CN211316654U - Evaporative condenser and air conditioning system thereof - Google Patents

Abstract

An evaporative condenser and an air conditioning system thereof relate to the field of refrigeration equipment, and the evaporative condenser comprises a heat exchanger, a water spray assembly arranged at the front end of the heat exchanger and a fan arranged at the rear end of the heat exchanger; the heat exchanger comprises a conveying pipe and a plurality of fins which are uniformly arranged on the conveying pipe; each fin comprises a bending part positioned at the front end and a main body part positioned at the rear end, an angle formed by the main body part and the bending part is an obtuse angle, and the conveying pipe sequentially penetrates through the main body part; a diversion trench is formed in one side, close to the water spraying assembly, of the bent part, and the diversion trench extends to a bent part between the main body part and the bent part from the front end of the bent part; and the bent part is provided with an overflowing hole. The evaporative condenser can greatly reduce water drops taken away by the fan and water drops flowing out of the gaps of the fins, and improve the utilization rate of cooling water; in addition, the water distribution on the surface of the fin can be uniform, and the heat exchange efficiency of the evaporative condenser is improved.

Description

Evaporative condenser and air conditioning system thereof

Technical Field

The utility model relates to a refrigeration plant field especially relates to an evaporative condenser and air conditioning system thereof.

Background

With the continuous development of economy, the living standard of human beings is continuously improved, and refrigeration equipment such as an air conditioner is required in daily life. In the case of a conventional refrigerating air conditioner on the market, the refrigerating air conditioner generally comprises a compressor, a condenser, an evaporator, a four-way valve, a one-way valve capillary tube assembly and the like, wherein the condenser is installed outdoors and is used for converting gas or vapor into liquid and transferring heat in the tube to air near the tube in a rapid manner. The condenser operation is exothermic and therefore the condenser temperature is high. Therefore, the condenser must be cooled by heat dissipation, most of the existing condensers adopt an air cooling mode, and the outdoor condenser takes air as a cold source, so that the heat dissipation effect is poor.

Among the existing condenser, for example, utility model patent with publication number CN203869374U discloses a finned heat exchanger, an air conditioner indoor unit and an air conditioner, the finned heat exchanger includes a heat exchange tube and a fin sleeved outside the heat exchange tube, and a water chute is provided on the fin. The finned heat exchanger that this technique provided, the guiding gutter has been seted up on its fin, when having the comdenstion water to produce on the fin, because the area of contact of guiding gutter and water droplet is greater than the smooth plane of fin among the prior art and the area of contact of water droplet, make the water droplet attach the wall mobility good, the water droplet can smoothly flow along the guiding gutter under the effect of self gravity like this, and then discharge the comdenstion water finned heat exchanger, avoid the comdenstion water to gather on the fin of finned heat exchanger, influence the heat exchange efficiency and the heat transfer effect of finned heat exchanger, solved among the prior art because of the fin surface is the plane, easily form the water bridge between the fin that the fin interval causes, influence heat exchanger air inlet and heat exchange efficiency scheduling problem. Although the water guide groove of the heat exchanger solves the problem of accumulation of condensed water and improves the heat exchange effect, the heat exchanger is air-cooled, the heat dissipation effect is poor, when the outdoor environment temperature rises, the condensation pressure of an air conditioning system also rises, the performance of an air conditioning unit is reduced, and the energy consumption is increased.

Nowadays, the evaporative cooling technology has a wide application prospect as an energy-saving air conditioning mode. Some of traditional evaporative condensers spray cooling water by adopting nozzles or spray pipes, water mist sprayed by the nozzles is sucked among condenser fins under the driving of a fan, and the water mist evaporates and absorbs heat of the surrounding environment of the condenser, so that the heat exchange effect of the condenser is improved. The water spraying mode can quickly increase the heat exchange temperature difference between the condenser and the environment, but has some problems.

For example, the utility model with the publication number CN201293595Y discloses a deflector for an evaporative cooling device, which comprises a base plate portion and a folded plate portion extending backwards from the lower side of the base plate portion, wherein the included angle between the folded plate portion and the base plate portion is an obtuse angle; at least one row of through holes are arranged on the folding plate part. Because the technology is provided with the through hole on the folded plate part and has the structure that the folded plate part and the base plate part form an obtuse angle to be crossed, water drops taken away by air can be greatly reduced, and the cooling water consumption of evaporative cooling equipment is reduced. The above-described baffle for an evaporative cooling apparatus has the following problems:

when the guide plate is used, under the suction action of the fan, water vapor in the evaporative condenser is pumped out of the evaporative condenser from the lower part of the folded plate part. Because the utility model is provided with the through holes on the folded plate part and has the structure that the folded plate part and the base plate part form the obtuse angle intersection, on one hand, the water drops taken away by the air can be reduced, the cooling water consumption is reduced, the water floating rate of the equipment is reduced, and the utilization coefficient of the cooling water is improved; on the other hand, the phenomenon of vortex air flow generated when the wet air passes through the guide plate can be avoided. The evaporative condenser blocks cooling water through the guide plate after cooling and heat dissipation, but the cooling water sprayed by the nozzle flows out from the gaps of the fins of the condenser and is diffused to the surrounding environment under the suction action of the fan, so that a large amount of water is consumed, and the utilization rate of the cooling water is low. In addition, the water drops sprayed from the nozzles are concentrated, and the uniform distribution of the water drops among the fins of the condenser is difficult to realize.

Disclosure of Invention

The utility model aims to avoid the defects in the prior art and provide an evaporative condenser which can greatly reduce the water drops taken away by a fan and the water drops flowing out from the gaps of fins, has good water collecting efficiency, reduces the waste of water resources and improves the utilization rate of cooling water; in addition, the evaporative condenser can also enable the surfaces of the fins to be uniformly distributed with water, and the heat exchange efficiency of the evaporative condenser is improved.

Another object of the present invention is to provide an air conditioning system of an evaporative condenser.

The purpose of the utility model is realized through the following technical scheme:

an evaporative condenser comprises a heat exchanger, a water spraying assembly arranged at the front end of the heat exchanger and used for spraying cooling water to the heat exchanger, and a fan arranged at the rear end of the heat exchanger and used for extracting hot air around the heat exchanger; the heat exchanger comprises a conveying pipe for conveying refrigerant and a plurality of fins uniformly arranged on the conveying pipe; wherein the content of the first and second substances,

each fin comprises a bending part positioned at the front end and used for blocking cooling water and a main body part positioned at the rear end, an angle formed by the main body part and the bending part is an obtuse angle, and the conveying pipe sequentially penetrates through the main body part;

a diversion trench for guiding blocked cooling water to the main body part is arranged on one side of the bent part close to the water spray assembly, and the diversion trench extends from the front end of the bent part to a bent part between the main body part and the bent part;

the bent portion is provided with an overflowing hole for discharging part of the cooling water to the space between the main body portions.

The working principle of the evaporative condenser is as follows:

when the cooling water spraying assembly sprays cooling water to the heat exchanger, the bent parts at the front ends of the fins block part of the cooling water, the bent parts are fully distributed with cooling water drops, the water drops flow downwards along the front walls of the bent parts under the self gravity, when the water drops flow to the diversion trenches, the water drops flow to the bent parts along the diversion trenches, the water drops are driven by the fan to be blown to the main body parts of the fins, and the water drops are evaporated and absorb heat due to higher surface temperature of the fins, so that the ambient temperature around the heat exchanger is reduced; because be equipped with the discharge orifice on the portion of bending, when the cooling water sprays at the portion of bending, tiny water droplet can pass the discharge orifice, under the fan drive, move to the space between the main part, because the fin temperature is high, lead to the space temperature between the main part also to rise, tiny water droplet can evaporate under high temperature, absorb the heat on every side, also play and reduce heat exchanger ambient temperature, the discharge orifice plays the gas-liquid separation effect, stop more water droplets at the fin portion of bending, the water conservation effect is showing.

The utility model discloses a preferred scheme, wherein, the guiding gutter sets up downwards along the slope of department of bending, and its benefit lies in, is favorable to the cooling water to the department of bending flow on the guiding gutter for the cooling water becomes the membrane under fan suction effect and blows to the main part of fin, reduces heat exchanger ambient temperature with higher speed.

Preferably, the flow guide grooves are arranged vertically and uniformly downwards along the bent parts, so that cooling water on the bent parts can be better gathered on the flow guide grooves, the water distribution uniformity of the surfaces of the fins is improved, and the heat exchange efficiency is improved.

Preferably, the overflowing hole is arranged between the two adjacent guide grooves, and the function of the overflowing hole is that when the bent part blocks cooling water, part of fine water drops can better pass through the overflowing hole, so that the ambient temperature around the heat exchanger is directly reduced.

Furthermore, the overflowing holes are multiple, and the overflowing holes are arranged in a matrix mode in the direction of the flow guide groove, so that the overflowing holes can better achieve a gas-liquid separation effect, and fine water drops can be fully and directly reduced in the ambient temperature of the heat exchanger.

Further, the overflowing holes are arranged in two rows, and each row is provided with at least two overflowing holes.

Preferably, the bent parts account for 10% -20% of the whole fin, and through the design, the structure is compact, the cooling water can be formed into a water film to blow the main body part, and the ambient temperature around the heat exchanger is reduced.

Preferably, the water spray assembly comprises a fixed bracket and a spray nozzle arranged on the fixed bracket, and the fixed bracket is arranged at the front end of the windward side of the fin.

Furthermore, the number of the nozzles is multiple, and the nozzles are arranged on the fixed support in a matrix manner. Through the structure, the bent part can be better ensured within the range of the nozzle, and the cooling liquid is uniformly sprayed on the bent part.

Preferably, the conveying pipe is a copper pipe, which has the advantages of hard texture, corrosion resistance, high temperature resistance, high pressure resistance and capability of being used in various environments.

An air conditioning system of an evaporative condenser comprises a compressor, a throttling device and an evaporator which are sequentially connected through a pipeline, and the air conditioning system further comprises the evaporative condenser, wherein the evaporative condenser, the compressor, the throttling device and the evaporator form a closed circulating system.

The working principle of the air conditioning system of the evaporative condenser is as follows:

when the evaporator works, the compressor continuously sucks vapor generated in the evaporator, compresses the vapor and then sends the compressed vapor to the evaporative condenser, and the compressed vapor is cooled and condensed into liquid at equal pressure and releases the released heat to the environment. The utility model discloses in spray the water droplet to the fin portion of bending through the nozzle, flow to the main part of fin by the filming to the department of bending of fin along the guiding gutter, liquid film water distribution mode makes fin surface water distribution more even, and liquid film evaporation absorbs the environment heat, strengthens the heat transfer difference in temperature between evaporative condenser and surrounding environment, and the heat transfer effect of heat exchanger is showing and is improving. Meanwhile, the bending part of the fin also plays a role in retaining water, and water drops cannot flow into the environment from the fin gap. The liquid condensed by the evaporative condenser is cooled and depressurized by a throttling device to form a gas-liquid mixture, the gas-liquid mixture enters an evaporator, the liquid in the mixture is evaporated in the evaporator, the heat is absorbed to form refrigerant gas, and the refrigerant gas returns to the compressor again, and the cycle is repeated.

The utility model has the advantages that:

1. the utility model discloses a fin sets to bending, the portion of bending is the obtuse angle with the main part, make the portion of bending play the effect that blocks the cooling water, because be equipped with the discharge orifice in the portion of bending, spray when the cooling water is in the portion of bending, make cooling water aqueous vapor liquid separation through the discharge orifice, tiny water droplet can pass the discharge orifice, under the fan drive, move to the space between the main part, because the fin temperature is high, lead to the space temperature between the main part also to rise, tiny water droplet can evaporate under high temperature, absorb heat on every side, also play and reduce heat exchanger ambient temperature around, great water droplet can be blockked in the portion of bending, can the significantly reduced is taken away the water droplet by the fan, good water efficiency of receiving has, reduce the waste of water resource, improve the utilization ratio of cooling water.

2. The utility model discloses a set up the guiding gutter, at first by keeping off at the fin portion of bending through nozzle spun cooling water, collect the guiding gutter in along the guiding gutter flow under self action of gravity, finally be inhaled the fin surface with the liquid film form under the drive of fan, improve evaporative condenser heat exchange efficiency, in addition, the compression work that unit refrigerant consumed also reduces thereupon, plays energy-conserving effect.

3. Compared with the prior art CN201293595Y, the utility model discloses a bend on the fin is located the air inlet end, and faces water spray assembly, therefore water spray assembly spray water smoke and air current mix when moving forward, receive the hindrance of bend at first, intercept partial water smoke, the water smoke that intercepts forms the liquid film under the air current effect and reaches the fin main part and participate in the heat dissipation to avoid partial water smoke to directly flow through between the fin main part and can not fully exert its radiating effect, make the radiating effect better; in the CN201293595Y in the prior art, the folded plate portion is disposed at the air outlet end of the evaporative condenser, although the amount of water vapor carried away by the airflow can be reduced, the blocked water vapor cannot fully participate in evaporation and heat dissipation, and the heat dissipation effect is not good.

Drawings

The invention is further described with the aid of the accompanying drawings, in which, however, the embodiments do not constitute any limitation to the invention, and for a person skilled in the art, other drawings can be derived from the following drawings without inventive effort.

Fig. 1 is a schematic diagram of an evaporative condenser and an air conditioning system thereof according to the present invention.

Fig. 2 is a schematic view of a three-dimensional structure of a heat exchanger and a water spray assembly in an evaporative condenser of the present invention.

Fig. 3 is a top view of the heat exchanger and the water spray assembly in the evaporative condenser of the present invention.

Fig. 4 is a schematic structural diagram of a fin in a heat exchanger according to the present invention.

Detailed Description

The invention will be further described with reference to the following examples.

Example 1

Referring to fig. 1 to 4, an evaporative condenser of the present embodiment includes a heat exchanger 1, a water spray assembly 2 disposed at a front end of the heat exchanger 1 for spraying cooling water to the heat exchanger 1, and a fan 3 disposed at a rear end of the heat exchanger 1 for extracting hot air around the heat exchanger 1; the heat exchanger 1 comprises a conveying pipe 4 for conveying refrigerant and a plurality of fins 5 uniformly arranged on the conveying pipe 4; each fin 5 comprises a bending part 5-1 positioned at the front end and used for blocking cooling water and a main body part 5-2 positioned at the rear end, an angle formed by the main body part 5-2 and the bending part 5-1 is an obtuse angle, and the conveying pipe 4 sequentially penetrates through the main body part 5-2; a diversion trench 5-3 for guiding blocked cooling water to the main body part 5-2 is arranged on one side of the bending part 5-1 close to the water spray assembly 2, and the diversion trench 5-3 extends from the front end of the bending part 5-1 to a bending part between the main body part 5-2 and the bending part 5-1; the bent part 5-1 is provided with an overflowing hole 5-4 for discharging part of cooling water between the main body parts 5-2.

Referring to fig. 1-4, the flow guide grooves 5-3 are arranged obliquely downward along the bent portions, which is beneficial to cooling water flowing to the bent portions on the flow guide grooves 5-3, accelerates the cooling water to form a film under the suction action of the fan 3 and blow to the main body portions 5-2 of the fins 5, and accelerates the reduction of the ambient temperature around the heat exchanger 1.

Referring to fig. 1-4, the flow guide grooves 5-3 are multiple and are uniformly arranged vertically and downwardly along the bent portions 5-1, so that the cooling water on the bent portions 5-1 can be better gathered on the flow guide grooves 5-3, the water distribution uniformity on the surface of the fin 5 is improved, and the heat exchange efficiency is improved.

Referring to fig. 1-4, the overflowing hole 5-4 is disposed between the two adjacent guide grooves 5-3, and functions to allow a part of fine water droplets to better pass through the overflowing hole 5-4 while the bent portion 5-1 blocks the cooling water, so as to directly reduce the ambient temperature around the heat exchanger 1.

Referring to fig. 1-4, a plurality of overflowing holes 5-4 are arranged in a matrix along the direction of the flow guide groove 5-3, so that the overflowing holes 5-4 can better perform a gas-liquid separation function, and fine water droplets can be fully and directly reduced in ambient temperature around the heat exchanger 1.

Referring to fig. 1-4, the overflow holes 5-4 are in two rows of at least two.

Referring to fig. 1-4, the bent portion 5-1 accounts for 10% -20% of the whole fin 5, and by means of the design, the structure is compact, a water film formed by cooling water can be blown to the main body portion 5-2, and the ambient temperature around the heat exchanger 1 is reduced.

Referring to fig. 1-4, the water spray assembly 2 includes a fixing bracket 6 and a nozzle 7 disposed on the fixing bracket 6, wherein the fixing bracket 6 is disposed at the front end of the windward side of the fin 5.

Referring to fig. 1 to 4, the plurality of nozzles 7 are arranged in a matrix on the fixing bracket 6. Through the structure, the bent part 5-1 can be better ensured within the range of the nozzle 7, and the cooling liquid can be uniformly sprayed on the bent part 5-1.

Referring to fig. 1 to 4, the operation principle of the evaporative condenser is as follows:

referring to fig. 1-4, during operation, a refrigerant in a conveying pipe 4 of a heat exchanger 1 is changed from gas to liquid, and a large amount of heat is emitted, at this time, a fan 3 operates, the heat exchanger 1 is sucked by the fan 3 to extract hot air from the heat exchanger 1, when a water spray assembly 2 sprays cooling water to the heat exchanger 1, a part of the cooling water is blocked by a bent part 5-1 at the front end of a fin 5, the bent part 5-1 is fully distributed with cooling water drops, and the water drops flow downwards along the front wall of the bent part 5-1 under the self gravity, when the water drops flow to the diversion trench 5-3, the water drops flow to the bent part along the diversion trench 5-3, driven by the fan 3, the water drops form a film and are blown to the main body part 5-2 of the fin 5, and the water drops form a liquid film to evaporate and absorb heat due to the higher surface temperature of the fin 5, so that the ambient temperature around the heat exchanger 1 is reduced; because the bending part 5-1 is provided with the overflowing holes 5-4, when cooling water is sprayed on the bending part 5-1, fine water drops can penetrate through the overflowing holes 5-4 and move into gaps between the main body parts 5-2 under the driving of the fan 3, the temperature of the gaps between the main body parts 5-2 is increased due to the high temperature of the fins 5, the fine water drops can evaporate at high temperature to absorb ambient heat and reduce the ambient temperature of the heat exchanger 1, the overflowing holes 5-4 play a role in gas-liquid separation, more water drops are blocked at the bending part 5-1 of the fins 5, and the water saving effect is remarkable.

Referring to fig. 1-4, the delivery pipe 4 is a copper pipe, which is advantageous in that the copper pipe has a hard texture, is not easily corroded, is resistant to high temperature and high pressure, and can be used in various environments.

Referring to fig. 1 to 4, the air conditioning system of the evaporative condenser of the present embodiment includes a compressor 8, a throttling device 9, and an evaporator 10, which are connected in sequence through a pipeline, wherein the evaporative condenser further includes the above-mentioned evaporative condenser, and the evaporative condenser, the compressor 8, the throttling device 9, and the evaporator 10 form a closed circulation system.

Referring to fig. 1 to 4, the air conditioning system of the evaporative condenser of the present embodiment includes a compressor 8, the evaporative condenser, a throttling device 9, and an evaporator 10, which are connected in sequence by pipes, to form a closed circulation system.

Referring to fig. 1 to 4, the operating principle of the air conditioning system of the evaporative condenser is as follows:

referring to fig. 1-4, in operation, the compressor 8 continuously draws vapor generated in the evaporator 10 and compresses the vapor to the evaporative condenser, isobaric cooling and condensation to a liquid and releases the released heat to the environment. The utility model discloses in spray the water droplet to the portion 5-1 of bending of fin 5 through nozzle 7, flow to the fin 5 department of bending along guiding gutter 5-3 and blown to the main part 5-2 of fin 5 by the film forming, the liquid film water distribution mode makes 5 surface water distributions of fin more even, and the liquid film evaporates the absorption environment heat, increases the heat transfer difference in temperature between evaporative condenser and surrounding environment, and heat exchanger 1's heat transfer effect is showing and is improving. Meanwhile, the bending part 5-1 of the fin 5 also plays a role in retaining water, and water drops cannot flow into the environment from the gap of the fin 5. The liquid condensed by the evaporative condenser is cooled and depressurized by the throttling device 9 to become a gas-liquid mixture, the gas-liquid mixture enters the evaporator 10, the liquid in the mixture is evaporated in the evaporator 10, the heat is absorbed to become refrigerant gas, and the refrigerant gas returns to the compressor 8 again, and the cycle is repeated.

Example 2

The other structure of this embodiment is the same as embodiment 1, except that: the angle between the bending part 5-1 and the main body part 5-2 of the fin 5 ranges from 90 degrees to 180 degrees, and the specific angle can be adjusted according to actual conditions.

Example 3

The other structure of this embodiment is the same as embodiment 1, except that: the inclination angle and the number of the flow guide grooves 5-3 and the position and the number of the overflowing holes 5-4 can be determined according to actual conditions.

It should be finally noted that the above embodiments are only intended to illustrate the technical solutions of the present invention, and not to limit the scope of the present invention, and although the present invention has been described in detail with reference to the preferred embodiments, it should be understood by those skilled in the art that the technical solutions of the present invention can be modified or replaced with equivalents without departing from the spirit and scope of the technical solutions of the present invention.

Claims (10)

1. An evaporative condenser comprises a heat exchanger, a water spraying assembly arranged at the front end of the heat exchanger and used for spraying cooling water to the heat exchanger, and a fan arranged at the rear end of the heat exchanger and used for extracting hot air around the heat exchanger; the heat exchanger comprises a conveying pipe for conveying refrigerant and a plurality of fins uniformly arranged on the conveying pipe; it is characterized in that the preparation method is characterized in that,

each fin comprises a bending part positioned at the front end and used for blocking cooling water and a main body part positioned at the rear end, an angle formed by the main body part and the bending part is an obtuse angle, and the conveying pipe sequentially penetrates through the main body part;

a diversion trench for guiding blocked cooling water to the main body part is arranged on one side of the bent part close to the water spray assembly, and the diversion trench extends from the front end of the bent part to a bent part between the main body part and the bent part;

the bent portion is provided with an overflowing hole for discharging part of the cooling water to the space between the main body portions.

2. The evaporative condenser, as recited in claim 1, wherein said flow guide grooves are formed along the bent portions in an inclined downward direction.

3. The evaporative condenser, as recited in claim 2, wherein the plurality of the guiding grooves are arranged vertically and uniformly downward along the bent portion.

4. The evaporative condenser, as recited in claim 3, wherein said flow-passing holes are provided between said adjacent two of said guide grooves.

5. The evaporative condenser, as recited in claim 4, wherein the flow holes are plural and arranged in a matrix along the direction of the flow guide grooves.

6. The evaporative condenser, as recited in claim 5, wherein said flow apertures are in two rows of at least two.

7. The evaporative condenser, as recited in claim 5 or 6, wherein the bent portions occupy 10% to 20% of the entire fin.

8. The evaporative condenser, as recited in claim 5 or 6, wherein said water spray assembly comprises a fixing bracket and a spray nozzle provided on the fixing bracket, said fixing bracket being provided at the front end of the windward side of said fins.

9. The evaporative condenser, as recited in claim 8, wherein the plurality of nozzles are arranged in a matrix on the fixing bracket.

10. An air conditioning system of an evaporative condenser comprises a compressor, a throttling device and an evaporator which are sequentially connected through pipelines, and is characterized in that: the evaporative condenser according to any of claims 1 to 9, further comprising a closed circulation system formed by the evaporative condenser, the compressor, the throttling means and the evaporator.

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