CN205481611U - Cooling device and possess this cooling device's air conditioner - Google Patents

Abstract

The utility model provides a cooling device includes casing, fan, compressor, air -cooled condenser, collection portion, water -cooled condenser, evaporation media structure and spray the structure, the casing has the air intake and the air outlet of intercommunication, forms the hot air duct that looses between air intake and air outlet, and the fan is located air outlet or air intake. The forced air cooling condenser is used for holding water with compressor and water -cooled condenser intercommunication, collection portion for unenclosed structure, and water -cooled condenser floods in the collection water that the portion contains when using, evaporation media structure is located the hot air duct that looses with the air -cooled condenser. Spray top that the structure located evaporation media structure in order to spray and then to cool down to water the evaporation media. Come autogenous pressure to contract the refrigerant of machine and can carry out the primary cooling through the air when flowing through air -cooled condenser, can be through water evaporation carrying on secondary cooling when the refrigerant flows in water -cooled condenser. The utility model provides an air conditioner.

Description

Chiller and have the air-conditioning of this chiller

Technical field

This utility model relates to a kind of heat-exchange device, applies at the chiller of air-conditioning technical field particularly to a kind of and have the air-conditioning of this chiller.

Background technology

In life, industry chiller, air cooling way is generally used to cool down, as conventional home-use outdoor machine of air-conditioner is made up of compressor, condenser, blower fan etc., condenser is blown by blower fan, make the coolant in condenser carry out heat exchange by condenser and air, thus reduce the temperature of coolant.But, the condensation efficiency of condenser raises with outdoor temperature and reduces, and power consumption is bigger.

Utility model content

In view of the foregoing, it is necessary to a kind of energy-conservation chiller is provided.

There is a need to provide a kind of air-conditioning having this chiller.

A kind of chiller, including housing and blower fan, described housing has formation heat dissipation wind channel between air inlet and the air outlet of connection, described air inlet and described air outlet, and described blower fan is located at described air outlet or air inlet.Described chiller also includes compressor, air-cooled condenser, collection portion, water-cooled condenser, evaporative medium structure and spray structure, described air-cooled condenser is connected between described compressor and described water-cooled condenser, described collection portion is positioned at the bottom of described housing for accommodating water, described collection portion is unenclosed construction, described water-cooled condenser connects with described air-cooled condenser, and described water-cooled condenser is submerged in described collection portion is filled with water in time using；In described evaporative medium structure is arranged at described housing, described spray structure is arranged in described housing and is positioned at the top of described evaporative medium structure, for providing described water to be evaporated heat radiation to drench described evaporative medium structure to described evaporative medium structure, described evaporative medium structure and described air-cooled condenser are positioned at described heat dissipation wind channel, air is entered through described evaporative medium structure and described air-cooled condenser by described air inlet, discharged by described air outlet again, once can be cooled down by air when coolant from described compressor flows through described air-cooled condenser, described coolant can carry out cooling twice by water when flowing into described water-cooled condenser.

Further, described air-cooled condenser and described evaporative medium structure are juxtaposed on described heat dissipation wind channel, and described air-cooled condenser is arranged adjacent to air outlet, and described evaporative medium structure is arranged adjacent to described air inlet.

Further, described housing includes diapire, roof and the sidewall being oppositely arranged, and described sidewall is between described diapire and described roof, and described air outlet is located on the sidewall of described housing.

Further, described sidewall includes the first side wall and the second sidewall being oppositely arranged, it is provided with described air outlet in described the first side wall and described second sidewall one of which, described air inlet is set in another one so that described heat dissipation wind channel in described housing in unidirectional and extend vertically through described the first side wall and described second sidewall.

Further, described chiller also includes controller, described controller includes controlling module and sensing module, described control module is electrically connected with described sensing module, described compressor and described blower fan, and described sensing module is located at described collection portion in order to sense the liquid level of the described water in described collection portion.

Further, when in described sensing module senses described collection portion, described water reaches at or above the liquid level preset value of a certain water, described control module controls described blower fan and is in the first mode of operation, in this first operative mode, described chiller is in power save mode, described blower fan has the first power, and described air-cooled condenser has the first air quantity；When in described sensing module senses described collection portion, the liquid level of described water is less than a certain preset value, described control module controls described blower fan and is in the second mode of operation, under described second mode of operation, described chiller is in high wind state, described chiller has the second power, and described second power is higher than described first power.

Further, the quantity of described blower fan is several, and when described chiller is in described first mode of operation, described control module can control at least one of which blower fan and quit work；When described chiller is in described second mode of operation, it is in running order that described control module can control at least two of which blower fan.

Further, when described sensing module senses the liquid level preset value that described water is less than a certain water, described control module increases the wind speed of described blower fan；When the water in described sensing module senses described collection portion is higher than the liquid level preset value of a certain water, described control module reduces the wind speed of described blower fan.

Further, described chiller also includes suction pump, described suction pump and described collection portion and described spray structure are by being connected pipeline communication, it is circulated utilization to be pumped by the water in described collection portion to described spray structure, the power bracket of described suction pump is 5～60W, and the range of lift of described suction pump is at below 10m.

A kind of air-conditioning, it includes chiller and the vaporising device connected with chiller, described vaporising device tool vaporizer, described chiller includes housing and blower fan, described housing has air inlet and the air outlet of connection, forming heat dissipation wind channel between described air inlet and described air outlet, described blower fan is located at described air outlet or air inlet.Described chiller also includes compressor, air-cooled condenser, collection portion, water-cooled condenser, evaporative medium structure and spray structure, described compressor connects with described vaporizer, described air-cooled condenser is connected between described compressor and described water-cooled condenser, described collection portion is positioned at the bottom of described housing for accommodating water, described collection portion is unenclosed construction, described water-cooled condenser connects with described air-cooled condenser, and described water-cooled condenser is submerged in described collection portion is filled with water in time using；Described evaporative medium structure and described air-cooled condenser are positioned at described heat dissipation wind channel, in described evaporative medium structure is arranged at described housing, described spray structure is arranged in described housing and is positioned at the top of described evaporative medium structure, for providing described water to be evaporated heat radiation to drench described evaporative medium structure to described evaporative medium structure, described evaporative medium structure and described air-cooled condenser are positioned at described heat dissipation wind channel, air is entered through described evaporative medium structure and described air-cooled condenser by described air inlet, discharged by described air outlet again, once can be cooled down by air when coolant from described compressor flows through described air-cooled condenser, described coolant can carry out cooling twice by water when flowing into described water-cooled condenser.

Compared to prior art, chiller that this utility model provides and have the air-conditioning of this chiller, the coolant flowing through air-cooled condenser is once cooled down by air, the coolant flowing through water-cooled condenser carries out cooling twice by water, collection portion is unenclosed construction, spray structure spraying and sprinkling evaporation media structure is evaporated heat radiation and then lowers the temperature water water, and water falls into collection portion.Owing to water produces phase transformation in evaporation process, absorbing heat more, so improve condensing heat-exchange efficiency, improving the reliability of system simultaneously.Chiller has air-cooled and evaporative cooling two ways, and the energy consumption of the condenser system that the most single air-cooled or single water evaporates cold mode is lower.Further, since two heat-exchange systems share an air channel, reduce the loss of wind energy, and the miniaturization of compact conformation, beneficially chiller.

Accompanying drawing explanation

The structural principle block diagram of the air-conditioning that Fig. 1 provides for embodiment of the present utility model.

Fig. 2 is the assembling figure of the chiller of the air-conditioning of Fig. 1.

Fig. 3 is the chiller decomposed figure shown in Fig. 2.

Fig. 4 is another visual angle figure of the decomposed figure of the chiller shown in Fig. 2.

Fig. 5 is the functional module group figure of controller.

Main element symbol description

Following detailed description of the invention will further illustrate this utility model in conjunction with above-mentioned accompanying drawing.

Detailed description of the invention

Below in conjunction with the accompanying drawing in this utility model embodiment, the technical scheme in this utility model embodiment is clearly and completely described, it is clear that described embodiment is only a part of embodiment of this utility model rather than whole embodiments.Based on the embodiment in this utility model, the every other embodiment that those of ordinary skill in the art are obtained under not making creative work premise, broadly fall into the scope of this utility model protection.In the case of not conflicting, the feature in following embodiment and embodiment can be mutually combined.

It should be noted that in this utility model, when an assembly is considered as " to be connected " with another assembly, it can be to be joined directly together with another assembly, it is also possible to is to be indirectly connected to another assembly by assembly placed in the middle.

Unless otherwise defined, all of technology used herein and scientific terminology are identical with belonging to the implication that those skilled in the art of the present utility model are generally understood that.It is intended merely to describe the purpose of specific embodiment at term used in the description of the present utility model herein, it is not intended that in limiting this utility model.

Refer to the structural principle schematic diagram of the air-conditioning 300 that Fig. 1, Fig. 1 provide for embodiment of the present utility model.Air-conditioning 300 includes chiller 100 and the vaporising device 200 connected with chiller 100.Vaporising device 200 has the vaporizer 201 connected with chiller 100.Chiller 100 carries out heat exchange for making the coolant (not shown) of high temperature realize cooling down with air or other water.The vaporising device 200 coolant after making the cooling of cooled device 100 absorbs amount of heat by evaporation in vaporizer 201, it is achieved its local environment is lowered the temperature.Coolant absorbs heat in vaporizer 201 after evaporating and returns chiller 100, thus completes the refrigerant circulation in process of refrigerastion.Certainly, air-conditioning 300 also includes other common structure, such as throttle valve component etc., for saving space, does not repeats at this.

In the present embodiment, chiller 100 is used as the air-conditioner outdoor unit being disposed in the outdoor.Chiller 100 includes the second heat-exchange system 102 that housing 10 (as shown in Figure 2), compressor 20, the first heat-exchange system 101 of being contained in described housing 10 connect, and blower fan 40 with the first heat-exchange system 101.The coolant flowed out from vaporising device 200 after the first heat-exchange system 101 carries out heat exchange, passes through the second heat-exchange system 102 and carries out second time heat exchange, and flow back into vaporising device 200, be so circulated refrigeration after compressor 20 compresses.First heat-exchange system 101 has the heat exchange pattern different from the second heat-exchange system 102, and wherein, the rate of heat exchange of the second heat-exchange system 102 is higher than the rate of heat exchange of the first heat-exchange system 101.Specifically, first heat-exchange system 101 and the second heat-exchange system 102 have different heat exchange modes, if the heat exchange mode of the first heat-exchange system 101 is air cooling way, the heat exchange mode of the second heat-exchange system 102 is water evaporation mode, and the second heat-exchange system 102 includes the first heat exchange subsystem 30 and the second heat exchange subsystem 50 connected with the first heat exchange subsystem 30.The heat exchange between coolant and the water realizing air-conditioning 300 of the first heat exchange subsystem 30.

Incorporated by reference to refering to Fig. 3 and Fig. 4, housing 10 includes diapire 11, the roof 12 being oppositely arranged, and the sidewall 13 between diapire 11 and roof 12.Described sidewall 13 includes the first side wall 133 and the second sidewall 137 being oppositely arranged.It is provided with air outlet 138 on the first side wall 133 and the second sidewall 137 one of which, air inlet 139 is set in another one, blower fan 40 is set on air outlet 138, thus formation one is unidirectional in housing 10 and extends vertically through the first side wall 133 and the heat dissipation wind channel of the second sidewall 137.Blower fan 40, for being sucked from air inlet 139 by air, is discharged to air outlet 138.In other embodiments, air inlet 139 may be disposed on roof 12；Blower fan 40 can be located at air inlet 139, and so that air is sent into housing 10 from air inlet 139, air is discharged through evaporative medium structure 53 and air-cooled condenser 1011 to air outlet 138.

Further, also including a dividing plate 14 in housing 10, housing 10 is divided into cooling chamber 130 and containing cavity 170 by dividing plate 14.Air outlet 138, air inlet 139 are arranged on the sidewall of cooling chamber 130, and then make heat dissipation wind channel be arranged at cooling chamber 130.In present embodiment, air inlet 139 is oppositely arranged with air outlet 138；The quantity of air outlet 138 is two, arranges from top to bottom.In present embodiment, the number of blower fan 40 is two, is installed in respectively on two air outlets 138.

Compressor 20 is placed in containing cavity 170, and it connects with the vaporizer 201 of vaporising device 200.

First heat-exchange system 101 includes the air-cooled condenser 1011 connected with compressor 20, so that the coolant after compressor 20 compresses and air carry out heat exchange for the first time.Air-cooled condenser 1011 is arranged in heat dissipation wind channel.In present embodiment, air-cooled condenser 1011 is finned air-cooled condenser.

Second heat-exchange system 102 communicates with the first heat-exchange system 101, and shared heat dissipation wind channel.

First heat exchange subsystem 30 includes collection portion 35 and water-cooled condenser 37.Collection portion 35 is located at the lower section of housing 10 and is positioned at the bottom of cooling chamber 130, is used for collecting water.Collection portion 35 is a unenclosed construction, and it uses upper part or overall unlimited mode.Water-cooled condenser 37 is contained in collection portion 35, and is submerged in water in time using.Water-cooled condenser 37 connects with compressor 20, so that carrying out second time heat exchange from the high temperature refrigerant of compressor 20 and the water in collection portion 35.

In present embodiment, water-cooled condenser 37 is the multiple structure of the heat exchanger tube bending winding being made up of a metal.Water-cooled condenser 37 includes the first condensing unit 371 and the second condensing unit 373 being interconnected.First condensing unit 371 and the second condensing unit 373 the most helically tubulose.In other embodiments, water-cooled condenser 37 can also be constituted for the heat exchanger tube gone for a stroll and coupled radiating fin, and water-cooled condenser 37 can be other shape outside serpentine pipe, such as S-shaped pipe.In other are implemented, the quantity of condensing unit can be one, or two or more.

Second heat exchange subsystem 50 includes bracing frame 51, evaporative medium structure 53, suction pump 55 and spray structure 57.Second heat exchange subsystem 50 is for realizing the heat radiation to water, thus reduces the temperature of water.

Bracing frame 51 is contained in cooling chamber 130, and be set up in collection portion 35, evaporative medium structure 53 is made to be integrally located at the top in collection portion 35 and bottom it higher than the water surface in collection portion 35 for supporting evaporative medium structure 53, evaporative medium structure 53 is made to be fully contacted with air, to reach the purpose of high-efficiency evaporating.

Evaporative medium structure 53 is arranged at cooling chamber 130 and neighbouring air inlet 139 is arranged, and it is supported by bracing frame 51.Evaporative medium structure 53 is in described heat dissipation wind channel and between the first location division 516 and air inlet 139.Evaporative medium structure 53 is a stephanoporate structure.In present embodiment, evaporative medium structure 53 is wet curtain, the feature of its tool honeycomb loose structure；The quantity of evaporative medium structure 53 is one.It is appreciated that evaporative medium structure 53 can be made up of materials such as paper pulp or other fiber, pottery, rustless steel, polrvinyl chloride (Polyvinyl chloride, PVC).Such as, the evaporative medium structure that ceramic material is made, it has a lot of micro hole, to increase the contact area of water and air；The evaporative medium structure that stainless steel material is made, utilizes stainless steel silk to have porous or the structure of similar honeycomb around being set as.In present embodiment, evaporative medium structure 53 is more than the first side wall 133 and 1/5th of the second sidewall 137 spacing towards the distance between the side and blower fan 40 of blower fan 40.

In the present embodiment, air-cooled condenser 1011 and evaporative medium structure 53 are juxtaposed between air inlet 139 and air outlet 138, and air-cooled condenser 1011 is between evaporative medium structure 53 and air outlet 138.Air-cooled condenser 1011 can also be positioned on bracing frame 51.

Suction pump 55 is arranged in collection portion 35, and suction pump 55 connects by being connected pipeline 59 with collection portion 35 and spray structure 57, to pump the water in collection portion 35 to spray structure 57.Owing to collection portion 35 uses open type to design, collection portion 35 is identical with atmospheric pressure in cooling chamber 130, water is flowed down by the gravity of self, draw water to the top in collection portion 35 through suction pump 55 again, form the circular flow of water, therefore, the requirement of lift can be reduced by suction pump 55, power can also reduce, thus reduces cost, improves efficiency.The present embodiment uses the power bracket of suction pump 55 to be 5～60W；Range of lift is 1.5m～6m in below 10m, the preferred scope of suction pump 55 lift.

Spray structure 57 is arranged in cooling chamber 130, and is positioned at the top of evaporative medium structure 53, for providing water to evaporative medium structure 53 so that evaporative medium structure 53 is soaked, and then makes water and air have bigger contact area.

As it is shown in figure 5, chiller 100 also includes controller 103, controller 103 is for controlling the mode of operation of chiller.Controller 103 includes controlling module 1031 and sensing module 1035.Control module 1031 in order to control the first heat-exchange system 101 and work of the second heat-exchange system 102.Control module 1031 to be electrically connected with sensing module 1035, compressor 20, suction pump 55 and two blower fans 40.Sensing module 1035 is located in collection portion 35, in order to sense the liquid level of water in collection portion 35.When in sensing module 1035 senses collection portion 35, water reaches at or above the liquid level preset value of a certain water, control module 1031 controls blower fan 40 and is in the first mode of operation, in this first operative mode, chiller 100 is in power save mode, blower fan 40 has the first power, and air-cooled condenser 1011 has the first air quantity.Specifically, control module 1031 controls one of them blower fan 40 and works, and another blower fan 40 stops.When in sensing module 1035 senses collection portion 35, the liquid level of water is less than a certain preset value, control module 1031 controls blower fan 40 and is in the second mode of operation, in the second mode, chiller 100 is in high wind state, chiller 100 has the second power, and this second power is higher than the first power.Specifically, control module 1031 to control two blower fans 40 and work simultaneously.Now, air-cooled condenser 1011 has the second air quantity, and this second air quantity is higher than the first air quantity.The quantity of described blower fan 40 can be two or more, and when described chiller 100 is in described first mode, described control module 1031 can control at least one of which blower fan 40 and quit work；When described chiller 100 is in described second pattern, it is in running order that described control module 1031 can control at least two of which blower fan 40.In other embodiments, especially in the case of only blower fan 40, the blower fan of adjustable speed can be used.By control module 1031, the wind speed of single blower fan 40 is adjusted reaching chiller 100 and there is multiple mode of operation, as when sensing module 1035 and sensing the liquid level of water less than preset value, the wind speed of blower fan 40 is increased, to suck more air quantity by controlling module 1031.

During assembling, bracing frame 51 is put into the cooling chamber 130 of housing 10, water-cooled condenser 37 is put into collection portion 35, evaporative medium structure 53 and air-cooled condenser 1011 are juxtaposed on bracing frame 51, in spray structure 57 is installed in cooling chamber 130 and communicate with suction pump 55, compressor 20 and suction pump 55 are arranged in containing cavity 170, water-cooled condenser 37 are connected with compressor 20 and air-cooled condenser 1011, air-cooled condenser 1011 is connected with the vaporizer 201 of vaporising device 200.

During use, introducing the water in collection portion 35, water logging there is not water-cooled condenser 37.In process of refrigerastion, it is delivered to air-cooled condenser 1011 after compressor 20 compression refrigerant, carry out heat exchange for the first time with air when coolant flows through air-cooled condenser 1011, coolant flows into the water in water-cooled condenser 37 and collection portion 35 and carries out second time heat exchange, suction pump 55 works and then extracts the water in collection portion 35 to spray structure 57, spray structure 57 makes water be sprayed to evaporative medium structure 53 from top to bottom, under the effect of blower fan 40, air is sucked into air outlet 138 from air inlet 139, the air of shower water and flowing carries out heat exchange by evaporative medium structure 53, realize the cooling to water.Coolant after supercooling is delivered to the vaporizer 201 of vaporising device 200, and coolant absorbs heat in vaporizer 201 after evaporating and returns compressor 20, thus completes the refrigerant circulation in process of refrigerastion.During this refrigerant circulation, coolant absorbs amount of heat by evaporation in vaporizer 201, thus reaches the effect of cooling.

Chiller 100 that this utility model provides and have the air-conditioning 300 of this chiller 100, first heat-exchange system 101 is once cooled down through the coolant of air-cooled condenser 1011 by cross-ventilation, second heat-exchange system 102 includes the first heat exchange subsystem 30 and the second heat exchange subsystem 50, first heat exchange subsystem 30 carries out cooling twice by the coolant of the water cooled condenser of water convection current 37, collection portion 35 is unenclosed construction, it utilizes water self gravitation to flow into the first heat exchange subsystem from the second heat exchange subsystem 50, water is evaporated dispelling the heat and then lowering the temperature water by the second heat-exchange system by spray structure spraying and sprinkling evaporation media structure, improve condensing heat-exchange efficiency, improve the reliability of system simultaneously.Further, since two heat-exchange systems share an air channel, reduce the loss of wind energy, and compact conformation, the beneficially miniaturization of chiller 100.What is more, chiller 100 tool controls the controller 103 of mode of operation, and it is according to the liquid automatic control mode of operation of water sensing, it is ensured that while total system reliability, facilitate use.

Being appreciated that chiller 100 not only limits the use of in air-conditioning 300, it can also be applied to other life, industry cooling field, such as ice machine, CNC equipment cooling etc..

It is appreciated that, it is convenient to omit bracing frame 51, directly support member is set on the medial wall of cooling chamber 130, as having the raised line of one fixed width, to support evaporative medium structure 53 and air-cooled condenser 1011.

Being appreciated that air-cooled condenser 1011 can be arranged by neighbouring air inlet 139, evaporative medium structure 53 is between air-cooled condenser 1011 and blower fan 40.

It is appreciated that, it is convenient to omit housing 10 can not set cooling chamber 130 and the containing cavity 170 of isolation.Housing 10 is not limited to hexahedron, housing 10 substantially semicylinder shape, the number of air inlet 139 can be two or more, and the number of evaporative medium structure 53 corresponds to two or more, each air inlet 139 be correspondingly arranged an evaporative medium structure 53.

It is appreciated that air-cooled condenser 1011 and is provided with the sidewall of air outlet 138 or to be provided with the sidewall of air inlet 139 almost parallel.

Embodiment of above is only in order to illustrate the technical solution of the utility model and unrestricted, although this utility model being described in detail with reference to embodiment of above, it will be understood by those within the art that, the technical solution of the utility model can be modified or equivalent the most should not depart from the spirit and scope of technical solutions of the utility model.

Claims (10)

1. a chiller, including housing and blower fan, described housing has air inlet and the air outlet of connection, heat dissipation wind channel is formed between described air inlet and described air outlet, described blower fan is located at described air outlet or air inlet, it is characterized in that: described chiller also includes compressor, air-cooled condenser, collection portion, water-cooled condenser, evaporative medium structure and spray structure, described air-cooled condenser is connected between described compressor and described water-cooled condenser, described collection portion is positioned at the bottom of described housing for accommodating water, described collection portion is unenclosed construction, described water-cooled condenser connects with described air-cooled condenser, described water-cooled condenser is submerged in described collection portion is filled with water in time using；In described evaporative medium structure is arranged at described housing, described spray structure is arranged in described housing and is positioned at the top of described evaporative medium structure, for providing described water to be evaporated heat radiation to drench described evaporative medium structure to described evaporative medium structure, described evaporative medium structure and described air-cooled condenser are positioned at described heat dissipation wind channel, air is entered by described air inlet, through described evaporative medium structure and described air-cooled condenser, discharged by described air outlet again, once can be cooled down by air when coolant from described compressor flows through described air-cooled condenser, described coolant can carry out cooling twice by water when flowing into described water-cooled condenser.

2. chiller as claimed in claim 1, it is characterised in that: described air-cooled condenser and described evaporative medium structure are juxtaposed on described heat dissipation wind channel, and described air-cooled condenser is arranged adjacent to air outlet, and described evaporative medium structure is arranged adjacent to described air inlet.

3. chiller as claimed in claim 2, it is characterised in that: described housing includes diapire, roof and the sidewall being oppositely arranged, and described sidewall is between described diapire and described roof, and described air outlet is located on the sidewall of described housing.

4. chiller as claimed in claim 3, it is characterized in that: described sidewall includes the first side wall and the second sidewall being oppositely arranged, it is provided with described air outlet in described the first side wall and described second sidewall one of which, described air inlet is set in another one so that described heat dissipation wind channel in described housing in unidirectional and extend vertically through described the first side wall and described second sidewall.

5. chiller as claimed in claim 1, it is characterized in that: described chiller also includes controller, described controller includes controlling module and sensing module, described control module is electrically connected with described sensing module, described compressor and described blower fan, and described sensing module is located at described collection portion in order to sense the liquid level of the described water in described collection portion.

6. chiller as claimed in claim 5, it is characterized in that: when in described sensing module senses described collection portion, described water reaches at or above the liquid level preset value of a certain water, described control module controls described blower fan and is in the first mode of operation, in this first operative mode, described chiller is in power save mode, described blower fan has the first power, and described air-cooled condenser has the first air quantity；When in described sensing module senses described collection portion, the liquid level of described water is less than a certain preset value, described control module controls described blower fan and is in the second mode of operation, under described second mode of operation, described chiller is in high wind state, described chiller has the second power, and described second power is higher than described first power.

7. chiller as claimed in claim 6, it is characterised in that: the quantity of described blower fan is several, and when described chiller is in described first mode of operation, described control module can control at least one of which blower fan and quit work；When described chiller is in described second mode of operation, it is in running order that described control module can control at least two of which blower fan.

8. chiller as claimed in claim 5, it is characterised in that: when described sensing module senses the liquid level preset value that described water is less than a certain water, described control module increases the wind speed of described blower fan；When the water in described sensing module senses described collection portion is higher than the liquid level preset value of a certain water, described control module reduces the wind speed of described blower fan.

9. chiller as claimed in claim 1, it is characterized in that: described chiller also includes suction pump, described suction pump and described collection portion and described spray structure are by being connected pipeline communication, it is circulated utilization to be pumped by the water in described collection portion to described spray structure, the power bracket of described suction pump is 5～60W, and the range of lift of described suction pump is at below 10m.

null10. an air-conditioning，It includes chiller and the vaporising device connected with chiller，Described vaporising device tool vaporizer，Described chiller includes housing and blower fan，Described housing has air inlet and the air outlet of connection，Heat dissipation wind channel is formed between described air inlet and described air outlet，Described blower fan is located at described air outlet or air inlet，It is characterized in that: described chiller also includes compressor、Air-cooled condenser、Collection portion、Water-cooled condenser、Evaporative medium structure and spray structure，Described compressor connects with described vaporizer，Described air-cooled condenser is connected between described compressor and described water-cooled condenser，Described collection portion is positioned at the bottom of described housing for accommodating water，Described collection portion is unenclosed construction，Described water-cooled condenser connects with described air-cooled condenser，Described water-cooled condenser is submerged in described collection portion is filled with water in time using；Described evaporative medium structure and described air-cooled condenser are positioned at described heat dissipation wind channel, in described evaporative medium structure is arranged at described housing, described spray structure is arranged in described housing and is positioned at the top of described evaporative medium structure, for providing described water to be evaporated heat radiation to drench described evaporative medium structure to described evaporative medium structure, described evaporative medium structure and described air-cooled condenser are positioned at described heat dissipation wind channel, air is entered through described evaporative medium structure and described air-cooled condenser by described air inlet, discharged by described air outlet again, once can be cooled down by air when coolant from described compressor flows through described air-cooled condenser, described coolant can carry out cooling twice by water when flowing into described water-cooled condenser.