CN210980101U - Indoor air intelligent management machine - Google Patents

Abstract

The utility model discloses an indoor air intelligent management machine. It includes shell and air outlet, still includes inner chamber, air conditioner subassembly and new trend subassembly, wherein: the inner cavity is arranged in the shell and is divided into a front cavity part and a rear cavity part through a first partition plate, and the air outlet is positioned on the side wall of the front cavity part; the air conditioning assembly is located within the front chamber portion; the fresh air component is positioned in the rear cavity part; the fresh air component comprises a fresh air system, an air return system and a heat exchanger; the heat exchanger is communicated with the fresh air system and the return air system; the air outlet is communicated with the fresh air system and the air conditioning assembly. The utility model has the advantages of have the refrigeration concurrently, heat and the new trend function.

Description

Indoor air intelligent management machine

Technical Field

The utility model relates to an air conditioning technology field under the airtight environment, it is indoor air intelligent management machine that says so more specifically.

Background

A conventional air conditioner generally includes an indoor unit and an outdoor unit, the indoor unit and the outdoor unit are connected by a pipe, a compressor and a condenser (heat exchanger) are disposed in the outdoor unit, an indoor heat exchanger (condenser) is disposed in the indoor unit, a refrigerant is compressed into a high-temperature and high-pressure gas in the compressor, and then the gas is condensed in one of the indoor heat exchanger and the outdoor condenser to release heat. In the other, evaporation endotherm; the heating or cooling function is realized for the indoor environment. Air-conditioning products on the market generally do not have the new trend function.

A multi-connected air conditioner features that an outdoor unit is connected to two or more indoor units via pipeline, and in summer, the indoor units are used for cooling and in winter, the indoor units are used for heating. This type of multi-connected air conditioner or central air conditioner also cannot introduce outdoor fresh air into the room, and does not have a fresh air mode.

With the rapid development of Chinese economy and the continuous improvement of the living standard of people, people seek high-quality living environment more and more. Because of the air conditioner, people can refrigerate and cool in summer and can enjoy warm in winter as spring. However, it is impossible to have better air quality and living environment because the air conditioner needs to close the door and window for cooling or heating, so that fresh air is not available in the room. If fresh air is not circulated indoors, oxygen is lacked, people feel uncomfortable, feel oppression in chest and short breath, and other diseases can be induced, so-called 'air conditioning syndrome'. If the environment is a place with dense crowds, such as a school classroom, a kindergarten and a conference room, the air pollution caused by oxygen deficiency is more serious. Scientific studies have shown that 90% of human diseases are caused by hypoxia.

If the machine is provided, the hot weather can be used for refrigerating, the cold weather can be used for heating, no matter the air is refrigerated or heated, a certain proportion of fresh air can enter the room continuously, and when the air conditioner is stopped in spring and autumn, the machine can be used as a fresh air purifier to be needed urgently, so that the machine is a household appliance which people dreak sleep to demand, and the household appliance product in the true sense does not exist in the market at present.

In view of this, it is necessary to provide an air conditioner with cooling, heating and fresh air modes to fill up the market gap, aiming at the problem that the existing air conditioner or central air conditioner cannot have the cooling, heating and fresh air functions at the same time.

Disclosure of Invention

The utility model aims at providing an indoor air intelligent management machine has the refrigeration concurrently, heats and the new trend function, all-weather, have the mode of heating, refrigeration mode, new trend mode, heat and new trend mode and refrigeration and new trend mode, improve the availability factor of air conditioner, save space, save the cost.

In order to realize the purpose, the technical scheme of the utility model is that: indoor air intelligent management machine, including shell and air outlet, its characterized in that: still include inner chamber, air conditioner subassembly and new trend subassembly, wherein:

the inner cavity is arranged in the shell and is divided into a front cavity part and a rear cavity part through a first partition plate, and the air outlet is positioned on the side wall of the front cavity part;

the air conditioning assembly is located within the front chamber portion;

the fresh air component is positioned in the rear cavity part;

the fresh air component comprises a fresh air system, an air return system and a heat exchanger; the heat exchanger is communicated with the fresh air system and the return air system;

the air outlet is communicated with the fresh air system and the air conditioning assembly.

In the technical scheme, the heat exchanger is transversely arranged in the rear cavity part;

the heat exchanger is of a hexagonal structure; the heat exchanger comprises a fresh air inlet side face, a return air inlet side face, a fresh air outlet side face and a return air outlet side face.

In the technical scheme, the display screen is arranged on the front side wall of the shell and is positioned below the air outlet;

the air deflector is movably connected to the air outlet;

an induction system is arranged on the rear chamber part and is positioned above the heat exchanger;

the induction system is located between the fresh air system and the return air system.

In the technical scheme, the air conditioner component comprises a condenser/radiator, an auxiliary heater, a water receiving tank, an electric control board, a cold and hot fan, a cold and hot filter screen and an air supply duct; the auxiliary heater is positioned on the condenser/radiator; the condenser/radiator is fixed on the upper part of the front cavity part; the water receiving tank is positioned at the lower end of the condenser/radiator; the electric control plate is positioned below the water receiving tank; the cold and hot filter screen is positioned at the front ends of the water receiving tank and the electric control plate; the cold and hot fan is fixed between the electric control plate and the first partition plate.

In the technical scheme, the fresh air system comprises a fresh air inlet, a fresh air inlet pipeline, a fresh air outlet, a fresh air inlet cavity, a fresh air outlet cavity, a fresh air channel, a filter cavity and a fresh air motor cavity;

the fresh air inlet is positioned on the rear side wall of the shell and positioned at the upper part of the rear cavity part;

the fresh air outlet is positioned in the fresh air inlet cavity and at the lower end of the heat exchanger;

the fresh air inlet cavity is positioned at the lower end of the heat exchanger and is communicated with the fresh air inlet side face;

the fresh air inlet is communicated with the fresh air outlet through the fresh air inlet pipeline;

the fresh air inlet pipeline is positioned on the side of the heat exchanger; the sealing cover position and the heat exchanger are arranged in parallel; the sealing cover is positioned above the fresh air inlet pipeline.

In the technical scheme, the filter cavity and the fresh air motor cavity are positioned at the upper end of the rear cavity part;

the filter cavity and the fresh air motor cavity are arranged at intervals, and are positioned below the fresh air motor cavity and above the fresh air outlet cavity;

the filter cavity comprises a primary filter screen cavity and a high-efficiency filter screen cavity, and the high-efficiency filter screen cavity is positioned at the upper end of the primary filter screen cavity and is superposed with the primary filter screen cavity;

the upper end of the first partition plate is connected to the lower end of the inner end face of the filter cavity;

the fresh air motor cavity is positioned on the side of the air outlet and communicated with the air outlet;

there is the new trend motor to be fixed in new trend motor intracavity, and be fixed in the shell top.

In the technical scheme, the air return system comprises an air return inlet, an air return inlet cavity, an air return channel, an air return outlet cavity, an air return motor and an air return outlet;

the return air inlet cavity is positioned below the fresh air outlet cavity;

the return air inlet is positioned on two side surfaces of the shell and on two side surfaces of the return air inlet cavity;

the return air inlet cavity is positioned at the upper end of the heat exchanger and communicated with the return air inlet side face;

the return air outlet cavity is positioned below the fresh air inlet cavity;

the air return motor is positioned in the air return outlet cavity;

the return air outlet is positioned on the rear side wall of the shell and positioned at the lower part of the rear cavity part;

the return air outlet is communicated with the return air outlet cavity.

In the technical scheme, the fresh air channel is positioned between the first partition plate and the return air inlet cavity, is positioned at the upper end of the heat exchanger and is communicated with the fresh air outlet side;

the fresh air channel is communicated with the fresh air outlet cavity;

the air return channel is positioned between the first partition plate and the fresh air inlet cavity, positioned at the lower end of the heat exchanger and communicated with the air return outlet side face;

the air return channel is communicated with the air return outlet cavity.

In the above technical solution, an inner side surface of the heat exchanger is located on the first separator;

a fourth partition board is fixed on two side surfaces of the inner cavity and is positioned between the fresh air outlet cavity and the return air inlet cavity; the fresh air inlet is fixed on the upper end surface of the fourth partition plate;

a downward bending structure is arranged on the outer side surface of the fourth partition plate;

a fifth partition plate is positioned between the fresh air inlet cavity and the return air outlet cavity;

the fresh air outlet is fixed on the upper end face of the fifth clapboard;

and an upward bending structure is arranged on the outer side surface of the fifth partition plate.

The utility model has the advantages of as follows:

(1) the utility model is provided with an air conditioning component and a fresh air component, and the air conditioning component and the fresh air component are separated by a first clapboard; the utility model has the functions of refrigeration, heating and fresh air, and has the modes of heating, refrigeration, fresh air, heating and fresh air, and refrigeration and fresh air; the use efficiency of the air conditioner is improved, the space is saved, and the cost is saved;

(2) the utility model has simple and convenient work, energy saving, consumption reduction, high efficiency and safety; because the heat exchanger is arranged, the heat exchange efficiency is 70% -80%, so when fresh air is used, the disturbance to the indoor air temperature is very small, the energy is effectively recovered, and the purposes of energy conservation and consumption reduction are achieved;

(3) the utility model discloses air conditioner subassembly and new trend subassembly share the air outlet, namely the air outlet is the air outlet of refrigerating air, heating air and new trend air, and is rationally distributed, saves space, saves cost;

(4) the utility model is an intelligent three-in-one machine, which has three functions of refrigeration, heating and fresh air cleaning (fresh air entering the room after filtration), can automatically turn on and off according to indoor environment indexes such as air cleanliness, carbon dioxide index, temperature and humidity, and automatically adjust the operation speed and the air volume; the App can be remotely controlled;

(5) the utility model can operate the closed indoor air in four modes, namely a heating mode, a refrigerating mode, a heating + fresh air mode and a refrigerating + fresh air mode, and the fresh air and the return air can be simultaneously performed during refrigerating or heating; in addition, the fresh air mode of the indoor environment can be realized only by depending on an indoor air intelligent management machine under the condition that the outdoor unit of the air conditioner is not operated, and continuous fresh air which is efficiently filtered is provided for the indoor;

(6) the utility model can realize the fresh air mode of the indoor environment only by depending on the operation of the indoor air intelligent management machine under the condition that the outdoor unit of the air conditioner is not operated, and provides continuous fresh air which is efficiently filtered for the indoor environment; the utility model has multiple functions and multiple purposes, is an air conditioner and a fresh air purifier, and is a real indoor air manager (namely an air pipe machine).

Drawings

Fig. 1 is a partial perspective structure diagram of the present invention when the rear cover is absent.

Fig. 2 is a schematic view of a three-dimensional structure of the present invention when the rear cover is absent.

Fig. 3 is a schematic view of the three-dimensional structure of the present invention in the absence of the rear cover.

Fig. 4 is a schematic side view of a partial perspective structure of the present invention in the absence of a side cover.

Fig. 5 is a rear view of the structure in the absence of the rear cover.

Fig. 6 is a rear view structure diagram of the overall structure of the present invention.

Fig. 7 is a schematic view of the overall structure of the present invention.

Fig. 8 is a first schematic view of the arrangement structure of the present invention.

Fig. 9 is a schematic view of the three-dimensional connection of the arrangement structure of the present invention.

In the figure, 1-a front cavity part, 2-a rear cavity part, 3-a shell, 4-an air outlet, 4.1-an air deflector, 5-an air conditioning component, 5.1-a condenser/a radiator, 5.2-an auxiliary heater, 5.3-a water receiving tank, 5.4-an electric control board, 5.5-a cold and hot fan, 5.6-a cold and hot filter screen, 5.7-a blowing air duct, 6-a fresh air component, 6.1-a fresh air system, 6.11-a fresh air inlet, 6.12-a fresh air inlet pipeline, 6.13-a fresh air outlet, 6.14-a fresh air inlet cavity, 6.15-a fresh air outlet cavity, 6.16-a fresh air channel, 6.17-a filter cavity, 6.171-a primary effect filter screen cavity, 6.172-a high-efficiency filter screen cavity, 6.18-a fresh air motor cavity, 6.181-a fresh air motor, 6.19-a sealing cover and 6.2-an air return system, 6.21 parts of return air inlet, 6.22 parts of return air inlet cavity, 6.23 parts of return air channel, 6.24 parts of return air outlet cavity, 6.25 parts of return air motor, 6.26 parts of return air outlet, 6.3 parts of heat exchanger, 6.31 parts of fresh air inlet side, 6.32 parts of return air inlet side, 6.33 parts of fresh air outlet side, 6.34 parts of return air outlet side, 7 parts of first partition plate, 8 parts of inner cavity, 9 parts of display screen, 10 parts of induction system, 11 parts of second partition plate, 12 parts of third partition plate, 13 parts of fourth partition plate, 13.1 parts of downward bent structure, 14 parts of fifth partition plate and 14.1 parts of upward bent structure.

Detailed Description

The following detailed description of the embodiments of the present invention will be made with reference to the accompanying drawings, which are not intended to limit the present invention, but are merely exemplary. While the advantages of the invention will be clear and readily appreciated by the description.

With reference to the accompanying drawings: the indoor air intelligent management machine comprises a shell 3, an air outlet 4 and an inner cavity 8;

the inner cavity 8 is divided into a front cavity part 1 and a rear cavity part 2 by a first clapboard 7;

an air conditioning assembly 5 is positioned in the front cavity part 1;

a fresh air component 6 is positioned in the rear cavity part 2; the four modes of operation can be carried out on the closed indoor air, namely a heating mode, a refrigerating mode, a heating + fresh air mode and a refrigerating + fresh air mode; in addition, the fresh air mode of the indoor environment can be realized only by depending on an indoor air intelligent management machine under the condition that an outdoor unit of the air conditioner is not operated, continuous fresh air which is efficiently filtered is provided for the indoor, and the air conditioner is multifunctional, multifunctional and multipurpose, is not only an air conditioner, but also a fresh air purifier and is a real indoor air intelligent management machine;

the shell 3 is positioned on the periphery of the inner cavity 8, and the air outlet 4 is positioned on the front side wall of the shell 3 and on the upper part of the front cavity part 1;

the fresh air component 6 comprises a fresh air system 6.1, an air return system 6.2 and a heat exchanger 6.3; the heat exchanger 6.3 is communicated with the fresh air system 6.1 and communicated with the return air system 6.2;

the air outlet 4 is communicated with the fresh air system 6.1 and is communicated with the air conditioning assembly 5 (as shown in fig. 1, fig. 2, fig. 3, fig. 4, fig. 5, fig. 6, fig. 7, fig. 8 and fig. 9); the air outlet is a shared air outlet for refrigerating air, heating air and fresh air, and is reasonable in layout and space-saving.

The heat exchanger 6.3 is placed transversely inside the rear cavity portion 2; the heat exchange function of the heat exchanger 6.3 in the utility model is realized to the utmost extent, and the space is saved;

the heat exchanger 6.3 is in a hexagonal structure; the heat exchanger 6.3 comprises a fresh air inlet side 6.31, a return air inlet side 6.32, a fresh air outlet side 6.33 and a return air outlet side 6.34 (as shown in fig. 1 and 4);

an air deflector 4.1 is movably connected to the air outlet 4 (as shown in fig. 1, 4, 7 and 9), and can shield or open the air outlet.

A display screen 9 is arranged on the front side wall of the shell 3 and below the air outlet 4 (as shown in fig. 4, 7 and 9); the display screen 9 is a liquid crystal display screen and displays various indexes of the indoor environment in real time, such as a PM2.5 value in the air, carbon dioxide concentration, indoor temperature and humidity and the like;

an induction system 10 is positioned in the middle of the first partition 7 and between the fresh air system 6.1 and the return air system 6.2; the induction system 10 comprises an induction controller and an air quality sensor;

the induction system 10 is arranged on the rear cavity part 2 and above the heat exchanger 6.3 (as shown in fig. 1) for detecting the air quality and adjusting the operation state of the machine; the operation of the indoor air intelligent management machine and the air conditioner outdoor unit is carried out by combining a display screen on the front panel, an electric control board on the front cavity and an induction system of the rear cavity; the electric control board controls the operation of the compressor and each fan, and the induction system monitors the indoor environment.

The air conditioning component 5 comprises a condenser/radiator 5.1, an auxiliary heater 5.2, a water receiving tank 5.3, an electric control plate 5.4, a cold and hot fan 5.5, a cold and hot filter screen 5.6 and an air supply duct 5.7; the auxiliary heater 5.2 is located on the condenser/radiator 5.1; the condenser/radiator 5.1 is fixed to the upper part of the front chamber portion 1; the water receiving tank 5.3 is positioned at the lower end of the condenser/radiator 5.1; the electric control plate 5.4 is positioned below the water receiving tank 5.3; the cold and hot filter screen 5.6 is positioned at the front ends of the water receiving tank 5.3 and the electric control plate 5.4; the cold and hot air blower 5.5 is fixed between the electric control board 5.4 and the first partition 7 (as shown in fig. 1 and 4); realize the utility model discloses a heating and refrigeration function.

The fresh air system 6.1 comprises a fresh air inlet 6.11, a fresh air inlet pipeline 6.12, a fresh air outlet 6.13, a fresh air inlet cavity 6.14, a fresh air outlet cavity 6.15, a fresh air channel 6.16, a filter cavity 6.17 and a fresh air motor cavity 6.18;

the fresh air inlet 6.11 is positioned on the rear side wall of the shell 3 and is positioned at the upper part of the rear cavity part 2; the fresh air inlet 6.11 is used for introducing fresh air;

the fresh air outlet 6.13 is positioned in the fresh air inlet cavity 6.14 and at the lower end of the heat exchanger 6.3; fresh air exhausted from the fresh air outlet 6.13 enters the fresh air inlet cavity 6.14 and then enters the heat exchanger 6.3 for heat exchange;

the fresh air inlet cavity 6.14 is positioned at the lower end of the heat exchanger 6.3 and is communicated with the fresh air inlet side surface 6.31; fresh air in the fresh air inlet cavity 6.14 enters the heat exchanger 6.3 through the fresh air inlet side 6.31 for heat exchange, and is discharged out of the heat exchanger 6.3 through the fresh air outlet side 6.3;

the fresh air inlet 6.11 is communicated with the fresh air outlet 6.13 through a fresh air inlet pipeline 6.12; fresh air enters a fresh air inlet pipeline 6.12 through a fresh air inlet 6.11 and is discharged through a fresh air outlet 6.13, so that a fresh air inlet function is realized;

the fresh air inlet pipeline 6.12 is positioned on the side of the heat exchanger 6.3; the position 6.19 with the sealing cover is arranged in parallel with the heat exchanger 6.3; the sealing cover 6.19 is positioned above the fresh air inlet pipeline 6.12; the shell 3 is tightly buckled and covered on the end faces of the heat exchanger 6.3 and the sealing cover 6.19, so that the sealing performance of the device is ensured, fresh air is ensured to run in a fresh air channel, and dirty air is ensured to run in an air return channel; the phenomenon of cross operation is prevented.

The filter cavity 6.17 and the fresh air motor cavity 6.18 are positioned at the upper end of the rear cavity part 2;

the filter cavity 6.17 and the fresh air motor cavity 6.18 are arranged at intervals, and are positioned below the fresh air motor cavity 6.18 and above the fresh air outlet cavity 6.15;

the filter chamber 6.17 comprises a primary filter screen chamber 6.171 and a high-efficiency filter screen chamber 6.172, the high-efficiency filter screen chamber 6.172 is positioned at the upper end of the primary filter screen chamber 6.171 and is superposed with the primary filter screen chamber; fresh air is discharged from a heat exchanger 6.3 through a fresh air outlet side 6.3, enters a fresh air channel 6.16, then enters a fresh air outlet cavity 6.15, then enters a primary filter screen cavity 6.171 from the lower end of a filter cavity 6.17 for primary filtering, then enters a high-efficiency filter screen cavity 6.172 from the lower end for fine filtering, and the filtered fresh air is discharged from the upper end of the filter cavity 6.17, enters a fresh air motor cavity 6.18, and then is discharged from an air outlet 4 through a fresh air motor 6.181 in the fresh air motor cavity 6.18;

the upper end of the first partition plate 7 is connected with the lower end of the inner end surface of the filter cavity 6.17; the fresh air entering the fresh air outlet cavity 6.15 is ensured to enter the filter cavity 6.17 from the lower end, and the utilization efficiency of the fresh air is improved;

the fresh air motor cavity 6.18 is positioned on the side of the air outlet 4 and communicated with the air outlet 4;

a fresh air motor 6.181 is fixed in the fresh air motor cavity 6.18 and fixed at the top end of the shell 3 (as shown in fig. 1); guarantee that the new trend is discharged from air outlet 4, rationally distributed, space utilization is higher.

The air return system 6.2 comprises an air return inlet 6.21, an air return inlet cavity 6.22, an air return channel 6.23, an air return outlet cavity 6.24, an air return motor 6.25 and an air return outlet 6.26; the air return function is realized;

the return air inlet cavity 6.22 is positioned below the fresh air outlet cavity 6.15;

the return air inlet 6.21 is positioned on two side surfaces of the shell 3 and on two side surfaces of the return air inlet cavity 6.22; the air return inlet 6.21 is in a shutter shape and is symmetrically arranged on two sides of the middle part of the rear cavity; indoor dirty air enters the return air inlet cavity 6.22 through the return air inlet 6.21; the air inlet quantity requirement of the inlet is met;

the return air inlet cavity 6.22 is positioned at the upper end of the heat exchanger 6.3 and is communicated with the return air inlet side surface 6.32; dirty air entering the return air inlet cavity 6.22 enters the heat exchanger 6.3 through the return air inlet side 6.32 for heat exchange, is discharged out of the heat exchanger 6.3 through the return air outlet side 6.34 and enters the return air channel 6.23;

the return air outlet cavity 6.24 is positioned below the fresh air inlet cavity 6.14;

the return air motor 6.25 is positioned in the return air outlet cavity 6.24;

the return air outlet 6.26 is positioned on the rear side wall of the shell 3 and is positioned at the lower part of the rear cavity part 2;

the return air outlet 6.26 is communicated with the return air outlet cavity 6.24 (as shown in fig. 1); the dirty air which is discharged out of the heat exchanger 6.3 through the air return air outlet side face 6.34 and enters the air return channel 6.23 enters the air return air outlet cavity 6.24, is discharged to the air return air outlet 6.26 through the air return motor 6.25 and is discharged out of the room;

the fresh air channel 6.16 is positioned between the first partition plate 7 and the return air inlet cavity 6.22, is positioned at the upper end of the heat exchanger 6.3 and is communicated with the fresh air outlet side surface 6.33;

the fresh air channel 6.16 is communicated with the fresh air outlet cavity 6.15 (as shown in fig. 2).

The return air channel 6.23 is positioned between the first partition plate 7 and the fresh air inlet cavity 6.14, positioned at the lower end of the heat exchanger 6.3 and communicated with the return air outlet side surface 6.34;

the return air channel 6.23 is communicated with the return air outlet cavity 6.24 (as shown in fig. 3); the dirty air which is discharged from the heat exchanger 6.3 through the air return air outlet side face 6.34 and enters the air return channel 6.23 enters the air return air outlet cavity 6.24, is discharged to the air return air outlet 6.26 through the air return motor 6.25 and is discharged out of the room.

The inner side surface of the heat exchanger 6.3 is positioned on the first clapboard 7 (as shown in figures 1 and 4), and the first clapboard 7 is divided into an upper part and a lower part by the inner side surface of the heat exchanger 6.3;

a second partition plate 11 is positioned on the inner end surface of the return air inlet cavity 6.22; a third partition plate 12 is arranged on the inner end face of the fresh air inlet cavity 6.14;

the second partition plate 11 and the third partition plate 12 are positioned on the same straight line and are respectively positioned at the upper top end and the lower top end of the heat exchanger 6.3; the return air inlet side surface 6.32 is positioned on the outer side of the second partition plate 11, and the fresh air outlet side surface 6.33 is positioned on the inner side of the second partition plate 11;

the fresh air inlet side surface 6.31 is positioned on the outer side of the third partition plate 12, and the return air outlet side surface 6.34 is positioned on the inner side of the third partition plate 12;

the fresh air outlet side face 6.33, the upper part of the first partition plate 7 and the second partition plate 11 form a fresh air channel 6.16;

the return air outlet side face 6.34, the lower part of the first partition 7 and the third partition 12 form the return air channel 6.23;

fourth partition plates 13 are fixed on two side surfaces of the inner cavity 8 and the second partition plate 11, and the fourth partition plates 13 are positioned between the fresh air outlet cavity 6.15 and the return air inlet cavity 6.22; the fresh air inlet 6.11 is fixed on the upper end face of the fourth partition plate 13;

a downward bending structure 13.1 is arranged on the outer side surface of the fourth partition plate 13; the sealing effect is ensured;

a fifth clapboard 14 is positioned between the fresh air inlet cavity 6.14 and the return air outlet cavity 6.24;

the fresh air outlet 6.13 is fixed on the upper end face of the fifth clapboard 14;

an upward bending structure 14.1 (shown in fig. 1, 2, 3 and 4) is arranged on the outer side surface of the fifth partition plate 14; the sealing effect is ensured.

The working method of the indoor air intelligent management machine of the utility model comprises the following steps,

the indoor air intelligent management machine comprises five operation modes which are respectively as follows: a heating mode, a refrigerating mode, a fresh air mode, a heating and fresh air mode and a refrigerating and fresh air mode;

the method comprises the following steps: when the heating mode is activated, the heater is turned on,

starting the indoor unit cold and hot fans while starting the outdoor unit of the air conditioner;

the main components in the outdoor unit comprise a compressor, a condenser, a condensing fan, a liquid separator, a liquid accumulator, a reversing valve, a capillary tube gas pipe, an outdoor unit shell and the like; the main components of the indoor unit are as follows: the device comprises a heat evaporator (comprising an electric heating tube), a cold and hot fan, a fresh air fan, a return air fan, a heat exchanger, a filter screen, an air outlet assembly, an intelligent control circuit board, a liquid crystal display screen, an ozone disinfection lamp, an anion generator, an indoor unit shell and the like;

during heating, low-pressure steam of refrigerant gas is pressurized by the compressor to become high-temperature high-pressure gas and enters a condenser/radiator 5.1 of the indoor unit; the refrigerant gas is condensed and liquefied in the condenser/radiator 5.1 to release heat, becomes refrigerant liquid, and heats the indoor air at the same time, thereby achieving the purpose of increasing the indoor temperature;

the refrigerant liquid is decompressed by the throttling device and enters a heat exchanger/evaporator of the outdoor unit, the refrigerant liquid is evaporated, gasified and absorbs heat to become refrigerant gas, and meanwhile, the heat of outdoor air is absorbed to become low-pressure refrigerant gas; the low-pressure refrigerant gas enters the compressor again and the next heating cycle is started;

the hot air flow formed in the heating circulation process sends hot air into the room from the air outlet 4 through the condenser/radiator 5.1 of the indoor unit to form a hot air flow channel;

step two: when the cooling mode is activated, the air conditioner is operated,

during refrigeration, the compressor is started, and refrigerant gas is pressurized by the compressor to become high-temperature high-pressure gas; the refrigerant gas enters a condenser of the outdoor unit, is condensed, liquefied and released to form refrigerant liquid, and simultaneously heat is released to the atmosphere; the liquid refrigerant is decompressed by the throttling device, enters an evaporator of the indoor unit, is evaporated to absorb heat to become a gas refrigerant, and simultaneously, the refrigerant liquid absorbs the heat of indoor air, thereby achieving the purpose of reducing the indoor temperature; the refrigerant gas enters the compressor again and the next refrigeration cycle is started;

the cold air flow formed in the process of the refrigeration cycle sends cold air into the room from the air outlet 4 through the condenser/radiator 5.1 of the indoor unit to form a cold air flow channel;

step three: when the fresh air mode is started, the air conditioner is started,

when the fresh air mode is started, the return air mode is started at the same time;

the fresh air mode is as follows: when the fresh air system works, the fresh air motor 6.181 is started, the fresh air motor 6.181 generates negative pressure, and outdoor fresh air is sucked into a room through the fresh air system 6.1;

fresh air enters a fresh air inlet pipeline 6.12 through a fresh air inlet 6.11, is discharged from a fresh air outlet 6.13 and enters a fresh air inlet cavity 6.14, enters a heat exchanger 6.3 from a fresh air inlet side 6.31 and is discharged from a fresh air outlet side 6.33, enters a fresh air outlet cavity 6.15 through a fresh air channel 6.16, enters from the lower end of a filter cavity 6.17, is discharged from the upper end of the filter cavity 6.17, is discharged to an air outlet 4 through a fresh air motor 6.181 and enters a room to form a fresh air flow channel (as shown in figures 1 and 2);

the air return mode is as follows: when the air return system works, the air return motor 6.25 is started, the air return motor 6.25 generates negative pressure, and indoor dirty air is discharged out of a room through the air return system 6.2;

the indoor viscera air enters a return air inlet cavity 6.22 through a return air inlet 6.21, enters a heat exchanger 6.3 from a return air inlet side 6.32, is discharged out of the heat exchanger 6.3 from a return air outlet side 6.34, enters a return air outlet cavity 6.24 through a return air channel 6.23, is discharged to a return air outlet 6.26 through a return air motor 6.25 and is discharged out of a room to form a return air flow passage (as shown in fig. 1 and 3);

step four: when the heating and fresh air modes are started,

the heating mode is the same as the first step; the fresh air mode is the same as the third step;

step five: when the cooling and fresh air modes are activated,

the refrigeration mode is the same as the step two, and the fresh air mode is the same as the step three.

In order to explain more clearly the indoor air intelligent management machine compare the advantage that has with current indoor air intelligent management machine, the staff contrasts these two kinds of technical scheme, its contrast result is as follows:

according to last table, room air intelligent management machine and current room air intelligent management machine, have multiple functions (having and heat, refrigeration and new trend function), a tractor serves several purposes, the mode of operation is including heating the mode, the mode of refrigeration, heating and new trend mode, refrigeration and new trend mode to and new trend mode alone, the complete machine utilization ratio reaches 100%.

Examples

The embodiment of the utility model provides an in, provide an indoor air intelligent management machine, it passes through pipeline (copper pipe) and cable conductor etc. and air condensing units UNICOM.

Two holes with the diameter of about 120 mm are formed in the building wall body for installing the air conditioner outdoor unit, and the two holes are respectively connected with a fresh air inlet and a return air outlet on the indoor air intelligent management machine through hoses.

Under the cooling mode and the heating mode, the indoor air intelligent management machine is matched with an air conditioner outdoor unit to cool or heat the indoor environment.

Under the new trend mode, outdoor air can get into indoorly from indoor air intelligent management machine through the new trend air intake, provides fresh air for indoor environment.

In an embodiment, an indoor air intelligent manager includes a housing having an interior cavity, the housing divided into a front chamber and a rear chamber; the upper part of the front cavity is provided with an air outlet; the air outlet is a common air outlet when refrigerating, heating and fresh air are supplied;

when the heating mode or the cooling mode is started, the outdoor unit of the air conditioner is started, and the cold and hot fans of the indoor unit are started at the same time; the formed air flow sends out hot air or cold air from the air outlet through a condenser (also called a radiator) and the like to form a hot/cold air flow channel;

when the fresh air mode is started, the return air mode is started at the same time;

the fresh air mode is as follows: when the fresh air system works, the fresh air motor 6.181 is started, the fresh air motor 6.181 generates negative pressure, and outdoor fresh air is sucked into a room through the fresh air inlet 6.11 and the fresh air system 6.1;

fresh air enters a fresh air inlet pipeline 6.12 through a fresh air inlet 6.11, is discharged from a fresh air outlet 6.13 and enters a fresh air inlet cavity 6.14, enters a heat exchanger 6.3 from a fresh air inlet side 6.31 and is discharged from a fresh air outlet side 6.33, enters a fresh air outlet cavity 6.15 through a fresh air channel 6.16, enters from the lower end of a filter cavity 6.17, is discharged from the upper end of the filter cavity 6.17, is discharged to an air outlet 4 through a fresh air motor 6.181 and enters a room to form a fresh air flow channel (as shown in figures 1 and 2);

the air return mode is as follows: when the air return system works, the air return motor 6.25 is started, the air return motor 6.25 generates negative pressure, and indoor dirty air is discharged out of a room through the air return system 6.2;

the indoor viscera air enters the return air inlet cavity 6.22 through the return air inlet 6.21, enters the heat exchanger 6.3 from the return air inlet side 6.32, is discharged out of the heat exchanger 6.3 from the return air outlet side 6.34, enters the return air outlet cavity 6.24 through the return air channel 6.23, is discharged to the return air outlet 6.26 through the return air motor 6.25 and is discharged out of the room to form a return air flow passage (as shown in fig. 1 and 3).

Other parts not described belong to the prior art.

Claims (9)

1. Indoor air intelligent management machine, including shell (3) and air outlet (4), its characterized in that: still include inner chamber (8), air conditioner subassembly (5) and new trend subassembly (6), wherein:

the inner cavity (8) is arranged in the shell (3), the inner cavity (8) is divided into a front cavity part (1) and a rear cavity part (2) through a first partition plate (7), and the air outlet (4) is located on the side wall of the front cavity part (1);

the air conditioning assembly (5) is located within the front cavity portion (1);

the fresh air component (6) is positioned in the rear cavity part (2);

the fresh air component (6) comprises a fresh air system (6.1), an air return system (6.2) and a heat exchanger (6.3); the heat exchanger (6.3) is communicated with the fresh air system (6.1) and communicated with the return air system (6.2);

the air outlet (4) is communicated with the fresh air system (6.1) and the air conditioning component (5).

2. The intelligent indoor air manager of claim 1, wherein: the heat exchanger (6.3) is placed transversely inside the rear cavity portion (2);

the heat exchanger (6.3) is of a hexagonal structure; the heat exchanger (6.3) comprises a fresh air inlet side surface (6.31), a return air inlet side surface (6.32), a fresh air outlet side surface (6.33) and a return air outlet side surface (6.34).

3. The intelligent indoor air manager of claim 2, wherein: a display screen (9) is arranged on the front side wall of the shell (3) and is positioned below the air outlet (4);

the air deflector is movably connected to the air outlet (4);

an induction system (10) is arranged on the rear cavity part (2) and above the heat exchanger (6.3);

the induction system (10) is located between the fresh air system (6.1) and the return air system (6.2).

4. The intelligent indoor air manager of claim 3, wherein: the air conditioning component (5) comprises a condenser/radiator (5.1), an auxiliary heater (5.2), a water receiving tank (5.3), an electric control plate (5.4), a cold and hot fan (5.5), a cold and hot filter screen (5.6) and an air supply duct (5.7); the auxiliary heater (5.2) is positioned on the condenser/radiator (5.1); the condenser/radiator (5.1) is fixed on the upper part of the front cavity part (1); the water receiving tank (5.3) is positioned at the lower end of the condenser/radiator (5.1); the electric control plate (5.4) is positioned below the water receiving tank (5.3); the cold and hot filter screen (5.6) is positioned at the front ends of the water receiving tank (5.3) and the electric control plate (5.4); the cold and hot air blower (5.5) is fixed between the electric control plate (5.4) and the first partition plate (7).

5. The intelligent indoor air manager of claim 4, wherein: the fresh air system (6.1) comprises a fresh air inlet (6.11), a fresh air inlet pipeline (6.12), a fresh air outlet (6.13), a fresh air inlet cavity (6.14), a fresh air outlet cavity (6.15), a fresh air channel (6.16), a filter cavity (6.17) and a fresh air motor cavity (6.18);

the fresh air inlet (6.11) is positioned on the rear side wall of the shell (3) and is positioned at the upper part of the rear cavity part (2);

the fresh air outlet (6.13) is positioned in the fresh air inlet cavity (6.14) and at the lower end of the heat exchanger (6.3);

the fresh air inlet cavity (6.14) is positioned at the lower end of the heat exchanger (6.3) and communicated with the fresh air inlet side surface (6.31);

the fresh air inlet (6.11) is communicated with the fresh air outlet (6.13) through the fresh air inlet pipeline (6.12);

the fresh air inlet pipeline (6.12) is positioned on the side of the heat exchanger (6.3); the sealing cover (6.19) is arranged in parallel with the heat exchanger (6.3); the sealing cover (6.19) is positioned above the fresh air inlet pipeline (6.12).

6. The intelligent indoor air manager of claim 5, wherein: the filter cavity (6.17) and the fresh air motor cavity (6.18) are positioned at the upper end of the rear cavity part (2);

the filter cavity (6.17) and the fresh air motor cavity (6.18) are arranged at intervals, and are positioned below the fresh air motor cavity (6.18) and above the fresh air outlet cavity (6.15);

the filter chamber (6.17) comprises a primary filter screen chamber (6.171) and a high-efficiency filter screen chamber (6.172), the high-efficiency filter screen chamber (6.172) is positioned at the upper end of the primary filter screen chamber (6.171) and is superposed with the primary filter screen chamber;

the upper end of the first partition plate (7) is connected with the lower end of the inner end surface of the filter cavity (6.17);

the fresh air motor cavity (6.18) is positioned at the side of the air outlet (4) and communicated with the air outlet (4);

a fresh air motor (6.181) is fixed in the fresh air motor cavity (6.18) and is fixed at the top end of the shell (3).

7. The intelligent indoor air manager of claim 6, wherein: the air return system (6.2) comprises an air return inlet (6.21), an air return inlet cavity (6.22), an air return channel (6.23), an air return outlet cavity (6.24), an air return motor (6.25) and an air return outlet (6.26);

the return air inlet cavity (6.22) is positioned below the fresh air outlet cavity (6.15);

the return air inlet (6.21) is positioned on two side faces of the shell (3) and two side faces of the return air inlet cavity (6.22);

the return air inlet cavity (6.22) is positioned at the upper end of the heat exchanger (6.3) and communicated with the return air inlet side surface (6.32);

the return air outlet cavity (6.24) is positioned below the fresh air inlet cavity (6.14);

the return air motor (6.25) is positioned in the return air outlet cavity (6.24);

the return air outlet (6.26) is positioned on the rear side wall of the shell (3) and is positioned at the lower part of the rear cavity part (2);

the return air outlet (6.26) is communicated with the return air outlet cavity (6.24).

8. The intelligent indoor air manager of claim 7, wherein: the fresh air channel (6.16) is positioned between the first partition plate (7) and the return air inlet cavity (6.22), is positioned at the upper end of the heat exchanger (6.3) and is communicated with the fresh air outlet side surface (6.33);

the fresh air channel (6.16) is communicated with the fresh air outlet cavity (6.15);

the return air channel (6.23) is positioned between the first partition plate (7) and the fresh air inlet cavity (6.14), is positioned at the lower end of the heat exchanger (6.3) and is communicated with the return air outlet side surface (6.34);

the return air channel (6.23) is communicated with the return air outlet cavity (6.24).

9. The intelligent indoor air manager of claim 8, wherein: the inner side of the heat exchanger (6.3) is located on the first partition (7);

fourth partition plates (13) are fixed on two side surfaces of the inner cavity (8), and the fourth partition plates (13) are positioned between the fresh air outlet cavity (6.15) and the return air inlet cavity (6.22); the fresh air inlet (6.11) is fixed on the upper end surface of the fourth partition plate (13);

a downward bending structure (13.1) is arranged on the outer side surface of the fourth partition plate (13);

a fifth clapboard (14) is positioned between the fresh air inlet cavity (6.14) and the return air outlet cavity (6.24);

the fresh air outlet (6.13) is fixed on the upper end surface of the fifth clapboard (14);

an upward bending structure (14.1) is arranged on the outer side surface of the fifth partition plate (14).

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