CN218096260U - Energy-saving air conditioner indoor unit and energy-saving air conditioner - Google Patents

Abstract

The utility model relates to an energy-saving air conditioner indoor unit and an energy-saving air conditioner, which comprises a shell component, wherein the shell component is provided with an installation cavity, the side wall of the shell component is provided with an air inlet and an air outlet, and the air inlet and the air outlet are communicated with the installation cavity; the direct evaporation device is arranged on the shell assembly, is positioned in the mounting cavity and is opposite to the air inlet; the indirect evaporation device is arranged on the shell assembly, the indirect evaporation device is positioned in the installation cavity, and the indirect evaporation device and the direct evaporation device are arranged oppositely; a fan assembly disposed on the housing assembly. Through combining direct evaporation plant and indirect evaporation plant, the air that gets into the interior machine exchanges heat the humidification on direct evaporation plant, cools down on indirect evaporation plant to reach the effect of cooling humidification.

Description

Energy-saving air conditioner indoor unit and energy-saving air conditioner

Technical Field

The utility model relates to an air conditioning refrigeration technology field especially relates to an energy-conserving air conditioning indoor set and energy-conserving air conditioner.

Background

Most of the existing air conditioners need to condense moisture in indoor air and discharge the moisture to the outside when refrigerating, so that the indoor air is dry in the process. In order to solve the problems, most users add a humidifier indoors, but the humidification range and efficiency of the humidifier are limited, and the problem of indoor humidification cannot be well solved.

SUMMERY OF THE UTILITY MODEL

Therefore, it is necessary to provide an air conditioner indoor unit and an energy-saving air conditioner that can both regulate temperature and increase humidity for the problem of indoor drying caused by the conventional air conditioner in the cooling process.

An energy-saving air conditioner indoor unit, comprising: the air conditioner comprises a shell assembly, a fan assembly and a fan, wherein the shell assembly is provided with an installation cavity, the side wall of the shell assembly is provided with an air inlet and an air outlet, and the air inlet and the air outlet are communicated with the installation cavity; the direct evaporation device is arranged on the shell assembly, is positioned in the mounting cavity and is opposite to the air inlet; the indirect evaporation device is arranged on the shell assembly, is positioned in the mounting cavity and is opposite to the direct evaporation device; the fan assembly is arranged on the shell assembly, and the fan assembly and the air outlet are arranged oppositely.

The energy-saving air conditioner indoor unit is provided with an air inlet, a direct evaporation device and an indirect evaporation device are arranged at the air inlet, a fan assembly drives indoor air to enter the energy-saving air conditioner indoor unit from the air inlet, and the air at the air inlet is subjected to heat exchange and humidification with liquid on the direct evaporation device in the process of passing through the direct evaporation device, so that the air temperature at the air inlet is reduced, and meanwhile, the liquid in the direct evaporation device is evaporated to well improve the air humidity, so that the cooling and humidifying effects are achieved; the air is at the in-process through indirect evaporation plant, because high-pressure liquid refrigerant evaporates the heat absorption at indirect evaporation plant, can play fine cooling effect to the air, thereby the cold air of humidification reaches the effect that reduces indoor temperature because the drive of fan subassembly is arranged from the air outlet. The direct evaporation device and the indirect evaporation device are combined, so that the defect of indoor drying of the traditional air conditioner in the operation process is overcome, the refrigeration effect of the air conditioner is improved, and the energy consumption of the air conditioner is reduced.

In one embodiment, the direct evaporation device is located between the air inlet and the indirect evaporation device. Through the combination of this direct evaporation device and indirect evaporation plant, the air of air inlet department is cooled down through indirect evaporation plant earlier, then the cooling forms behind the cold air and carries out the humidification through direct evaporation plant again, blows indoor air from the air outlet for the cold air that humidity is big.

In another embodiment, the indirect evaporation device is located between the air inlet and the direct evaporation device. The indirect evaporation device is arranged between the air inlet and the direct evaporation device, the air at the air inlet is subjected to heat exchange and humidification through the direct evaporation device, then the wet cold air is cooled through the indirect evaporation device, and the air blown into the room through the air outlet is the cold air with high humidity. Because this compound mode makes the room air pass through indirect evaporation plant behind the direct evaporation plant earlier, and the air temperature that just got into the air conditioning indoor set is higher, can carry out the heat transfer humidification more high-efficient, can reach the effect of better cooling humidification, improves refrigeration efficiency, reduces the air conditioner energy consumption.

In one embodiment, the direct evaporation device comprises a direct evaporation piece and a water circulation assembly, the direct evaporation piece is arranged opposite to a water outlet of the water circulation assembly, the water circulation assembly is arranged on the shell assembly and used for conveying water to the direct evaporation piece, the direct evaporation piece is arranged on the shell assembly, and the direct evaporation piece is located on one side where the air inlet is located. Through set up the hydrologic cycle subassembly on casing subassembly, the hydrologic cycle subassembly sets up with direct evaporation spare relatively, enables the hydrologic cycle subassembly with water carry direct evaporation spare on, get into the in-process by moist direct evaporation spare when the higher air of temperature, the water evaporation heat absorption on the direct evaporation spare makes air temperature reduce, becomes vapor simultaneously, and the air temperature after direct evaporation spare reduces and carries vapor simultaneously and becomes moist. The air humidifying and cooling effect of the air entering the shell assembly can be improved by arranging the plurality of direct evaporation pieces, and the energy consumption of the air conditioner can be well reduced.

Optionally, the number of direct evaporation elements is multiple.

In one embodiment, the direct evaporation element is a water curtain, the water curtain is arranged opposite to the air inlet, and the water circulation assembly is arranged opposite to the water curtain. The direct evaporation piece is the cascade, and the cascade sets up with the air intake relatively, improves the area of contact of air and cascade, reaches better humidification cooling effect. The structure of the water curtain is a corrugated honeycomb structure, and the specific surface area of the structure is large, so that the contact area of air and water on the direct evaporation part can be well increased, and the heat exchange and humidification effects are improved.

Optionally, the water curtain is of a corrugated honeycomb structure.

In one embodiment, the water circulation assembly comprises a conveying assembly and a flow dividing assembly, the conveying assembly is arranged on the shell assembly and connected with the flow dividing assembly, the conveying assembly is used for conveying liquid to the flow dividing assembly, a liquid outlet of the flow dividing assembly is opposite to the direct evaporation piece, and the liquid directly flows through the flow dividing assembly and then is conveyed to the direct evaporation piece. Through set up conveying assembly and reposition of redundant personnel subassembly on the hydrologic cycle subassembly, the liquid outlet and the relative setting of direct evaporation spare of reposition of redundant personnel subassembly make hydroenergy on the reposition of redundant personnel subassembly directly carry on the direct evaporation spare, provide the medium for the heat transfer humidification of direct evaporation spare.

Optionally, the flow diversion assembly is disposed at a top end of the direct evaporative element.

In one embodiment, the delivery assembly includes a circulation tube and a water pump, the water pump being in communication with the circulation tube, the circulation tube being in communication with the flow splitting assembly. By arranging the water pump and the circulating pipe, the water pump conveys water from the bottom of the shell assembly to each direct evaporation part at different positions through the circulating pipe.

In one of them embodiment, the reposition of redundant personnel subassembly includes into water subassembly and flow distribution plate, it sets up to intake the subassembly on the casing subassembly, intake the subassembly with conveying component communicates, flow distribution plate quantity has a plurality ofly, and the adjacent setting the flow distribution plate forms the liquid channel. Through setting up into water subassembly and flow distribution plate, the water of circulating pipe is carried to into water subassembly back, flows to the direct evaporation spare through the liquid passageway that crosses that forms between the adjacent flow distribution plate on, and the flow distribution plate enables water and shunts uniformly on the direct evaporation spare, improves the heat transfer humidification effect of evaporation spare and air.

Optionally, the water pump further comprises a water tank, the water tank is arranged on the shell assembly, the water tank is located at the bottom of the installation cavity, and at least part of the water pump is located in the water tank.

Optionally, a portion of the housing assembly forms a reservoir for holding a liquid, and at least a portion of the water pump is located in the reservoir.

In one embodiment, the water level adjusting device is arranged on the shell assembly and used for detecting the liquid level of the shell assembly. Through setting up the liquid level that water level regulating device is used for detecting the casing subassembly in, too high or the condition of crossing excessively appears in the liquid level in the casing subassembly, can influence the humidification heat transfer effect of direct evaporation spare, water level regulating device can detect the liquid level change.

In one embodiment, the fan assembly comprises fan blades and a motor assembly, the motor assembly is arranged on the shell assembly, the fan blades are arranged on the motor assembly, and the fan blades and the air outlet are arranged oppositely. Through setting up the fan subassembly, thereby motor element drive fan subassembly swing forms the negative pressure in the air conditioning indoor set installation cavity, and the air outside the air conditioner consequently gets into in the air conditioner from the air intake, carries out the wet cold air after heat transfer humidification through direct evaporation plant and indirect evaporation plant, discharges outside the air conditioner through the air outlet afterwards, reaches indoor refrigeration effect.

In one embodiment, the fan further comprises a swing blade, the swing blade is arranged on the shell assembly and is opposite to the fan blades, and the swing blade is movably connected with the shell assembly. Through setting up the pendulum leaf at the air outlet, the one end and the casing subassembly swing joint of pendulum leaf, the other end can be according to pendulum leaf and casing subassembly swing joint's the condition luffing motion for the wet cold air can be regulated and control at the wind direction that blows off of air outlet, satisfies the demand that the user changed the air conditioner wind direction, provides the convenience of using.

A second aspect of the present invention provides an energy saving air conditioner.

An energy-saving air conditioner comprises the energy-saving air conditioner indoor unit; an outdoor unit for transporting a refrigerant to the energy-saving indoor air conditioner; and the communicating pipe is used for communicating the outdoor unit with the indoor unit of the energy-saving air conditioner. The energy-saving air conditioner indoor unit and the outdoor unit are combined into finished air conditioner equipment, the outdoor unit provides a refrigerant for an indirect evaporation device of the indoor unit as a heat exchange medium, and the communicating pipe is used for transmitting the refrigerant, indoor unit condensed liquid or other substances. The air conditioner combined with the indoor unit of the air conditioner has the effects of humidifying and cooling, and can reduce the energy consumption of the air conditioner.

Drawings

FIG. 1 is an energy efficient air conditioning indoor unit main view;

FIG. 2 is a cross-sectional view of an indoor unit of the energy saving air conditioner;

FIG. 3 is a schematic top view of an energy-saving indoor unit of an air conditioner;

FIG. 4 is a longitudinal sectional view of the indoor unit of the energy saving air conditioner;

FIG. 5 is a schematic view of the connection of the circulating water pipe and the flow dividing assembly;

FIG. 6 is a schematic view of a shunt assembly connection;

figure 7 is an exploded view of a fan assembly.

Wherein, the corresponding relation between the reference signs and the component names is as follows:

1, a shell component, 11 air inlets and 12 air outlets;

2 direct evaporation device, 21 direct evaporation part, 22 water circulation component, 221 conveying component, 2211 circulation pipe, 2212 water pump, 222 flow dividing component, 2221 water inlet component and 2222 flow dividing plate;

3 an indirect evaporation device;

4 fan assembly, 41 fan blade, 42 motor assembly;

5, a water level adjusting device;

6, swinging the leaves.

Detailed Description

In order that the above objects, features and advantages of the present invention can be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings. It should be noted that the embodiments and features of the embodiments of the present application may be combined with each other without conflict.

In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention, however, the present invention may be practiced otherwise than as specifically described herein and, therefore, the scope of the present invention is not limited by the specific embodiments disclosed below.

An energy-saving air conditioner indoor unit according to some embodiments of the present invention will be described with reference to the accompanying drawings.

As shown in fig. 1 to 7, the embodiment discloses an energy-saving air-conditioning indoor unit, which includes a casing assembly 1, the casing assembly 1 is provided with an installation cavity, the side wall of the casing assembly is provided with an air inlet 11 and an air outlet 12, and the air inlet 11 and the air outlet 12 are communicated with the installation cavity; the direct evaporation device 2 is arranged on the shell assembly 1, the direct evaporation device 2 is positioned in the installation cavity, and the direct evaporation device 2 is arranged opposite to the air inlet 11; the indirect evaporation device 3 is arranged on the shell component 1, the indirect evaporation device 3 is positioned in the installation cavity, and the indirect evaporation device 3 is arranged opposite to the direct evaporation device 2; fan subassembly 4, fan subassembly 4 set up at casing subassembly 1, and fan subassembly 4 sets up with air outlet 12 is relative.

The application discloses an energy-saving air-conditioning indoor unit is provided with an air inlet 11, a direct evaporation device 2 and an indirect evaporation device 3 are arranged at the air inlet 11, a fan assembly 4 drives indoor air to enter the energy-saving air-conditioning indoor unit from the air inlet 11, and the air at the air inlet 11 is subjected to heat exchange and humidification with liquid on the direct evaporation device 2 in the process of passing through the direct evaporation device 2, so that the air temperature at the air inlet 11 is reduced, and meanwhile, the liquid in the direct evaporation device 2 can be evaporated to well improve the air humidity, so that the effects of cooling and humidification are achieved; in the process that the air passes through the indirect evaporation device 3, as the high-pressure liquid refrigerant is evaporated and absorbs heat in the indirect evaporation device 3, the air can be cooled well, and the humidified cold air is discharged from the air outlet 12 to the indoor space due to the driving of the fan assembly 4, so that the effect of reducing the indoor temperature is achieved. By combining the direct evaporation device 2 and the indirect evaporation device 3, the defect of indoor drying of the traditional air conditioner in the operation process is overcome, the refrigeration effect of the air conditioner is improved, and the energy consumption of the air conditioner is reduced.

In one embodiment, the direct evaporation device 2 is located between the air inlet 11 and the indirect evaporation device 3. Through the combination of direct evaporation plant 2 and indirect evaporation plant 3, the air of air intake 11 department reduces the temperature through indirect evaporation plant 3 earlier, then passes through direct evaporation plant 2 after the cooling forms the cold air and humidifies, blows indoor air from air outlet 11 and is the cold air that humidity is big.

In one embodiment, the indirect evaporation device 3 is located between the air inlet 11 and the direct evaporation device 2. The air at the air inlet 11 is firstly subjected to heat exchange and humidification by the direct evaporation device 2, then the wet cold air is cooled by the indirect evaporation device 3, and the air blown into the room through the air outlet is the cold air with high humidity. Because this compound mode makes the room air pass through indirect evaporation plant 3 after direct evaporation plant 2 earlier, and the air temperature that just got into the air conditioning indoor set is higher, can carry out the heat transfer humidification more efficiently, can reach the effect of better cooling humidification, improves refrigeration efficiency, reduces the air conditioner energy consumption.

As shown in fig. 2 to 6, in addition to the features of the above embodiment, the present embodiment further defines: the direct evaporation device 2 comprises a direct evaporation piece 21 and a water circulation assembly 22, the direct evaporation piece 21 is arranged opposite to a water outlet of the water circulation assembly 22, the water circulation assembly 22 is arranged on the shell assembly 1, the water circulation assembly 22 is used for conveying water to the direct evaporation piece 21, the direct evaporation piece 21 is arranged on the shell assembly 1, and the direct evaporation piece 21 is located on one side where the air inlet 11 is located. Through set up water circulation subassembly 22 on casing subassembly 1, water circulation subassembly 22 sets up with direct evaporation spare 21 is relative, enables water circulation subassembly 21 and carries water on direct evaporation spare 21, and when the higher air of temperature gets into by the in-process of moist direct evaporation spare 21, the water evaporation heat absorption on the direct evaporation spare 21 makes the air temperature reduce, becomes vapor simultaneously, and the air temperature after direct evaporation spare 21 reduces and carries vapor simultaneously and becomes moist. The effects of humidifying and cooling the air entering the housing assembly 1 can be improved by arranging the plurality of direct evaporation pieces 21, and the energy consumption of the air conditioner can be well reduced.

Alternatively, the number of the direct evaporating parts 21 is plural.

In addition to the features of the above embodiments, the present embodiment further defines: the direct evaporation element 21 is a water curtain, which is arranged opposite to the air inlet 11, and the water circulation component 22 is arranged opposite to the water curtain. The direct evaporation piece 21 is a water curtain, and the water curtain is arranged opposite to the air inlet 11, so that the contact area of air and the water curtain is increased, and a better humidifying and cooling effect is achieved. The structure of the water curtain is a corrugated honeycomb structure, and the specific surface area of the structure is large, so that the contact area of air and water on the direct evaporation part 21 can be well increased, and the heat exchange and humidification effects are improved.

Optionally, the water curtain is of a corrugated honeycomb structure.

In addition to the features of the above embodiments, the present embodiment further defines: the water circulation assembly 22 comprises a conveying assembly 221 and a flow dividing assembly 222, the conveying assembly 221 is arranged on the shell assembly 1, the conveying assembly 221 is connected with the flow dividing assembly 222, the conveying assembly 221 is used for conveying liquid to the flow dividing assembly 222, a liquid outlet of the flow dividing assembly 222 is arranged opposite to the direct evaporation part 21, and the liquid is directly conveyed to the direct evaporation part 21 after flowing through the flow dividing assembly 222. By arranging the conveying assembly 221 and the flow dividing assembly 222 on the water circulation assembly 22 and arranging the liquid outlet of the flow dividing assembly 222 opposite to the direct evaporation part 21, water on the flow dividing assembly 222 can be directly conveyed to the direct evaporation part 21, and a medium is provided for heat exchange and humidification of the direct evaporation part 21.

Optionally, flow divider assembly 221 is disposed at the top end of direct evaporation element 21.

As shown in fig. 4, in addition to the features of the above embodiment, the present embodiment further defines: the delivery assembly 221 comprises a circulation tube 2211 and a water pump 2212, the water pump 2212 is in communication with the circulation tube 2211, and the circulation tube 2211 is in communication with the flow splitting assembly 222; by providing a water pump 2212 and a circulation tube 2211, the water pump 2212 delivers water from the bottom of the housing assembly 1 through the circulation tube 2211 to each direct evaporation element 21 at a different location.

As shown in fig. 6, in addition to the features of the above embodiment, the present embodiment further defines: the flow dividing assembly 222 comprises a water inlet assembly 2221 and flow dividing plates 2222, the water inlet assembly 2221 is arranged on the shell assembly 1, the water inlet assembly 2221 is communicated with the conveying assembly 221, the number of the flow dividing plates 2222 is multiple, and the flow dividing plates 2222 arranged adjacently form a liquid passing channel. Through setting up into water subassembly 221 and flow distribution plate 2222, the water of circulating pipe 2211 is carried to into water subassembly 2221 after, flows to direct evaporation spare 21 through the liquid passageway that crosses that forms between adjacent flow distribution plate 2222 on, flow distribution plate 2222 enables water evenly to shunt on direct evaporation spare 21, improves the heat transfer humidification effect of evaporation spare 21 and air.

Optionally, a water tank is further included, the water tank is disposed on the housing assembly 1, the water tank is located at the bottom of the installation cavity, and at least a portion of the water pump 2212 is located in the water tank.

Optionally, a portion of the housing assembly 1 forms a reservoir for holding liquid, and at least a portion of the water pump 2212 is located in the reservoir.

As shown in fig. 4, further, a water level adjusting device 5 is further included, the water level adjusting device 5 is disposed on the housing assembly 1, and the water level adjusting device 5 is used for detecting the liquid level of the housing assembly 1. Through setting up the liquid level that water level regulating device 5 is used for detecting the casing subassembly in, too high or the condition of crossing low appears in the liquid level in casing subassembly 1, can influence the humidification heat transfer effect of direct evaporation spare 21, water level regulating device 5 can detect the liquid level change.

As shown in fig. 7, in addition to the features of the above embodiment, the present embodiment further defines: the fan assembly 4 comprises a fan blade 41 and a motor assembly 42, the motor assembly 42 is arranged on the housing assembly 1, the fan blade 41 is arranged on the motor assembly 42, and the fan blade 41 and the air outlet 12 are arranged oppositely. Through setting up fan subassembly 4, thereby motor element 42 drive fan subassembly 4 swing forms the negative pressure in the air conditioning indoor set installation cavity, and the air outside the air conditioner consequently gets into in the air conditioner from air intake 11, carries out the heat transfer humidification through direct evaporation plant 2 and indirect evaporation plant 3 and becomes wet cold air, discharges outside the air conditioner through air outlet 12 afterwards, reaches indoor refrigeration effect.

As shown in fig. 1, further, the fan further comprises a swing blade 6, the swing blade 6 is disposed on the housing assembly 1 and is opposite to the fan blade 41, and the swing blade is movably connected to the housing assembly 1. Through setting up pendulum leaf 6 at air outlet 11, the one end and the casing subassembly 1 swing joint of pendulum leaf 6, the other end can be according to pendulum leaf 6 and casing subassembly 1 swing joint's the condition luffing motion for the wet cold air can be regulated and control at air outlet 12's the wind direction that blows off, satisfies the demand that the user changed the air conditioner wind direction, provides the convenience of using.

Example 2

A second embodiment of the present application discloses an energy-saving air conditioner, including the above-mentioned energy-saving air conditioner indoor unit; the outdoor unit is used for conveying the refrigerant to the energy-saving air conditioner indoor unit; and the communicating pipe is used for communicating the outdoor unit with the indoor unit of the energy-saving air conditioner. The energy-saving air conditioner indoor unit and the outdoor unit are combined into finished air conditioner equipment, the outdoor unit provides a refrigerant for the indirect evaporation device 3 of the indoor unit as a heat exchange medium, and the communicating pipe is used for transmitting the refrigerant, indoor unit condensed liquid or other substances. The air conditioner combined with the indoor unit of the air conditioner has the effects of humidifying and cooling, and can reduce the energy consumption of the air conditioner.

All possible combinations of the technical features of the above embodiments may not be described for the sake of brevity, but should be considered as within the scope of the present disclosure as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. An energy-saving air conditioner indoor unit is characterized by comprising:

the air conditioner comprises a shell assembly (1), wherein the shell assembly (1) is provided with an installation cavity, the side wall of the shell assembly is provided with an air inlet (11) and an air outlet (12), and the air inlet (11) and the air outlet (12) are communicated with the installation cavity;

the direct evaporation device (2) is arranged on the shell assembly (1), the direct evaporation device is positioned in the mounting cavity, and the direct evaporation device is arranged opposite to the air inlet;

the indirect evaporation device (3) is arranged on the shell assembly (1), the indirect evaporation device (3) is positioned in the installation cavity, and the indirect evaporation device (3) is arranged opposite to the direct evaporation device (2);

fan subassembly (4), fan subassembly (4) set up casing subassembly (1), fan subassembly (4) with air outlet (12) set up relatively.

2. An energy saving indoor unit of an air conditioner according to claim 1,

the direct evaporation device (2) is positioned between the air inlet (11) and the indirect evaporation device (3); or

The indirect evaporation device (3) is positioned between the air inlet (11) and the direct evaporation device (2).

3. The indoor unit of an energy-saving air conditioner as claimed in claim 1, wherein the direct evaporation device (2) comprises a direct evaporation part (21) and a water circulation component (22), the direct evaporation part (21) is arranged opposite to a water outlet of the water circulation component (22), the water circulation component (22) is arranged on the casing component (1), the water circulation component (22) is used for conveying water to the direct evaporation part (21), the direct evaporation part (21) is arranged on the casing component (1), and the direct evaporation part (21) is located on one side where the air inlet (11) is located.

4. An energy-saving air-conditioning indoor unit as claimed in claim 3, wherein the direct evaporation member (21) is a water curtain, the water curtain is disposed opposite to the air inlet (11), and the water circulation assembly (22) is disposed opposite to the water curtain.

5. The indoor unit of claim 3, wherein the water circulation assembly (22) comprises a conveying assembly (221) and a flow dividing assembly (222), the conveying assembly (221) is disposed on the casing assembly (1), the conveying assembly (221) is connected to the flow dividing assembly (222), the conveying assembly (221) is used for conveying the liquid to the flow dividing assembly (222), a liquid outlet of the flow dividing assembly (222) is disposed opposite to the direct evaporation member (21), and the liquid is conveyed to the direct evaporation member (21) directly after flowing through the flow dividing assembly (222).

6. The indoor unit of an energy-saving air conditioner as claimed in claim 5, wherein the delivery assembly (221) comprises a circulation pipe (2211) and a water pump (2212), the water pump (2212) is communicated with the circulation pipe (2211), and the circulation pipe (2211) is communicated with the flow dividing assembly (222); and/or

The flow distribution assembly (222) comprises a water inlet assembly (2221) and flow distribution plates (2222), the water inlet assembly (2221) is arranged on the shell assembly (1), the water inlet assembly (2221) is communicated with the conveying assembly (221), the flow distribution plates (2222) are multiple in number, and the flow distribution plates (2222) which are adjacently arranged form a liquid passing channel.

7. An energy-saving air-conditioning indoor unit as claimed in claim 1, further comprising a water level adjusting device (5), wherein the water level adjusting device (5) is arranged on the shell assembly (1), and the water level adjusting device (5) is used for detecting the liquid level of the shell assembly (1).

8. The indoor unit of the energy-saving air conditioner as claimed in claim 1, wherein the fan assembly (4) comprises a fan blade (41) and a motor assembly (42), the motor assembly (42) is disposed on the casing assembly (1), the fan blade (41) is disposed on the motor assembly (42), and the fan blade (41) is disposed opposite to the air outlet (12).

9. The indoor unit of an energy-saving air conditioner as claimed in claim 8, further comprising a swing blade (6), wherein the swing blade (6) is disposed on the casing assembly (1) and opposite to the fan blade (41), and the swing blade is movably connected to the casing assembly (1).

10. An energy-saving air conditioner, characterized by comprising:

the energy saving air conditioning indoor unit of one of claims 1 to 9;

an outdoor unit for transporting a refrigerant to the energy-saving indoor air conditioner;

and the communicating pipe is used for communicating the outdoor unit with the indoor unit of the energy-saving air conditioner.

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