refrigerator after long-time switch door, and cold and hot air gathers in the inside formation defrosting water of refrigerator, and defrosting water flows to in connecing the fin from the drain pipe, if the refrigerator door is not totally closed or ambient temperature is higher, like summer, the drain pipe is to connecing the more water of fin discharge to lead to rivers to spill over the refrigerator outside, lead to ground to produce ponding. The existing method for solving the technical problem is to evaporate defrosting water in the connecting fins by utilizing the heat of the condenser, but the arrangement of the condenser in the refrigerator influences the heat exchange efficiency of the condenser, so that the energy consumption is increased.

In view of the above, there is a need for an improved condensing device in a refrigerator and a refrigerator to solve the above problems.

Disclosure of Invention

The invention aims to solve the problem that the energy consumption of a refrigerator is high due to low evaporation and heat dissipation efficiency of a condensing device in the refrigerator.

The invention provides a condensing system, which comprises a plurality of layers of reciprocating bent condensing pipes and a plurality of radiating fins arranged in the plurality of layers of reciprocating bent condensing pipes, and also comprises: the heat dissipation system comprises a water storage box, a water outlet pipe and a water pump connected with the water storage box and the water outlet pipe; the water storage box is arranged at the bottom of the condensation pipe and used for collecting accumulated water flowing to the bottom of the condensation pipe; the water pump is used for pumping accumulated water in the water storage box and conveying the accumulated water to the radiating fins at the top of the condenser pipe, so that the accumulated water flows through the radiating fins and/or the condenser pipe from top to bottom.

As an optional technical scheme, a plurality of the heat dissipation fins are sequentially stacked along the vertical direction, wherein any adjacent heat dissipation fins are communicated with each other through a water outlet.

As an optional technical scheme, the water outlets on any adjacent radiating fins are far away from each other, so that the accumulated water can flow on the adjacent radiating fins for the maximum distance.

As an optional technical solution, the plurality of heat dissipation fins include first fins inclined toward a first direction and second fins inclined toward a second direction, the first fins and the second fins are arranged at intervals, and the first fins and the second fins are sequentially and alternately arranged; wherein the first direction and the second direction are opposite.

As an optional technical solution, the water outlet pipe has at least one water outlet, and the accumulated water flows out from the at least one water outlet and flows onto the surface of the heat dissipation fin at the top of the condensation pipe.

As an optional technical scheme, the water pump and the water outlet pipe are respectively arranged in close contact with at least one condensing pipe.

As an optional technical scheme, a water level detector is arranged in the water storage box, and when the water level detector measures that the actual water level of accumulated water in the water storage box is greater than or equal to a preset water level, the water pump is started to extract the accumulated water from the water storage box.

As an optional technical scheme, a communication conduit is arranged between the water pump and the water storage box, and the communication conduit comprises a heating device and/or a heat preservation layer, so that accumulated water flowing into the communication conduit from the water storage box and then entering the water pump is liquid water.

As an optional technical solution, the condensing system is disposed in a sealed chamber, the chamber includes an air inlet and an air outlet, the air outlet and the air inlet are disposed on two opposite sides of the condensing tube, and the position of the air outlet is higher than the position of the air inlet.

As an optional technical solution, the air conditioner further comprises a fan, and the fan is respectively arranged at the air outlet and/or the air inlet.

The invention also provides a refrigerator comprising the condensing system.

Compared with the prior art, the condensing system and the refrigerator thereof have the advantages that accumulated water in the water storage box at the bottom of the condensing pipe is pumped by the water pump and flows onto the radiating fins at the top of the condensing pipe from the outlet of the water outlet pipe, so that the accumulated water flows through the radiating fins and the condensing pipe as much as possible, the contact area between the water and the fins and/or the condensing pipe is increased, the evaporation efficiency of the water is increased, and the radiating efficiency of the condensing pipe is improved.

The invention is described in detail below with reference to the drawings and specific examples, but the invention is not limited thereto.

Drawings

Fig. 1 is a schematic view of a condensing unit in a first embodiment of the present invention.

Fig. 2 is a schematic side view of fig. 1.

FIG. 3 is a schematic view of stacked fins in another embodiment of the invention.

Fig. 4 is a schematic cross-sectional view of the fins of fig. 3 stacked on top of each other.

Fig. 5 is a schematic view of a condensing unit in a second embodiment of the present invention.

Fig. 6 is a schematic side view of fig. 5.

Fig. 7 is a schematic view of a condensing unit in a third embodiment of the present invention.

Fig. 8 is a schematic side view of fig. 7.

FIG. 9 is a schematic diagram of a condensing system of the present invention.

FIG. 10 is a schematic view of another condensing system 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 is described in further detail below with reference to embodiments and accompanying drawings. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Fig. 1 is a schematic diagram of a condensing device according to a first embodiment of the present invention, and fig. 2 is a schematic diagram of a side view of fig. 1.

As shown in fig. 1, the condensing device 100 includes a plurality of layers of reciprocating bent condenser tubes 10 and a heat dissipation drainage layer, the heat dissipation drainage layer aims to accelerate evaporation efficiency of accumulated water such as defrosting water, and meanwhile, heat dissipation efficiency of the plurality of layers of reciprocating bent condenser tubes 10 is improved.

The plurality of layers of the condenser pipes 10 which are arranged in a reciprocating bending mode comprise a plurality of layers of first bending parts 11 which are horizontally bent in a reciprocating mode and a plurality of second bending parts 12 which are horizontally bent in a reciprocating mode, the first bending parts 11 of each layer and the second bending parts 12 of each layer are arranged alternately, and the first bending parts 11 of each layer and the second bending parts 12 of each layer are spaced mutually. The first bent portion 11 and the second bent portion 12 are connected to each other through a fourth bent portion 13 extending along the vertical direction, wherein adjacent fourth bent portions 13 are symmetrically arranged along the left-right direction.

In the present embodiment, the horizontal reciprocating bending means that the first bending portion 11 and the second bending portion 12 are respectively bent in a reciprocating manner along a horizontal plane in the front-rear and left-right directions.

In other words, the plurality of layers of reciprocally bent condensation pipes 10 may be regarded as a first bent portion 11 horizontally reciprocally bent and a second bent portion 12 horizontally reciprocally bent alternately arranged in sequence in the vertical direction. The vertical direction corresponds to the up-down direction indicated in fig. 1.

As shown in fig. 1 and 2, the heat dissipation and drainage layer includes first fins 20 and second fins 30 alternately arranged in sequence, the first fins 20 include first slopes 21 inclined toward a first direction, and a first drainage port 22 is disposed at a lowest position of the first slopes; the second fin 30 includes a second slope 31 inclined toward the second direction, and a second drain opening 32 is provided at a lowest position of the second slope 31; wherein the first direction is opposite the second direction such that a maximum distance is provided for water to trickle from the first drain opening toward the second drain opening.

In the present embodiment, the first direction is inclined, for example, toward the lower left, and the second direction is inclined, for example, toward the lower right. The water flows out from the higher position of the first inclined surface 21, through the first inclined surface 21 toward the first drain opening 22 at the lower left, flows into the higher position of the second fin 20 at the lower part, and flows into the second drain opening 32 at the lower right through the guidance of the second inclined surface 22. When the plurality of first fins 20 and the plurality of second fins 30 are alternately arranged, the water flowing from the upper position of the first fin 20 toward the first drain opening 22, into the upper position of the second fin 20, and then out of the second drain opening 32 is repeated, so that the flowing distance of the water flowing through the first fin 20 and the second fin 30 is the longest.

The first fin 20 and the second fin 30 are respectively provided with the inclined surfaces, so that the first fin and the second fin have the advantages that the inclined surfaces on the first fin and the second fin ensure that water does not stay on the surfaces of the first fin 20 and the second fin 30 to form accumulated water; secondly, the inclined plane on the fin guides the water to flow, and the area of contact grow of water on the fin inclined plane, and simultaneously, water is at fin inclined plane thickness attenuation, and contact surface grow and thickness attenuation make water by the flash evaporation easily, and in addition, the steam after the evaporation carries out the heat transfer with condenser pipe 10 for condenser pipe 10's heat dissipation has been accelerated again.

In a preferred embodiment, in order to increase the contact area between the first bent part 11 and the first fin 20 and improve the heat dissipation and evaporation efficiency, the first bent part 11 is inclined toward the first direction, so that the first bent part 11 can be attached to the first inclined surface 21 of the first fin 20, or the first bent part 11 is attached to the first inclined surface 21.

Similarly, in order to increase the contact area between the second bent portion 12 and the second fin 30 and improve the heat dissipation and evaporation efficiency, the second bent portion 12 is inclined toward the second direction, so that the second bent portion 12 can be attached to the second inclined surface 31 of the second fin 30, or the second bent portion 12 is attached to the second inclined surface 31.

For the design that the fins are attached to the upper part of the condensing tube, the first fins and the condensing tube are in direct contact, so that on one hand, the water evaporation efficiency on the fins is improved; on the other hand, the heat dissipation effect of the condensation pipe is improved; the two promote each other. In addition, when the water flowing on the fins is less, the air flows well above the fins, so that the heat dissipation effect is better.

It should be noted that the inclination angles of the first inclined surface 21 and the second inclined surface 31 are not particularly limited in the present invention, and it is only necessary that water can flow on the first inclined surface 21 and the second inclined surface 31 without water accumulation. In addition, the inclination angles of the first inclined surface 21 and the second inclined surface 31 are not too large to affect the arrangement of the condensation pipes 10.

In a preferred embodiment, the angle of inclination of the first inclined surface 21 may be different from or mirror the same as the angle of inclination of the second inclined surface 31. Wherein the inclination angle of the first inclined surface 21 and the inclination angle of the second inclined surface 31 are in mirror-image same relationship, that is, the first direction and the second direction are in mirror-image symmetrical relationship.

In a preferred embodiment, the first slope 21 completely covers the first bottom wall of the first fin 20, i.e. the first bottom wall is inclined towards said first direction; the second slope 31 completely covers the second bottom wall of the second fin 30, i.e., the second bottom wall is inclined toward the second direction. Wherein the first drain opening 22 is located on a first side (e.g., left side) of the first bottom wall and the second drain opening 32 is located on a second side (e.g., right side) of the second bottom wall, the first and second sides being remote.

Referring to fig. 3 and 4, in another embodiment of the present invention, the first fin 20 further includes a third inclined surface 211, a connection point of the third inclined surface 211 and the first inclined surface 21 is a lowest position of the first bottom wall of the first fin 20, and the first drain opening 22 is disposed at the connection point; the second fin 30 further includes a fourth inclined surface 311, a connection position of the fourth inclined surface 311 and the second inclined surface 31 is a lowest position of the second bottom wall of the second fin 30, and the second drain opening 32 is disposed at the connection position.

Wherein the first inclined surface 21 and the third inclined surface 211 substantially form a V-shaped structure; the second slope 31 and the fourth slope 311 also form a substantially V-shaped structure. The two sides of the V-shaped structure do not necessarily need to be symmetrical. When the bottom wall of the fin is provided with the plurality of inclined surfaces, the water evaporation device can be used for accelerating the flowing speed of water, increasing the contact area and accelerating the evaporation efficiency of the water. In addition, the problem that water flows out from the edge of the inclined plane and is easy to spill can be prevented.

In a preferred embodiment, the first drain opening 22 may be a slit portion extending in the front-rear direction of the first fin 20 at the junction of the first inclined surface 21 and the third inclined surface 211; the second drain opening 32 may be another slit portion extending in the front-rear direction of the first fin 20 at the junction of the first inclined surface 21 and the third inclined surface 211.

In a preferred embodiment, the first fin 20 is provided with a first baffle 23 extending upward corresponding to the second drain opening 32 of the second fin 30; the second fin 30 is provided with a second baffle 33 extending upward corresponding to the first drain port 22 of the first fin 20; the first baffle 23 is used to prevent water from splashing when the water flows from the second drain opening 32 to the upper position of the first fin 20, and the second baffle 33 is used to prevent water from splashing when the water flows from the first drain opening 22 to the upper position of the second fin 30.

As shown in fig. 1, the first baffle plate 23 further comprises two first extension arms 231, such that the first baffle plate 23 is disposed substantially around the first slope 21 except for the area of the first drain opening 22; the second baffle 33 also includes two second extension arms 34 such that the second baffle 33 is disposed substantially around the area of the second ramp 31 exiting the second drain opening 32. The baffle is designed around the inclined plane of the fins, so that water can be prevented from splashing when flowing between the fins to the maximum extent.

FIG. 5 is a schematic view of a condensing unit in a second embodiment of the present invention; fig. 6 is a schematic side view of fig. 5. The same reference numerals in fig. 5 and 6 as those in fig. 1 and 2 denote the same elements, and have similar functions, as described above with reference to the first embodiment.

As shown in fig. 5 and 6, a condensing apparatus 200 according to a second embodiment of the present invention is different from the condensing apparatus 100 in that a plurality of first fins 20 and second fins 30 alternately arranged in sequence are respectively attached to the lower portion of the condensing tube 10.

The first fins 20 are attached to the lower side of the first bent portion 11, and the second fins 30 are attached to the lower side of the second bent portion 12, and are alternately arranged in this order.

Compared with the condensing device 100, the fin is attached to the lower part of the condensing tube, and the fin is directly contacted with the condensing tube, so that on one hand, the water evaporation efficiency on the fin is improved; on the other hand, the heat dissipation effect of the condensation pipe is improved; the two promote each other. In addition, when more water flows on the fins, the water is directly contacted with the condensing tubes on the fins, so that the heat dissipation effect is better.

FIG. 7 is a schematic view of a condensing unit in a third embodiment of the present invention; fig. 8 is a schematic side view of fig. 7.

As shown in fig. 7 and 8, a condensing device 300 according to a third embodiment of the present invention is different from the condensing device 100 according to the first embodiment in that a third bent portion 310 of a multi-layered reciprocally bent condensing tube is reciprocally bent in a vertical plane, and first fins 320 and second fins 330 alternately arranged are inserted through the multi-layered third bent portion 310. The first fin 320 and the second fin 330 have substantially the same structure as the first fin 20 and the second fin 30 of the condensation devices 100 and 200.

Referring to the condensing apparatus 300 shown in fig. 7, the plurality of layers of reciprocally bent and arranged condensing tubes include a plurality of layers of vertically reciprocally bent third bent portions 310, and any two adjacent layers of the third bent portions 310 are connected to each other by a fifth bent portion 312 extending along the horizontal direction, wherein the adjacent fifth bent portions 312 are symmetrically disposed along the front-back direction.

In this embodiment, the vertical reciprocating bending means that the third bending portion 310 is bent back and forth along a vertical plane in which the front, back, up and down directions are located.

In other words, the plurality of layers of reciprocally bent condensation pipes in the condensation device 300 can be regarded as the third bending parts 310 which are vertically reciprocally bent and arranged at intervals in sequence in the horizontal direction. The horizontal direction corresponds to the left-right direction indicated in fig. 7.

The heat dissipation and drainage layer in the condensation device 300 includes first fins 320 and second fins 330 alternately arranged in a vertical direction, the first fins 320 include first slopes 321 inclined toward the first direction, and the lowest position of the first slopes provides a first drainage port 322; the second fin 330 includes a second slope 331 inclined toward the second direction, and a second drain opening 332 is provided at a lowest position of the second slope 331; wherein the first direction is opposite the second direction such that the distance that water flows from the first drain opening 322 towards the second drain opening 332 is maximized.

A plurality of first through holes 3211 are formed in the first fin 320, and the plurality of first through holes 3211 penetrate the first inclined surface 321, so that the third bending portion 310, which is bent to and fro along the vertical direction, can penetrate through the plurality of first through holes 3211; the second fin 330 is provided with a plurality of second through holes 3311, and the plurality of second through holes 3311 penetrate the second inclined plane 331, so that the third bending portion 310, which is bent back and forth along the vertical direction, can be inserted into the plurality of second through holes 3311. The plurality of first through holes 3211 and the plurality of second through holes 3311 correspond to each other one by one, and the arrangement of the plurality of first through holes 3211 and the plurality of second through holes 3311 is consistent with the arrangement of the plurality of layers of vertically and reciprocally bent third bending portions 310, so that the third bending portions 310 can sequentially pass through the first through holes 3211 and the second through holes 3311.

In this embodiment, the first through holes 3211 and the second through holes 3311 are track holes and circular holes, and the track holes are formed along the front and rear directions of the first fin 320 and the second fin 330. The circular hole is used for fixing the first bending part 310 connected with the fifth bending part 312.

In the present embodiment, the first direction is inclined, for example, toward the lower left, and the second direction is inclined, for example, toward the lower right. The water flows out from the higher position of the first inclined surface 321, through the first inclined surface 321 toward the first drain port 322 at the lower left, flows into the higher position of the second fin 330 at the lower side thereof, and flows into the second drain port 332 at the lower right through the guidance of the second inclined surface 331. When the plurality of first fins 20 and the plurality of second fins 30 are alternately arranged, the water flowing from the upper position of the first fin 20 toward the first drain opening 22, into the upper position of the second fin 20, and then out of the second drain opening 32 is repeated, so that the flowing distance of the water flowing through the first fin 20 and the second fin 30 is the longest.

In the condensing device 300, because the first fins 320 and the second fins 330 are sequentially and alternately arranged in the vertical direction, and the third bending portion 310 of the condensing tube, which is bent in a reciprocating manner vertically, penetrates through the first fins 320 and the second fins 330, when water flows over the first inclined surface 321, a part of the water enters the first through hole 3211 on the first inclined surface 321 and flows vertically downward along the outer wall of the first bending portion 310 until the water flows to the bottom of the condensing tube; another part of the water flows out of the first water discharge port 322, flows into a higher position of the second fin 330, flows into the second water discharge port 332, and flows circularly to the bottom of the condensation pipe.

Therefore, the condensing device 300 has the advantages of the condensing devices 100 and 200, including the prevention of water accumulation of fins and the increase of evaporation efficiency of water, and the improvement of heat dissipation efficiency of the condensing tube; the fin is convenient to install (1) the through hole; (2) the through hole can contact with the condensing tube and flow down along the condensing tube when water flows through the through hole; (3) the through holes increase the fluidity of air in the condensation pipe; (4) the through holes also increase the probability that more water flows through more condensing tubes, thereby improving the heat dissipation and evaporation efficiency; the water is dispersed to flow, so that the evaporation of the water and the heat dissipation of the condenser pipe are further accelerated.

In a preferred embodiment, the inclination angle of the first inclined surface 321 may be different from or mirror the same as the inclination angle of the second inclined surface 331. The inclination angle of the first inclined plane 321 and the inclination angle of the second inclined plane 331 are in mirror-image relationship, that is, the first direction and the second direction are in mirror-image relationship.

In a preferred embodiment, the first slope 321 completely covers the first bottom wall of the first fin 320, i.e., the first bottom wall is inclined toward the first direction; the second slope 331 completely covers the second bottom wall of the second fin 330, i.e., the second bottom wall is inclined toward the second direction. Wherein the first drain opening 322 is located on a first side (e.g., left side) of the first bottom wall, and the second drain opening 332 is located on a second side (e.g., right side) of the second bottom wall, the first and second sides being remote.

In a preferred embodiment, the first fin 320 is provided with a first baffle 323 extending upward corresponding to the second drain opening 32 of the second fin 330; the second fin 330 is provided with a second baffle 333 extending upward corresponding to the first drain port 322 of the first fin 320; the first blocking plate 323 is used to prevent water from splashing when the water flows from the second drain opening 32 to the upper position of the first fin 320, and the second blocking plate 333 is used to prevent water from splashing when the water flows from the first drain opening 322 to the upper position of the second fin 330.

As shown in fig. 1, the first baffle 323 further includes two first extension arms 3231 such that the first baffle 323 is disposed substantially around the first sloped surface 321 except for the area of the first drain port 322; the second baffle 333 also includes two second extension arms 3331 such that the second baffle 333 is disposed substantially around the area of the second sloped surface 331 exiting the second drain opening 332. The baffle is designed around the inclined plane of the fins, so that water can be prevented from splashing when flowing between the fins to the maximum extent.

The invention also provides another condensing system which comprises a plurality of layers of reciprocating bent condensing pipes, a plurality of radiating fins arranged in the plurality of layers of reciprocating bent condensing pipes and a radiating system, wherein the radiating system comprises a water storage box, a water outlet pipe and a water pump connected with the water storage box and the water outlet pipe; the water storage box is arranged at the bottom of the condensation pipe and used for collecting accumulated water flowing to the bottom of the condensation pipe; the water pump is used for pumping accumulated water in the water storage box, and the accumulated water is conveyed to the radiating fins at the top of the condensing tube, so that the accumulated water flows through the radiating fins and/or the condensing tube from top to bottom, and the evaporation efficiency of the radiating fins and the radiating efficiency of the condensing tube in the condensing system are improved.

In a preferred embodiment, a plurality of radiating fins are stacked in sequence along the vertical direction, and the water outlet pipe sprays the accumulated water onto the radiating fins on the highest layer. The water outlets of any adjacent radiating fins are mutually communicated through the water outlets, and the water outlets of any adjacent radiating fins are better away from each other, so that the accumulated water can flow on the adjacent radiating fins for the maximum distance, and the evaporation and radiating efficiency is improved.

Preferably, the plurality of heat dissipation fins comprise first fins inclined towards a first direction and second fins inclined towards a second direction, the first fins and the second fins are arranged at intervals, and the first fins and the second fins are sequentially and alternately arranged; wherein the first direction and the second direction are opposite.

In a preferred embodiment, the water outlet pipe is provided with at least one water outlet, and the accumulated water flows out of the at least one water outlet and flows onto the heat dissipation fins on the top of the multi-layer reciprocating bent condensation pipe. In the invention, the water flowing out of the water outlet flows onto the surface of the radiating fin on the top of the condenser, and is not preferably sprayed onto the radiating fin, so that the interference of the fan blowing and/or sucking on the water sprayed onto the radiating fin is avoided.

In a preferred embodiment, the water pump and the water outlet pipe are respectively arranged in close contact with at least one condensation pipe. And water flows in the water pump and the water outlet pipe to exchange heat with the condenser pipe, so that the heat dissipation efficiency of the condenser pipe is improved.

In a preferred embodiment, a water level detector is arranged in the water storage box, and when the actual water level of the accumulated water in the water storage box measured by the water level detector is greater than or equal to a preset water level, the water pump is started to pump the accumulated water from the water storage box into the water outlet pipe.

In a preferred embodiment, a communication conduit is arranged between the water pump and the water storage box, and the communication conduit comprises a heating device and/or an insulating layer, so that accumulated water flowing into the communication conduit from the water storage box and then entering the water pump is liquid water.

In a preferred embodiment, the condensing system is generally disposed in a sealed compartment, the compartment includes an air inlet and an air outlet, the air outlet and the air inlet are disposed on opposite sides of the condensing tube, and the air outlet is higher than the air inlet.

The position of the air outlet is higher than that of the air inlet, so that hot air flows out of the upper portion of the condensing system, cold air flows in from the lower portion of the condensing system, air circulation inside the condensing system can be achieved even when a fan is not arranged, and evaporation and heat dissipation efficiency is improved.

Of course, in order to increase the air circulation, a fan may be provided at the outlet and/or the inlet, which fan accelerates the inflow and/or outflow of the cool air. The problem that the fan and the condenser of the existing refrigerator are arranged in the same chamber, even if the fan blows air to the condenser, the generated air flow repeatedly flows in the chamber, and the exchange of the air outside the chamber is difficult, so that the heat dissipation and the moisture evaporation of a condensation pipe are seriously influenced is avoided; in the invention, the relative positions of the air inlet and the air outlet are changed, so that the air inside and outside the compartment is exchanged, hot air is discharged from the air outlet above the air inlet and/or cold air flows in from the air inlet, the air flow exchange inside and outside the compartment is accelerated, and the heat dissipation and the moisture evaporation of the condenser pipe are faster.

The heat dissipation system in the above-mentioned condensation system can be adapted to the condensation tube and the heat dissipation fins of the existing condensation device, but not limited thereto. As a more preferable embodiment, it can be used in combination with any of the above-described condensation devices in the first, second, and third embodiments of the present invention.

The following description will take the example of the heat dissipation system used in conjunction with the above-described condensing devices 100, 300.

FIG. 9 is a schematic diagram of a condensing system of the present invention.

As shown in fig. 9, the condensing system 400 includes a condensing device 100 and a heat dissipation system, the heat dissipation system includes a water pump 110 connected to a water storage box 140 and a water outlet pipe 120, the water storage box 140 is disposed at the bottom of the condensing pipe for receiving water flowing back and forth from the first fins 20 and the second fins 30; the water outlet pipe 120 is disposed at one side of the condensation pipe, and includes at least one water outlet 121, and water flows from the at least one water outlet 121 to the first inclined surface 21 of the first fin 20 at the top of the condensation pipe (as shown in fig. 1). The water flows out from the left side of the first fin 20, flows in from the left side of the second fin 30, flows out from the right side of the second fin 30, and repeatedly flows until the water flows into the water storage box 140.

In the condensing system 400, the water stored in the water storage box 140 is increased by the water pump 110 to flow through the first fins 20 and the second fins 30, so that the contact area is increased, and the evaporation and heat dissipation efficiency is increased.

The fans 130 may be disposed at the air outlets and/or air inlets on opposite sides of the compartment of the condensing system 400.

For other features, functions and effects of the water pump 110, the water outlet pipe 120, the water storage box 140 and the fan 130, reference is made to the above description of the condensing system.

FIG. 10 is a schematic view of another condensing system of the present invention.

As shown in fig. 10, the condensing system 500 includes a condensing device 300 and a heat dissipation system, the heat dissipation system includes a water pump 301 connected to a water storage box 304 and a water outlet pipe 302, the water storage box 304 is disposed at the bottom of the condensing pipe and is used for receiving water flowing back and forth from the first fins 320 and the second fins 330; the water outlet pipe 302 is disposed at one side of the condensation pipe, and includes at least one water outlet port 3021, and water flows from the at least one water outlet port 3021 to the first inclined surface 321 of the first fin 320 at the top of the condensation pipe (as shown in fig. 1). The water flows out from the left side of the first fin 320, flows in from the left side of the second fin 330, and flows out from the right side of the second fin 330, and the water flows repeatedly until the water flows into the water storage 304.

In the condensing system 500, the water accumulated in the water storage box 304 is increased by the water pump 301 to flow through the first fin 320 and the second fin 330 and pass through the through holes in the first fin 320 and the second fin 330, so that the water can flow along the condensing pipe, the contact area is obviously increased, and the evaporation and heat dissipation efficiency is increased.

The fans 303 may be provided at air outlets and/or air inlets on opposite sides of the compartment of the condensing system 500.

For other features, functions and effects of the water pump 301, the water outlet pipe 302, the water storage box 304 and the fan 303, reference is made to the above description of the condensing system.

The present invention also provides a refrigerator including one of the condensing apparatus 100, 200, 300 or the condensing system 400, 500.

In summary, according to the condensing device and the refrigerator thereof provided by the invention, the condensing tube of the condensing device is provided with the first fins and the second fins which are inclined towards different directions and are alternately arranged at intervals, and by virtue of the inclined or inclined surface design, water accumulation of the fins is avoided, the contact area between water and the fins and/or the condensing tube is increased, the evaporation efficiency of water is increased, and the heat dissipation efficiency of the condensing tube is improved.

In addition, according to the condensation system and the refrigerator thereof, accumulated water in the water storage box at the bottom of the condensation pipe is pumped by the water pump and flows to the heat dissipation fins at the top of the condensation pipe from the outlet of the water outlet pipe, so that the accumulated water flows through the heat dissipation fins and the condensation pipe as much as possible, the contact area between the water and the fins and/or the condensation pipe is increased, the evaporation efficiency of the water is increased, and the heat dissipation efficiency of the condensation pipe is improved.

The present invention is capable of other embodiments, and various changes and modifications may be made by one skilled in the art without departing from the spirit and scope of the invention.

Claims (11)

1. The utility model provides a condensing system, includes a plurality of layers of condenser pipe of reciprocal buckling and sets up a plurality of radiating fin in a plurality of layers of condenser pipe of reciprocal buckling, its characterized in that still includes:

the heat dissipation system comprises a water storage box, a water outlet pipe and a water pump connected with the water storage box and the water outlet pipe;

the water storage box is arranged at the bottom of the condensation pipe and used for collecting accumulated water flowing to the bottom of the condensation pipe; the water pump is used for pumping accumulated water in the water storage box and conveying the accumulated water to the radiating fins at the top of the condenser pipe, so that the accumulated water flows through the radiating fins and/or the condenser pipe from top to bottom.

2. The condensing system according to claim 1, wherein a plurality of said heat dissipating fins are stacked in series in a vertical direction, and wherein any adjacent ones of said heat dissipating fins are communicated with each other through a drain opening.

3. A condensing system according to claim 2, wherein the drain openings of any adjacent fins are spaced apart so that the accumulated water is able to flow the greatest distance over the adjacent fins.

4. The condensing system as claimed in claim 2, wherein the plurality of heat dissipating fins includes a first fin inclined toward a first direction and a second fin inclined toward a second direction, the first fin and the second fin are spaced apart from each other, and the first fin and the second fin are alternately arranged in sequence; wherein the first direction and the second direction are opposite.

5. A condensing system according to claim 1, wherein said outlet tube has at least one outlet from which said standing water flows out and onto the surface of said fins at the top of said condenser tube.

6. A condensing system according to claim 1, wherein said water pump and said outlet tube are each positioned in close proximity to at least one of said condenser tubes.

7. The condensing system as claimed in claim 1, wherein a water level detector is disposed in the water storage box, and when the water level detector measures that an actual water level of the accumulated water in the water storage box is greater than or equal to a preset water level, the water pump is started to pump the accumulated water from the water storage box.

8. A condensing system according to claim 7, characterised in that a communication conduit is provided between the water pump and the water storage box, the communication conduit including heating means and/or an insulating layer, such that the accumulated water flowing from the water storage box into the communication conduit and into the water pump is liquid water.

9. A condensing system according to claim 1, wherein said condensing system is disposed in a sealed compartment, said compartment includes an air inlet and an air outlet, said air outlet and said air inlet are disposed on opposite sides of said condenser tube, and said air outlet is disposed at a position higher than said air inlet.

10. A condensing system according to claim 9, further comprising a fan, wherein said fan is disposed at said outlet and/or said inlet respectively.

11. A refrigerator comprising a condensing system, characterized in that it is a condensing system according to any one of claims 1 to 10.

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