CN220062097U - Condensed water removing device and air conditioner - Google Patents

Abstract

The disclosure relates to the technical field of air conditioner structures, and in particular relates to a condensed water removing device and an air conditioner. Wherein, comdenstion water drainage device includes the evaporimeter, the condenser, the fan, first water collector, the second water collector, a first detector, atomizing device and pumping device, first water collector sets up in the below of evaporimeter, the second water collector sets up in the below of condenser, pumping device's both ends respectively with first water collector and second water collector intercommunication, a detector sets up on first water collector for the liquid level in the monitoring first water collector, atomizing device installs in the second water collector, and atomizing device and condenser all are located the induced draft side or the side of blowing of fan. So set up, both realized utilizing the comdenstion water that the evaporimeter produced to cool down the condenser, avoid comdenstion water to pile up in the air conditioner again, monitor the liquid level in the first water collector through first detector simultaneously to avoid the comdenstion water that gathers in the first water collector too much and overflow, guarantee the normal work of air conditioner.

Description

Condensed water removing device and air conditioner

Technical Field

The disclosure relates to the technical field of air conditioner structures, and in particular relates to a condensed water removing device and an air conditioner.

Background

The evaporation and condensation of the integral air conditioner are completed in the same box body, an external air conditioner is not required to be arranged, and holes are not required to be perforated on a wall body, so that the integral air conditioner has the advantages of convenience in installation, space saving in installation and easiness in moving positions, and is increasingly applied to families.

However, because the integral air conditioner is not provided with the air conditioner external unit, condensed water generated on an evaporator can be accumulated in the integral air conditioner during operation, and the operation of the air conditioner is affected. In the related art, by arranging the water receiving disc below the evaporator, condensed water is gathered in the water receiving disc, and the water pipe is arranged on the water receiving disc, so that the condensed water in the water receiving disc flows to the vicinity of the condenser through the water pipe, and the condensed water is atomized and then is contacted with the condenser, thereby realizing cooling of the condenser and avoiding accumulation of the condensed water in an air conditioner. However, when the water pipe of the water receiving disc is blocked, condensed water is continuously gathered in the water receiving disc, so that the condensed water overflows the water receiving disc, and the normal operation of the air conditioner is affected.

Disclosure of Invention

In order to solve the above technical problems or at least partially solve the above technical problems, the present disclosure provides a condensed water drain device and an air conditioner.

The disclosure provides a condensate water removal device, comprising an evaporator, a condenser, a fan, a first water receiving disc, a second water receiving disc, a first detector, an atomization device and a water pumping device;

the first water pan is arranged below the evaporator, the second water pan is arranged below the condenser, two ends of the water pumping device are respectively communicated with the first water pan and the second water pan, the first detector is arranged on the first water pan and used for monitoring the liquid level in the first water pan, the atomizing device is arranged in the second water pan, and the atomizing device and the condenser are both positioned on the air suction side or the air blowing side of the fan.

Optionally, the atomization device and the condenser are both located at the blowing side of the fan, and the atomization device is arranged between the condenser and the fan;

or, atomizing device with the condenser all is located the induced draft side of fan, atomizing device set up in the condenser dorsad one side of fan.

Optionally, the atomizing device includes ultrasonic atomizer and casing, the top surface of casing is equipped with the atomizing export, ultrasonic atomizer set up in the casing, the side of casing is equipped with the water hole that supplies the condensate water to get into inside the casing.

Optionally, the first water-receiving disc is communicated with the second water-receiving disc through a communicating pipe, the communicating pipe is obliquely arranged, and one end of the communicating pipe connected with the first water-receiving disc is higher than one end of the communicating pipe connected with the second water-receiving disc.

Optionally, the pumping device includes drinking-water pipe and water pump, the one end of drinking-water pipe with first water collector intercommunication, the other end with second water collector intercommunication, the water pump with the drinking-water pipe intercommunication, in order to drive condensate water in the first water collector passes through the drinking-water pipe is carried to in the second water collector.

Optionally, a mounting bracket is arranged on the first water-receiving disc, one end of the mounting bracket is connected with the first water-receiving disc, the other end of the mounting bracket is positioned above the first water-receiving disc, and the water pump is mounted above the first water-receiving disc through the mounting bracket.

Optionally, in the vertical direction, the projections of the evaporator on the first water-receiving tray are all located in the first water-receiving tray, and the projections of the condenser on the second water-receiving tray are all located in the second water-receiving tray.

Optionally, the device further comprises a second detector, wherein the second detector is arranged on the second water receiving disc and is used for monitoring the liquid level in the second water receiving disc.

Optionally, the device further comprises a controller, wherein the first detector, the second detector, the pumping device and the atomizing device are all electrically connected with the controller, and the controller controls the pumping device to work according to the monitoring result of the first detector and controls the atomizing device to work according to the monitoring result of the second detector.

The present disclosure also provides an air conditioner including the condensed water drain device as claimed in any one of the above.

Compared with the prior art, the technical scheme provided by the disclosure has the following advantages:

the first water receiving disc is arranged below the evaporator and is used for containing condensed water generated during operation of the evaporator, the second water receiving disc is arranged below the condenser, and two ends of the water pumping device are respectively communicated with the first water receiving disc and the second water receiving disc so as to convey the condensed water in the first water receiving disc to the second water receiving disc through the water pumping device; the first detector is arranged on the first water receiving disc and is used for monitoring the liquid level in the first water receiving disc, so that the water pumping device is started in time when the liquid level in the first water receiving disc reaches the preset liquid level height, and the condensed water in the first water receiving disc is conveyed into the second water receiving disc through the water pumping device, so that excessive condensed water accumulated in the first water receiving disc is prevented from overflowing; the atomizing device is arranged in the second water pan, and the atomizing device and the condenser are both positioned at the air suction side or the air blowing side of the fan, so that the condensate water in the second water pan is atomized by the atomizing device, the water vapor formed after the condensate water is atomized by the fan is blown to the condenser, and the condenser is cooled, so that the condenser is cooled by the condensate water generated by the evaporator, the work of the air conditioner is influenced by accumulation of the condensate water in the air conditioner is avoided, meanwhile, the liquid level in the first water pan is monitored by the first detector, so that excessive and overflowing of the accumulated condensate water in the first water pan is avoided, and the normal work of the air conditioner is ensured.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this specification, illustrate embodiments consistent with the disclosure and together with the description, serve to explain the principles of the disclosure.

In order to more clearly illustrate the embodiments of the present disclosure or the solutions in the prior art, the drawings that are required for the description of the embodiments or the prior art will be briefly described below, and it will be obvious to those skilled in the art that other drawings can be obtained from these drawings without inventive effort.

FIG. 1 is a schematic view of a condensate removal apparatus according to an embodiment of the present disclosure;

fig. 2 is a schematic structural view of a first water-receiving tray according to an embodiment of the disclosure;

fig. 3 is a schematic structural view of a second water-receiving tray according to an embodiment of the present disclosure;

fig. 4 is a schematic structural view of an atomizing device according to an embodiment of the present disclosure.

Wherein, 1, an evaporator; 11. a first water pan; 12. a first detector; 2. a condenser; 21. a second water receiving tray; 22. a second detector; 3. an atomizing device; 31. a housing; 311. a water passing hole; 32. an ultrasonic atomizer; 4. a communicating pipe; 5. a water pumping device; 51. a water pump; 52. a water pumping pipe.

Detailed Description

In order that the above objects, features and advantages of the present disclosure may be more clearly understood, a further description of aspects of the present disclosure will be provided below. It should be noted that, without conflict, the embodiments of the present disclosure and features in the embodiments may be combined with each other.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present disclosure, but the present disclosure may be practiced otherwise than as described herein; it will be apparent that the embodiments in the specification are only some, but not all, embodiments of the disclosure.

Referring to fig. 1 to 4, the embodiment of the present disclosure provides a condensed water drain device including an evaporator 1, a condenser 2, a fan, a first water receiving tray 11, a second water receiving tray 21, a first detector 12, an atomizing device 3, and a water pumping device 5.

The first water receiving disc 11 is arranged below the evaporator 1 and is used for containing condensed water generated during operation of the evaporator 1, the second water receiving disc 21 is arranged below the condenser 2, and two ends of the water pumping device 5 are respectively communicated with the first water receiving disc 11 and the second water receiving disc 21 so as to convey the condensed water in the first water receiving disc 11 into the second water receiving disc 21 through the water pumping device 5; the first detector 12 is arranged on the first water receiving disc 11 and is used for monitoring the liquid level in the first water receiving disc 11 so as to timely start the water pumping device 5 when the liquid level in the first water receiving disc 11 reaches the preset liquid level height, and the condensed water in the first water receiving disc 11 is conveyed into the second water receiving disc 21 through the water pumping device 5 so as to avoid overflowing caused by excessive condensed water accumulated in the first water receiving disc 11; the atomizing device 3 is arranged in the second water receiving disc 21, and the atomizing device 3 and the condenser 2 are both positioned on the air suction side or the air blowing side of the fan, so that condensate water in the second water receiving disc 21 is atomized by the atomizing device 3, and water vapor formed after the condensate water is atomized by the fan is blown to the condenser 2 to cool the condenser 2, thereby not only cooling the condenser 2 by utilizing the condensate water generated by the evaporator 1, but also avoiding the accumulation of the condensate water in the air conditioner to influence the work of the air conditioner.

Specifically, the evaporator 1 and the condenser 2 are both indispensable structures in the air conditioner, the condenser 2 is a part of a refrigerating system of the air conditioner, belongs to one of heat exchangers, can convert gaseous refrigerant into liquid refrigerant, and can transfer heat in a refrigerant pipeline to air nearby the refrigerant pipeline; the evaporator 1 is a heat exchanger, high-pressure liquid refrigerant enters the evaporator 1 through a throttling component, the liquid refrigerant is turned into mist due to the throttling effect of the throttling component, the mist refrigerant is turned into gas under the low-pressure condition, heat is absorbed in the conversion process, the surface temperature of the evaporator 1 is reduced, and accordingly air flow is changed into cool air after passing through, and the purpose of refrigeration is achieved. Therefore, the condenser 2 emits heat during the operation of the air conditioner, so that the surface temperature of the condenser 2 increases, the evaporator 1 absorbs heat during the operation of the air conditioner, and the surface temperature of the evaporator 1 decreases, so that moisture in the air is condensed into droplets on the surface of the evaporator 1, and condensed water is formed on the surface of the evaporator 1.

In the specific implementation, the first water-receiving disc 11 and the second water-receiving disc 21 can be rectangular, or the first water-receiving disc 11 and the second water-receiving disc 21 can be circular; in the vertical direction, one side close to the bottom surface is below the evaporator 1 and the condenser 2, the evaporator 1 can be selectively placed in the first water receiving disc 11, the lower end of the evaporator 1 is connected with the disc bottom of the first water receiving disc 11, so that condensed water formed on the surface of the evaporator 1 flows into the first water receiving disc 11 under the action of gravity, a space can be formed between the first water receiving disc 11 and the evaporator 1 in the vertical direction, and the condensed water can drop from the surface of the evaporator 1 and enter the first water receiving disc 11; the condenser 2 can be selectively placed in the second water receiving tray 21, and the lower end of the condenser 2 is connected with the tray bottom of the second water receiving tray 21, so that the distance required by the atomizing device 3 to move the water body atomized by the liquid in the second water receiving tray 21 to the surface of the condenser 2 is shortened.

The first detector 12 may be a liquid level switch, specifically may be a laser detector, or may be a photoelectric gate detector, or may be a connection between the first detector 12 and a side wall of the first water-receiving tray 11, so that a detection end of the first detector 12 faces a tray bottom of the first water-receiving tray 11, so that the first detector 12 monitors a liquid level in the first water-receiving tray 11, or may be a rectangular mounting piece disposed on a side surface of the first water-receiving tray 11, one end of the mounting piece is connected with the side wall of the first water-receiving tray 11, and the other end extends upwards to be located above the first water-receiving tray 11, and connects the first detector 12 with one end of the mounting piece far away from the first water-receiving tray 11, so that the first detector 12 is located above the first water-receiving tray 11, and a detection end of the first detector 12 faces the tray bottom of the first water-receiving tray 11, so that the first detector 12 monitors the liquid level in the first water-receiving tray 11.

The water pumping device 5 can be selectively positioned above the first water receiving disc 11 and the second water receiving disc 21, the water pumping device 5 is provided with a water pump and a water pipe, the water pipe is connected with the water pump, one end of the water pipe extends into the first water receiving disc 11 from the upper part of the first water receiving disc 11, and the other end of the water pipe extends into the second water receiving disc 21 from the upper part of the second water receiving disc 21, so that the liquid in the first water receiving disc 11 can be transported into the second water receiving disc 21 through the water pump; of course, the water pumping device 5 may be located on the side surfaces of the first water receiving disc 11 and the second water receiving disc 21, and water holes are formed on the side walls of the first water receiving disc 11 and the side surfaces of the second water receiving disc 21, so that two ends of the water pumping device 5 are respectively connected with the water holes on the side walls of the first water receiving disc 11 and the second water receiving disc 21, and liquid in the first water receiving disc 11 can enter the second water receiving disc 21 through the water pumping device 5.

The above-mentioned atomizer 3 may be selected as an ultrasonic atomizer, the ultrasonic atomizer has a diaphragm, when the liquid moves onto the diaphragm of the ultrasonic atomizer, the diaphragm rapidly vibrates to make the liquid form fine droplets and fly in the air, so as to realize the function of the atomizer 3 for atomizing the liquid; of course, the atomizing device 3 may alternatively have a water-spraying plate capable of rotating rapidly, so that the water-spraying plate rotates rapidly to spray the liquid in the second water-receiving tray 21, and the liquid in the second water-receiving tray 21 is splashed into the air, thereby realizing atomization of the liquid in the second water-receiving tray 21.

The above-mentioned atomizing device 3 and the condenser 2 may be both located on the air suction side or the air blowing side of the fan, specifically, the air blowing side of the fan may face the side of the condenser 2, so that the condensed water in the second water collector 21 moves under the blowing of the fan after atomization, and finally the atomized water mist contacts with the surface of the condenser 2, so as to absorb the heat generated during the operation of the condenser 2 and cool the condenser 2, and then the water mist may be discharged from the air duct communicating with the outside.

When the evaporator is specifically used, the evaporator 1 works to generate condensed water on the surface of the evaporator, the condensed water flows into the first water receiving disc 11 under the action of gravity, the condensed water continuously gathers in the first water receiving disc 11, when the liquid level of liquid in the first water receiving disc 11 is monitored by the first detector 12 to be higher than a set liquid level, the water pumping device 5 is started to transport the liquid in the first water receiving disc 11 into the second water receiving disc 21, the liquid in the second water receiving disc 21 is continuously atomized under the action of the atomizing device 3, the atomized liquid moves under the action of the fan, finally the atomized liquid is discharged out of the air conditioner through the air outlet of the air conditioner under the blowing of the fan, and part of the atomized liquid contacts with the surface of the condenser 2 to be evaporated to realize the cooling of the condenser 2.

The condensate water draining device provided by the embodiment of the disclosure comprises an evaporator 1, a condenser 2, a fan, a first water receiving disc 11, a second water receiving disc 21, a first detector 12, an atomizing device 3 and a water pumping device 5; the first water receiving disc 11 is arranged below the evaporator 1, the second water receiving disc 21 is arranged below the condenser 2, two ends of the water pumping device 5 are respectively communicated with the first water receiving disc 11 and the second water receiving disc 21, the first detector 12 is arranged on the first water receiving disc 11 and used for monitoring the liquid level in the first water receiving disc 11, the atomizing device 3 is arranged in the second water receiving disc 21, the fan is arranged towards the side face of the condenser 2, condensed water formed by the operation of the evaporator 1 is gathered in the first water receiving disc 11, the water pumping device 5 and the first detector 12 are mutually matched to enable the condensed water gathered in the first water receiving disc 11 to be timely transported into the second water receiving disc 21, the condensed water in the second water receiving disc 21 is atomized through the atomizing device 3, and then the atomized water mist is blown to the condenser 2 through the fan to cool the condenser 2, so that the condensed water produced by the evaporator 1 is utilized to cool the condenser 2, the operation of the air conditioner is prevented from being accumulated in the air conditioner, the overflow of the condensed water formed by the evaporator 1 is prevented from damaging the first water receiving disc 11, and the stability of the air conditioner is improved when the air conditioner is used.

Referring to fig. 1 to 4, in some embodiments, the atomizing device 3 and the condenser 2 are both located on the blowing side of the blower, and the atomizing device 3 is disposed between the condenser 2 and the blower; or, atomizing device 3 and condenser 2 all are located the induced draft side of fan, and atomizing device 3 sets up in condenser 2 one side of being away from the fan.

Specifically, the fan is not shown in the figure, the fan can be arranged on the side surface of the condenser 2 in the horizontal direction, so that the blowing side of the fan faces the side surface of the condenser 2 in the horizontal direction, the atomizing device 3 is positioned between the condenser 2 and the blowing side of the fan in the horizontal direction, and therefore when the fan works, the fan drives air to blow to the condenser 2, and water mist generated by the atomizing device 3 moves along with the air and contacts with the surface of the condenser 2, so that the water mist absorbs heat on the surface of the condenser 2; when the side that induced drafts of fan is towards the side of condenser 2, the one side that the side that induced drafts of fan was kept away from to atomizing device 3 in the horizontal direction is the side that condenser 2 was dorsad to the fan, atomizing device 3 sets up in the side that condenser 2 was dorsad to the fan, be in on the horizontal direction promptly, condenser 2 is in atomizing device 3 between the side that induced drafts of fan, thereby make the during operation of fan, the air around condenser 2 gets into in the side that induced drafts, the water smoke that atomizing device 3 produced moves along with the air jointly, the water smoke contacts the surface of condenser 2 earlier and absorbs the heat on condenser 2 surface, then get into the side that induced drafts along with the air, the operation of cooling down to condenser 2 when having realized discharging the water smoke inside the air conditioner.

By arranging the atomizing device 3 and the condenser 2 to be positioned at the blowing side of the fan, the atomizing device 3 is arranged between the condenser 2 and the fan; or, atomizing device 3 and condenser 2 all are located the side that induced drafts of fan, and atomizing device 3 sets up in the condenser 2 one side of fan dorsad, and the water smoke that finally makes atomizing device 3 produce contacts with condenser 2 earlier under the effect of fan again, makes water smoke absorb the heat on condenser 2 surface, discharges the fan jointly along with the air again, makes the comdenstion water that evaporator 1 produced still can cool down condenser 2 in the inside in-process of discharge air conditioner, has promoted the utilization efficiency to the condensed water that evaporator 1 produced.

Referring to fig. 1 and 2, in some embodiments, the atomizing device 3 includes an ultrasonic atomizer 32 and a housing 31, the top surface of the housing 31 is provided with an atomizing outlet, the ultrasonic atomizer 32 is disposed in the housing 31, and the side surface of the housing 31 is provided with a water passing hole 311 for condensed water to enter the interior of the housing 31. The arrangement is such that the condensed water in the second water receiving tray 21 can be carried out in the housing 31 through the water passing holes 311, and then atomized by the ultrasonic atomizer 32, and the water vapor formed after the atomization is blown out of the housing 31 through the atomization outlet.

Specifically, the shell 31 may be selected to be a rectangular shell, or a shell 31 may be selected to be a cylindrical shell, the shell 31 is mounted on the tray bottom of the second water tray 21, one surface of the shell 31 away from the tray bottom of the second water tray 21 is a top surface of the shell 31, the window may be a rectangular through hole formed in the top surface of the shell 31, or a window may be a circular through hole formed in the top surface of the shell 31, the area of the window may be the area of the top surface of the grade shell 31, or the area of the window may be smaller than the area of the top surface of the shell 31; the ultrasonic atomizers 32 may be selectively mounted inside the housing 31 by bolts, or the ultrasonic atomizers 32 may be selectively bonded to the side surface of the housing 31, or one ultrasonic atomizer 32 may be selectively mounted inside the housing 31, or two ultrasonic atomizers 32 may be selectively mounted inside the housing 31, or the ultrasonic atomizers 32 may be selectively mounted on the bottom surface inside the housing 31, so that the vibrating diaphragm of the ultrasonic atomizers 32 faces the window, and the water mist atomized by the ultrasonic atomizers 32 moves upward to the side surface of the condenser 2; the side surface of the housing 31 near the second water receiving disc 21 may be provided with a circular through hole as the water passing hole 311, or a rectangular through hole of the water passing hole 311 may be selected, so long as the effect that the condensed water in the second water receiving disc 21 can enter the housing 31 through the water passing hole 311 is satisfied.

Through setting up atomizing device 3 and including ultrasonic atomizer 32 and casing 31, the top surface of casing 31 is equipped with the window, ultrasonic atomizer 32 sets up in casing 31, the side of casing 31 is equipped with the water hole 311 that supplies the condensate water to get into the inside of casing 31, finally make casing 31 can avoid the impurity in the condensate water in the second water collector 21 direct contact with ultrasonic atomizer 32, the liquid in the inside liquid of casing 31 is calmer more relative to the liquid in the second water collector 21, and the volume of the required liquid of handling of vibrating diaphragm of ultrasonic atomizer 32 has been restricted to casing 31, make the vibration of the vibrating diaphragm of ultrasonic atomizer 32 concentrate in the inside liquid of casing 31, thereby promote ultrasonic atomizer 32 and apply high frequency vibration to the liquid and make its atomizing effect.

Referring to fig. 1, 3 and 4, in some embodiments, the first water-receiving tray 11 and the second water-receiving tray 21 are communicated with each other through a communication pipe 4, the communication pipe 4 is disposed obliquely, and an end of the communication pipe 4 connected to the first water-receiving tray 11 is higher than an end of the communication pipe 4 connected to the second water-receiving tray 21.

Specifically, the first water-receiving tray 11 and the second water-receiving tray 21 may be selected to be arranged at intervals in the horizontal direction, and in the vertical direction, the tray bottom of the first water-receiving tray 11 is higher than the tray bottom of the second water-receiving tray 21, and through holes may be selected to be respectively arranged on the side walls of the first water-receiving tray 11 and the second water-receiving tray 21, so that one end of the communicating pipe 4 is connected with the through hole of the first water-receiving tray 11, and the other end is connected with the through hole of the second water-receiving tray 21, thereby the communicating pipe 4 is arranged obliquely, and condensed water collected in the first water-receiving tray 11 can enter the second water-receiving tray 21 through the communicating pipe 4 under the action of gravity; of course, the tray bottoms of the first water tray 11 and the second water tray 21 may be at the same height in the vertical direction, through holes are respectively formed in the side walls of the first water tray 11 and the second water tray 21, in the vertical direction, the through holes in the side walls of the first water tray 11 are located above the through holes in the side walls of the second water tray 21, one end of the communicating pipe 4 is connected with the through holes in the side walls of the first water tray 11, and the other end of the communicating pipe is connected with the through holes in the side walls of the second water tray 21, so that the communicating pipe 4 may be obliquely arranged, and after a certain volume of condensed water in the first water tray 11 is accumulated, the liquid level rises to the joint of the first water tray 11 and the communicating pipe 4, so that the condensed water in the first water tray 11 moves along the communicating pipe 4 under the action of gravity and enters the second water tray 21.

Through setting up between first water collector 11 and the second water collector 21 through communicating pipe 4 intercommunication, communicating pipe 4 slope setting, communicating pipe 4 is higher than communicating pipe 4 and the one end that second water collector 21 is connected with the one end of first water collector 11 connection, make the comdenstion water in the first water collector 11 flow into in the second water collector 21 through communicating pipe 4 under the action of gravity, make pumping device 5 and communicating pipe 4 form the double-circuit intercommunication of first water collector 11 and second water collector 21, the volume of condensed water gathering in the first water collector 11 can get into in the second water collector 21 through communicating pipe 4, when the liquid level of condensed water in the first water collector 11 is higher, pumping device 5 and communicating pipe 4 guide the water in the first water collector 11 jointly and get into in the second water collector 21, thereby guarantee that the comdenstion water that evaporator 1 produced can not spill over first water collector 11.

Referring to fig. 1, in some embodiments, the pumping device 5 includes a pumping pipe 52 and a pumping pump 51, one end of the pumping pipe 52 is communicated with the first water receiving tray 11, the other end is communicated with the second water receiving tray 21, and the pumping pump 51 is communicated with the pumping pipe 52 to drive condensed water in the first water receiving tray 11 to be delivered into the second water receiving tray 21 through the pumping pipe 52.

Specifically, the water pump 51 and the water suction pipe 52 can be both arranged above the first water receiving disc 11 and the second water receiving disc 21, a bracket can be arranged at the edge of the first water receiving disc 11 to mount the water pump 51 and the water suction pipe 52, one end of the water suction pipe 52 is positioned above the first water receiving disc 11 and inside the first water receiving disc 11, when condensed water is gathered in the first water receiving disc 11, the end part of the water suction pipe 52 can be positioned below the liquid level of the condensed water, the other end of the water suction pipe 52 can be selectively extended above the second water receiving disc 21, and the liquid in the water suction pipe 52 can fall into the second water receiving disc 21; of course, the water pump 51 and the water suction pipe 52 may be disposed on the side surfaces of the first water receiving disc 11 and the second water receiving disc 21, and through holes may be disposed on the side walls of the first water receiving disc 11 and the second water receiving disc 21 as water through holes, two ends of the water suction pipe 52 are respectively connected with the water through holes of the first water receiving disc 11 and the second water receiving disc 21, and the water pump 51 is communicated with the water suction pipe 52, so that condensed water in the first water receiving disc 11 flows into the second water receiving disc 21 through the water suction pipe 52 under the driving of the water pump 51.

Through setting up pumping device 5 and including drinking-water pipe 52 and water pump 51, the one end and the first water collector 11 intercommunication of drinking-water pipe 52, the other end and the second water collector 21 intercommunication, water pump 51 and drinking-water pipe 52 intercommunication, in order to drive the comdenstion water in the first water collector 11 and carry to the second water collector 21 through drinking-water pipe 52, make water pump 51 provide the driving force for the comdenstion water of gathering in the first water collector 11, and make the comdenstion water in the second water collector 21 that the comdenstion water got into through drinking-water pipe 52, water pump 51 and drinking-water pipe 52 are as pumping device 5's simple structure, can stable long-time operation, the cost of manufacture of comdenstion water drainage device has been reduced.

Referring to fig. 1, in some embodiments, a mounting bracket is provided on the first water receiving tray 11, one end of the mounting bracket is connected to the first water receiving tray 11, and the other end is located above the first water receiving tray 11, and the water pump 51 is mounted above the first water receiving tray 11 through the mounting bracket.

Specifically, the mounting bracket can be selected to include a vertical plate and a horizontal plate, one end of the vertical plate is connected with the side wall of the first water receiving disc 11, the other end extends upwards, the horizontal plate is arranged at one end of the vertical plate far away from the first water receiving disc 11, and extends towards the inside of the first water receiving disc 11 in the horizontal direction, so that the horizontal plate and the vertical plate form an L-shaped plate body, the water pump 51 can be selected to be connected with one end of the horizontal plate far away from the vertical plate, the water pumping pipe 52 is connected with the water pump 51, and accordingly, the water pumping pipe 52 and the water pump 51 are arranged above the first water receiving disc 11 and the second water receiving disc 21.

Through setting up being equipped with the installing support on the first water collector 11, the one end and the first water collector 11 of installing support are connected, and the other end is located the top of first water collector 11, and water pump 51 passes through the installing support to be installed in the top of first water collector 11, avoids dust foreign matter to pile up in drinking-water pipe 52 to make water pump 51 and drinking-water pipe 52 can utilize the space of first water collector 11 top, thereby reduce the space volume that condensate water drainage device needs to occupy, improve the space utilization in the air conditioner.

Referring to fig. 1 to 4, in some embodiments, in the vertical direction, the projections of the evaporator 1 on the first water pan 11 are all located inside the first water pan 11, and the projections of the condenser 2 on the second water pan 21 are all located inside the second water pan 21.

Specifically, the area of the first water receiving disc 11 is larger than the projected area of the evaporator 1, and the area of the second water receiving disc 21 is larger than the projected area of the condenser 2 in the vertical direction; the evaporator 1 is projected to be located inside the first water receiving disc 11 in the vertical direction, so that condensed water on the surface of the evaporator 1 can fall into the first water receiving disc 11 completely under the action of gravity, and the projection of the second water receiving disc 21 is located inside the second water receiving disc 21 completely, so that after the atomizing device 3 atomizes the condensed water in the second water receiving disc 21, the atomized condensed water can float upwards to be in contact with the condenser 2, and the atomized condensed water can absorb heat generated during the working of the condenser 2.

Through setting up in vertical orientation, the projection of evaporimeter 1 in first water collector 11 is whole to be located the inside of first water collector 11, the condenser 2 is whole to be located the inside of second water collector 21 at the projection of second water collector 21, make the comdenstion water that evaporimeter 1 during operation produced fall into first water collector 11 under the action of gravity in whole, the water smoke that atomizing device 3 produced upwards floats can with the surface contact of condenser 2, thereby make water smoke absorb the heat on condenser 2 surface, realize cooling down condenser 2 when getting rid of the comdenstion water that evaporimeter 1 produced.

Referring to fig. 1, in some embodiments, the condensate removal apparatus further includes a second detector 22, the second detector 22 being disposed on the second drip tray 21 for monitoring the liquid level in the second drip tray 21.

Specifically, the second detector 22 may be selected to be a liquid level switch, specifically may be a photo gate detector, or the second detector 22 may be selected to be a laser detector, where the second detector 22 may be selectively disposed on a side wall of the second water-receiving tray 21, so that a detection end of the second detector 22 faces a tray bottom of the second water-receiving tray 21, so that the second detector 22 may detect a liquid level of the liquid in the second water-receiving tray 21, or may alternatively be disposed on the second water-receiving tray 21, where one end of the support is connected to the second water-receiving tray 21, and the other end of the support extends upward to above the second water-receiving tray 21, and the second detector 22 is mounted at an end of the support away from the second water-receiving tray 21, so that the second detector 22 faces the tray bottom of the second water-receiving tray 21, and the second detector 22 may detect the liquid level in the second water-receiving tray 21; when the second detector 22 detects that there is liquid in the second water pan 21, the atomizing device 3 may be activated, and when it is detected that there is excessive accumulation of liquid in the second water pan 21, the evaporator 1 may be stopped to avoid overflowing the condensed water in the second water pan 21 due to excessive condensed water.

The second detector 22 is arranged on the second water receiving disc 21 and is used for monitoring the liquid level in the second water receiving disc 21, so that excessive condensation water in the second water receiving disc 21 is prevented from overflowing the second water receiving disc 21 due to excessive condensation water accumulation, and the stability of the condensation water removing device in the use process is improved.

Referring to fig. 1 to 4, in some embodiments, the condensed water drain device further includes a controller, and the first detector 12, the second detector 22, the pumping device 5, and the atomizing device 3 are all electrically connected to the controller, and the controller controls the operation of the pumping device 5 according to the monitoring result of the first detector 12 and controls the operation of the atomizing device 3 according to the monitoring result of the second detector 22.

Specifically, the first detector 12 and the second detector 22 can be selected to monitor the liquid level in the first water receiving disc 11 and the second water receiving disc 21 and then send signals to the controller, and the controller can control the operation of the water pumping device 5 and the atomizing device 3 through the signals sent by the first detector 12 and the second detector 22, and the controller can be a computer, and of course, the controller of the air conditioner can also be selected as the controller of the condensed water draining device.

The first detector 12 may select to have a working liquid level and a protection liquid level, when the first detector 12 detects that the liquid level in the first water receiving disc 11 is at the working liquid level, the first detector 12 sends a signal to the controller, the controller controls the pumping device 5 to start to convey the condensed water in the first water receiving disc 11 to the second water receiving disc 21, and the pumping device 5 continuously operates until the liquid level in the first water receiving disc 11 is reduced below the working liquid level; when the first detector 12 detects that the liquid level in the first water receiving disc 11 is higher than the protection liquid level, the condensed water in the first water receiving disc 11 gathers too much, at this time, the controller controls the evaporator 1 and the condenser 2 to stop operating, the atomizing device 3 and the fan continue to operate so that the condensed water is discharged from the air conditioner, when the first detector 12 detects that the liquid level in the first water receiving disc 11 is higher than the protection liquid level, the evaporator 1 and the condenser 2 can be selected to stop operating, and the atomizing device 3 and the fan continue to keep operating for 1 hour and then stop operating.

The second detector 22 may select an atomization liquid level and a safe liquid level, when a certain amount of condensed water is accumulated in the second water receiving disc 21 and reaches the atomization liquid level, the second detector 22 detects that the liquid level is higher than the atomization liquid level and sends a signal to the controller, the controller controls the atomization device 3 to start to atomize the condensed water in the second water receiving disc 21 until the second detector 22 detects that the liquid level in the second water receiving disc 21 is lower than the atomization liquid level, and the controller controls the atomization device 3 to stop running; when the condensed water in the second water receiving disc 21 gathers and reaches the safe liquid level, the second detector 22 detects that the liquid level is higher than the safe liquid level and sends a signal to the controller, the controller controls the evaporator 1 and the condenser 2 to stop running, the fan and the atomizing device 3 keep running until the second detector 22 detects that the liquid level in the second water receiving disc 21 is lower than the safe liquid level, and the controller controls the evaporator 1 and the condenser 2 to start running; it is of course also possible to select the second detector 22 to detect that the liquid level is higher than the safe liquid level and send a signal to the controller, which controls the evaporator 1 and the condenser 2 to stop operating, and the fan and the atomizing device 3 to stop operating after 1 hour.

When the condensate water draining device provided by the embodiment of the disclosure is specifically used, condensate water generated by the operation of the evaporator 1 falls into the first water receiving disc 11 and flows into the second water receiving disc 21 through the communicating pipe 4, the condensate water in the second water receiving disc 21 enters the inside of the shell 31 and contacts with the ultrasonic atomizer 32, when the second detector 22 detects that the liquid level in the second water receiving disc 21 is higher than the atomization liquid level and sends a signal to the controller, the controller controls the atomizer 3 to start to atomize the condensate water in the second water receiving disc 21, the fan blows air in the air conditioner to move, the atomized condensate water contacts with the condenser 2 first, then the air blowing port of the air conditioner discharges the inside of the air conditioner, the atomizer 3 continuously works until the liquid level in the second water receiving disc 21 is detected to be lower than the atomization liquid level by the second detector 22, when the condensate water is gathered more in the first water receiving disc 11, the first detector 12 detects that the liquid level in the first water receiving disc 11 is at the operation liquid level, the first detector 12 sends a signal to the controller, the controller controls the atomizer 5 to start to atomize the condensate water in the second water receiving disc 21 to keep the liquid level in the first water receiving disc 11 at the operation level, the first water receiving disc 11 is stopped, the first detector 1 is continuously operated until the liquid level in the first water receiving disc 11 is stopped at the operation level in the first water receiving disc 11 is stopped, and the operation system is stopped, and the operation of the fan 1 is continuously stopped when the operation of the first detector 1 is stopped, and the operation level is stopped.

When the second detector 22 detects that the liquid level in the second water receiving disc 21 is higher than the safe liquid level when the condensed water in the second water receiving disc 21 gathers, the second detector 22 detects that the liquid level is higher than the safe liquid level and sends a signal to the controller, the controller controls the evaporator 1 and the condenser 2 to stop running, and the fan and the atomizing device 3 keep running until the second detector 22 detects that the liquid level in the second water receiving disc 21 is lower than the safe liquid level, and the controller controls the evaporator 1 and the condenser 2 to start running; when the second detector 22 detects that the liquid level in the second water receiving disc 21 is higher than the safe liquid level for more than 1 hour, the controller controls the condenser 2 and the evaporator 1 to stop working, and the fan and the atomizing device 3 stop working after keeping running for 1 hour; when the first detector 12 detects that the liquid level in the first water receiving disc 11 is higher than the protection liquid level, the first detector 12 sends a signal to the controller, and at the moment, the controller controls the evaporator 1 and the condenser 2 to stop running, and the atomizing device 3 and the fan keep running for 1 hour and then stop running.

The embodiment of the disclosure also provides an air conditioner, which comprises the condensed water removing device according to any embodiment.

By using the condensate water removing device according to any one of the embodiments in the air conditioner, condensate water generated during operation can be discharged without arranging a drain pipe when the air conditioner is used, and the air conditioner is prevented from being failed due to excessive accumulation of the condensate water in the air conditioner, so that the stability of the air conditioner during use is improved.

It should be noted that in this document, relational terms such as "first" and "second" and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising one … …" does not exclude the presence of other like elements in a process, method, article, or apparatus that comprises the element.

The foregoing is merely a specific embodiment of the disclosure to enable one skilled in the art to understand or practice the disclosure. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the disclosure. Thus, the present disclosure is not intended to be limited to the embodiments shown and described herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The condensate water draining device is characterized by comprising an evaporator, a condenser, a fan, a first water receiving disc, a second water receiving disc, a first detector, an atomization device and a water pumping device;

the first water pan is arranged below the evaporator, the second water pan is arranged below the condenser, two ends of the water pumping device are respectively communicated with the first water pan and the second water pan, the first detector is arranged on the first water pan and used for monitoring the liquid level in the first water pan, the atomizing device is arranged in the second water pan, and the atomizing device and the condenser are both positioned on the air suction side or the air blowing side of the fan.

2. The condensate removal apparatus of claim 1, wherein the atomizing device and the condenser are both located on a blowing side of the blower, the atomizing device being disposed between the condenser and the blower;

or, atomizing device with the condenser all is located the induced draft side of fan, atomizing device set up in the condenser dorsad one side of fan.

3. The condensate removal apparatus of claim 1, wherein the atomizing device comprises an ultrasonic atomizer and a housing, wherein an atomization outlet is provided on a top surface of the housing, the ultrasonic atomizer is disposed in the housing, and a water passing hole for condensate water to enter the housing is provided on a side surface of the housing.

4. The condensate removal apparatus as claimed in claim 1, wherein the first water pan and the second water pan are connected by a communication pipe, the communication pipe being disposed obliquely, and an end of the communication pipe connected to the first water pan is higher than an end of the communication pipe connected to the second water pan.

5. The condensate removal apparatus of claim 1, wherein the water extraction apparatus comprises a water extraction pipe and a water pump, wherein one end of the water extraction pipe is in communication with the first water receiving tray, the other end is in communication with the second water receiving tray, and the water pump is in communication with the water extraction pipe to drive condensate in the first water receiving tray to be delivered into the second water receiving tray through the water extraction pipe.

6. The condensate removal apparatus as claimed in claim 5, wherein the first water pan is provided with a mounting bracket, one end of the mounting bracket is connected to the first water pan, the other end is located above the first water pan, and the water pump is mounted above the first water pan through the mounting bracket.

7. The condensate removal apparatus as claimed in claim 1, wherein in a vertical orientation, the evaporator projection is located entirely within the first water pan and the condenser projection is located entirely within the second water pan.

8. The condensate removal device of any one of claims 1 to 7, further comprising a second detector disposed on the second drip pan for monitoring a liquid level in the second drip pan.

9. The condensate removal device of claim 8, further comprising a controller, wherein the first detector, the second detector, the water extraction device, and the atomizing device are all electrically connected to the controller, wherein the controller controls operation of the water extraction device based on a monitoring result of the first detector, and controls operation of the atomizing device based on a monitoring result of the second detector.

10. An air conditioner comprising the condensed water removing apparatus according to any one of claims 1 to 9.