CN114110880B - Air treatment device - Google Patents

Abstract

The present invention provides an air treatment apparatus comprising: the shell is provided with a first air port and a second air port which are communicated with the indoor space, and a third air port and a fourth air port which are communicated with the outdoor space, wherein the first air port and the third air port are communicated to form a second air channel, and the second air port and the fourth air port are communicated to form a first air channel; the mounting plate is arranged in the shell, a first mounting through hole is formed in the mounting plate, and the second air port and the fourth air port are respectively positioned on two sides of the mounting plate; the limiting piece is connected with the first mounting through hole and defines an accommodating space; the adsorption component is accommodated in the accommodating space and can rotate in the accommodating space; the driving assembly is arranged in the shell and can drive the adsorption assembly to rotate. Through set up the adsorption component between air inlet passageway and exhaust passageway, do not need to design structures such as dehumidification module, simplified the structure of air treatment facility, be favorable to reducing the processing cost of air treatment facility.

Description

Air treatment device

Technical Field

The invention belongs to the technical field of fresh air equipment, and particularly relates to air treatment equipment.

Background

When indoor air humidity is low, traditional fresh air equipment is through inside humidification/dehumidification module to indoor humidification/dehumidification, however, because of there being humidification/dehumidification module, lead to fresh air equipment's structure complicacy, processing cost is higher.

Disclosure of Invention

The present invention aims to solve one of the technical problems existing in the prior art or related technologies.

In view of this, the present invention proposes an air treatment device comprising: the shell is provided with a first air port and a second air port which are communicated with the outside of the room, and a third air port and a fourth air port which are communicated with the inside of the room, wherein the first air port and the third air port are communicated to form a second air channel, the second air port and the fourth air port are communicated to form a first air channel, and the first air channel and the second air channel are not communicated with each other; the mounting plate is arranged in the shell, extends along the length direction of the shell, is provided with a first mounting through hole, and is respectively positioned at two sides of the mounting plate, and the second air hole and the fourth air hole are respectively positioned at two sides of the mounting plate; the limiting piece is connected with the first mounting through hole and extends along the direction deviating from the mounting plate, and the limiting piece defines an accommodating space; the adsorption assembly is accommodated in the accommodating space and can rotate in the accommodating space, and a first area of the adsorption assembly can reciprocally rotate between the first air duct and the second air duct; the driving assembly is arranged in the shell and can drive the adsorption assembly to rotate.

According to the air treatment equipment provided by the invention, the first air channel and the second air channel are arranged in the shell, one of the first air channel and the second air channel can be used as an air inlet channel, the other of the first air channel and the second air channel can be used as an air exhaust channel, and the first air channel is used as the air inlet channel and the second air channel is used as the air exhaust channel for exemplary illustration. Outdoor air can enter the first air channel through the second air opening, then air enters the room through the fourth air opening, indoor air can enter the second air channel through the second air opening of the third air opening, and then the air is discharged to the outside through the first air opening, so that indoor and outdoor air exchange is realized.

In summer, compared with the indoor environment, the outdoor environment is higher in temperature and humidity, when outdoor air enters the first air duct, the outdoor air meets the adsorption component with relatively lower temperature and humidity, and the first area on the adsorption component can adsorb heat and moisture of the outdoor air, so that the temperature and humidity of the air entering the indoor environment are reduced. The first area after adsorption is in a high-temperature and high-humidity state, and the first area rotates to the second air duct along with the rotation of the adsorption component, when indoor gas is discharged outwards, the indoor gas takes away heat and moisture at the first area, so that the heat and the moisture are discharged outdoors. The wind entering the room is dry wind, and the discharged wind is wind with moisture, which is equivalent to the function of dehumidifying the indoor air.

Through set up the adsorption component between first wind channel and second wind channel, can realize the indoor function of dehumidifying, do not need to design dehumidification module isotructure, simplified the structure of air treatment facility, be favorable to reducing the processing cost of air treatment facility.

In addition, because the air treatment equipment with simple structure can reduce indoor humidity, the indoor air conditioner does not need to be independently started to dehumidify the indoor space, so that electric energy can be saved, and the running pressure of the air conditioner can be reduced.

The first air duct and the second air duct are two independent channels, so that the air in the first air duct and the air in the second air duct are not easy to mix with each other, humidification and dehumidification functions can be stably realized, and the working stability of the air treatment equipment is improved.

Because the first air port and the third air port are respectively positioned at two sides of the mounting plate, the mounting plate divides the second air channel into two parts, and the air flow entering the second air channel can be ensured to flow through the adsorption component completely. Likewise, the second air port and the fourth air port are respectively positioned at two sides of the mounting plate, the mounting plate divides the first air channel into two parts, so that air flow entering the first air channel can flow through the adsorption assembly completely, and the humidifying and dehumidifying effects are improved.

The adsorption component can extend into the accommodating space of the limiting part through the first mounting through hole, and the setting of the limiting part can be favorable for reducing the gap between the adsorption component and the mounting plate, so that the mixing of the gas in the first air duct and the second air duct is avoided, and the dehumidification effect of the air treatment equipment is further improved.

In addition, the air treatment device in the technical scheme provided by the invention can also have the following additional technical characteristics:

in one possible design, the mounting plate separates the first air duct into a first sub-air duct and a second sub-air duct, the first sub-air duct and the second sub-air duct being stacked; the mounting plate separates the second air duct into a third sub-air duct and a fourth sub-air duct, and the third sub-air duct and the fourth sub-air duct are arranged in a stacked mode.

In this design, since the first sub-duct and the second sub-duct are distributed in the height direction, the extending direction of the first duct is changed from the inlet of the first duct to the outlet of the first duct. Similarly, the third sub-air duct and the fourth sub-air duct are distributed in the height direction, so that the extending direction of the second air duct is changed from the inlet of the second air duct to the outlet of the second air duct. The air flow entering the first air duct and the air flow entering the second air duct are not only required to flow transversely, but also required to flow vertically, so that the first air duct and the second air duct cannot occupy more space in a single direction, the difference between the height and the width of the air treatment equipment is smaller, the air treatment equipment is further suitable for being installed at the installation position with the smaller difference between the height and the width, and the applicability of the air treatment equipment is improved on the basis of simplifying the structure of the air treatment equipment.

In one possible design, the air treatment device further comprises: the baffle assembly is arranged in the shell, the baffle assembly divides the upper space of the mounting plate into a first sub-air channel and a fourth sub-air channel, and the baffle assembly divides the lower space of the mounting plate into a second sub-air channel and a third sub-air channel.

In this design, the baffle subassembly separates the upper portion space of casing into first sub-wind channel and fourth sub-wind channel to and the lower part space of casing separates into second sub-wind channel and third sub-wind channel, and the spacer effect of baffle subassembly avoids the gaseous mixture in first wind channel and the second wind channel, improves humidification and dehumidification effect.

In one possible design, the baffle assembly includes: the first baffle is positioned above the mounting plate; and the second partition plate is positioned below the mounting plate.

In this design, the first partition separates the upper space of the housing into a first sub-air duct and a fourth sub-air duct, and the second partition separates the lower space of the housing into a second sub-air duct and a third sub-air duct. Through setting up first baffle and second baffle, so the baffle subassembly is split type structure, is convenient for carry out the dismouting to the baffle subassembly.

In one possible design, the first partition and/or the second partition includes a second mounting port through which the shaft center of the adsorption assembly passes.

In this design, the axle center of adsorption component can stretch into in the second installation opening, and adsorption component is when rotating, and the pivot can rotate in the second installation opening, and the second installation opening can play limiting displacement to the pivot, avoids adsorption component to take place to deflect when rotating, improves the stability when adsorption component rotates. Illustratively, can install the bearing in the second installation opening, the axle center of bearing and adsorption component is assembled mutually for adsorption component can rotate steadily, avoids adsorption component to take place the friction with other parts, can effectively avoid because of the noise that adsorption component produced when rotating, is favorable to promoting the user to air treatment equipment's use experience.

In one possible design, the housing includes: the first air port and the second air port are arranged on the first side wall and distributed along the diagonal direction of the first side wall; the second side wall, the third wind gap and the fourth wind gap are located the second side wall, and third wind gap and fourth wind gap are distributed along the diagonal direction of second side wall.

In this design, first wind gap and second wind gap are along diagonal direction distribution, and third wind gap and fourth wind gap are along diagonal direction distribution for second wind gap and fourth wind gap and the entry and the exit position looks adaptation of first wind channel need not set up the pipeline that is used for linking to each other with second wind gap and fourth wind gap at the entry and the export of first wind channel, are favorable to simplifying the structure of product. Similarly, the first and third tuyeres are adapted to the inlet and outlet positions of the second air duct, and no pipes for connection to the first and third tuyeres need to be provided at the inlet and outlet of the second air duct.

In one possible design, the air treatment device further comprises: the first air supply assembly is arranged in the second sub-air duct; the second air supply assembly is arranged in the fourth sub-air duct.

In this design, first air supply subassembly is installed in the second sub-wind channel, and first air supply subassembly can drive the air current for first air supply subassembly can be with outdoor air pumping to indoor. The second air supply assembly is arranged in the fourth sub-air duct, and can drive air flow, so that the second air supply assembly can pump indoor air outdoors. The first air supply assembly and the second air supply assembly are arranged to improve the air flow rate, so that better humidifying and dehumidifying effects can be achieved in a shorter time.

In one possible design, the air treatment device further comprises: and the heating component is arranged in the second air duct.

In this design, a heating assembly is mounted within the first air duct, the heating assembly being capable of heating the gas entering the first air duct. In winter, the heating component can be started, and the gas entering the room is heated by the heating component to be at a higher temperature, so that the function of heating the room is realized, and the use experience of a user on the air treatment equipment is improved. The temperature of the air inlet is increased through the heating component, the indoor air conditioner does not need to be started to heat the indoor, or the air conditioner can be controlled to operate at lower power, so that the energy consumption of the indoor air conditioner is effectively reduced. Moreover, because heating element can heat the gas that gets into in the first wind channel, high temperature gas can take away the moisture on the adsorption component high efficiency, further promotes indoor humidification effect.

In winter, relative to outdoor, indoor air's temperature and humidity are higher, and when indoor gas outwards discharged, when meetting the relative lower adsorption component of temperature and humidity, the first region on the adsorption component can adsorb gaseous heat and moisture. The heating element heats the gas in the first air flue, and when the first region rotates to the first air flue, the high-temperature gas in the first air flue can evaporate the water on the adsorption element and blow the water back into the room along with the air inlet so as to bring the water back into the room. Under the condition of ensuring that the moisture of indoor gas is basically not lost, the moisture of outdoor gas also enters the room, and the function of humidifying the room is realized. The gas is heated by the heating component, so that the gas entering the chamber is ensured to be high-temperature and high-humidity gas.

In one possible design, the air treatment device further comprises: the first filter piece is arranged in the first air duct and is positioned between the second air port and the adsorption component; and/or the second filter piece is arranged in the second air duct, and the second filter piece is positioned between the third air port and the adsorption component.

In this design, first filter is installed in first wind channel, and the gas that gets into in the first wind channel can be through first filter, and first filter can filter the air inlet, avoids impurity in the air to enter into indoor, is favorable to improving air quality. Moreover, the filtering effect of the first filtering piece can avoid the contact of impurities and the adsorption component, avoid the blockage of the adsorption component caused by the impurities, and ensure the functional stability of the adsorption component.

The first filter element contacts with the inner wall of the first air duct, so that the air entering the first air duct needs to pass through the first filter element, and the filtering effect on the air inlet is improved.

The second filter is installed in the second wind channel, and the gas that gets into in the second wind channel can pass through the second filter, and the second filter can filter airing exhaust, avoids impurity in the air to advance with the adsorption component contact to avoid impurity to cause adsorption component to block up, ensure adsorption component's functional stability.

The second filter element contacts with the inner wall of the second air duct, so that the air entering the second air duct needs to pass through the second filter element, and the filtering effect on exhaust air is improved.

In one possible design, the heating element is a heating mesh; the first filter element is positioned between the second tuyere and the heating net.

In this design, the heating network comprises a plurality of heater strips for the heating network can heat the gaseous gas that passes through, improves the indoor gas temperature that gets into, and the area of contact of heating network and gas is great, can improve the heating rate of gas, thereby is favorable to rising indoor temperature fast. In order to enable the gas to pass through the heating net, a gap is required to be arranged on the heating net, if impurities are contacted with the heating net, the heating net can be blocked, and safety accidents can occur when the impurities are contacted with the high-temperature heating net. In order to avoid above-mentioned problem, this design sets up first filter between second wind gap and heating net, and first filter can block the impurity in the air inlet, and the air inlet has been filtered through first filter when contacting the heating net, avoids impurity and heating net contact, avoids impurity to cause the heating net to block up, also avoids impurity and high temperature heating net contact still probably to take place the incident, has improved the stability of air treatment facility during operation.

In other designs, the heating assembly may also include a heater wire or a heater rod.

In one possible design, the air treatment device further comprises: and the air quality sensor is arranged in the second air duct and is used for monitoring indoor air quality.

In this design, air quality sensor installs in the second wind channel, and air quality sensor can detect the gas quality that gets into in the second wind channel, then can feed back the testing result to the user, for example can set up the display screen on air treatment facility, and the display screen shows the testing result of air quality, makes things convenient for the user to know current indoor air quality. The air treatment equipment can also carry out data transmission with the electronic equipment of the user, so that the air treatment equipment can send data such as air quality to the user, and the user can know the data in time conveniently. When the air quality is poor, prompt information such as sound prompts or light prompts can be output, and a user can know the indoor air quality in time.

In one possible application, the air quality sensor may be at least one of a formaldehyde sensor, a carbon dioxide sensor, and a PM2.5 sensor.

In one possible design, the air quality sensor is located between the third tuyere and the suction assembly.

In this design, air quality sensor is located between third wind gap and the adsorption module, avoids adsorption module to adsorb the back detection of a portion impurity in the air, can effectively provide the accuracy of testing result.

In one possible design, the drive assembly includes: the motor is assembled with the adsorption component; or the drive assembly includes: the motor is arranged on the shell; the transmission piece is arranged on the driving shaft of the motor and assembled with the adsorption component.

In this design, the motor can be directly with the subassembly assembly of adsorbing, the subassembly of adsorbing includes the pivot, and the pivot assembly of the drive shaft of motor and subassembly of adsorbing is connected through the shaft coupling for the motor can drive the pivot and rotate, does not set up drive part between motor and the subassembly of adsorbing, reduces spare part quantity of use, can simplify air treatment facility's inner structure, effectively reduces air treatment facility's volume.

The motor can also drive the adsorption component through the driving medium and rotate, the driving medium is assembled with the drive shaft of motor, the driving medium still is connected with the adsorption component, can drive the driving medium operation, the driving medium can drive the adsorption component and rotate, through setting up the driving medium between motor and adsorption component, can adjust the rotational speed of adsorption component, exemplarily, can select the driving medium of corresponding model according to the in-service use demand, thereby make the transmission ratio between motor, driving medium and the adsorption component satisfy the preset condition, can reduce the rotational speed of adsorption component, thereby satisfy the operating condition of adsorption component, the adsorption component rotational speed is in a certain limit, can improve humidification and dehumidification effect.

In one possible design, the drive assembly includes: the motor is arranged on the shell; the transmission piece is arranged on a driving shaft of the motor and is assembled with the adsorption component; the transmission piece includes: a speed reducer; or the transmission gear is arranged on the periphery of the adsorption component, and the transmission gear is meshed with the meshing teeth; or a conveyor belt assembly, assembled with the suction assembly.

In this design, the driving medium can be the reduction gear, and motor and reduction gear assemble mutually, and the pivot assembly of reduction gear and adsorption component, motor drive the reduction gear and rotate, and the reduction gear drives adsorption component and rotates, through setting up the reduction gear between motor and driving medium, can reduce adsorption component's rotational speed to satisfy adsorption component's operating condition, adsorption component rotational speed can improve humidification and dehumidification effect in a certain limit.

The transmission member may be a transmission gear, and the driving shaft of the driving motor is assembled with the transmission gear, so that the driving motor can drive the transmission gear to rotate. The periphery of adsorption component is provided with the meshing tooth, and drive gear and meshing tooth mesh to make drive gear can drive adsorption component and rotate, through selecting for use the drive gear of specific size, can reduce adsorption component's rotational speed, thereby satisfy adsorption component's operating condition, adsorption component rotational speed is in a certain limit, can improve humidification and dehumidification effect.

In order to set up the meshing tooth in the periphery of adsorption component, adsorption component includes adsorption cylinder and annular shell, and adsorption cylinder is located the annular shell, and machine-shaping has the meshing tooth on the annular shell, compares in adsorption cylinder, and the hardness of annular shell is higher, and the meshing tooth of the machine-shaping of being convenient for ensures that drive gear and adsorption component can cooperate steadily.

The driving piece can also be a conveyor belt assembly, and the driving motor is assembled with the conveyor belt assembly, so that the driving motor can drive the conveying to operate the assembly, and the conveyor belt assembly can drive the adsorption assembly to be assembled, so that the adsorption assembly is driven to rotate through the conveyor belt assembly. Specifically, the conveyer belt subassembly includes band pulley and conveyer belt, and driving motor and band pulley assemble mutually, and driving motor can drive the band pulley and rotate, and adsorption component's periphery is provided with annular groove, and the conveyer belt can block in annular groove for the conveyer belt can overlap to establish at band pulley and adsorption component, and the band pulley drives the conveyer belt and rotates, and the conveyer belt drives adsorption component and rotate. Through set up the conveyer belt subassembly between driving motor and adsorption component, can reduce the rotational speed of adsorption component to satisfy the operating condition of adsorption component, the adsorption component rotational speed can improve humidification and dehumidification effect in a certain limit.

In one possible design, the transmission member comprises: a transmission gear; the air treatment apparatus further includes: the annular baffle is arranged on the mounting plate and shields a part of the axial end face of the adsorption assembly.

In this design, it is transmission gear to inject the driving medium, because the periphery of adsorption component sets up the meshing tooth, in order that the adsorption component can rotate steadily, need set up the clearance between the inner wall of meshing tooth and first installation opening, the air current between first wind channel and the second wind channel flows each other through the clearance between the inner wall of meshing tooth and first installation opening easily, in order to avoid above-mentioned problem, set up the baffle and the axial terminal surface of transmission gear relatively, the baffle can shelter from the clearance between the inner wall of meshing tooth and first installation opening, effectively avoid the air current to circulate between first wind channel and second wind channel, be favorable to improving air treatment facility's humidification and dehumidification effect.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, or may be learned by practice of the invention.

Drawings

The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 shows one of the schematic structural diagrams of an air treatment device in an embodiment of the present invention;

FIG. 2 shows a second schematic configuration of an air treatment device in accordance with an embodiment of the present invention;

FIG. 3 shows a third schematic diagram of the air treatment apparatus in an embodiment of the invention;

FIG. 4 shows a fourth schematic structural view of an air treatment apparatus in an embodiment of the present invention;

FIG. 5 shows a schematic diagram of the structure of the suction assembly and the drive gear in an embodiment of the invention;

fig. 6 shows a schematic structural view of the suction assembly and the conveyor belt assembly in the embodiment of the present invention.

The correspondence between the reference numerals and the component names in fig. 1 to 6 is:

100 housing, 101 first tuyere, 102 second tuyere, 103 third tuyere, 104 fourth tuyere, 110 first air duct, 111 first sub-air duct, 120 second air duct, 121 third sub-air duct, 122 fourth sub-air duct, 130 first filter, 140 second filter, 150 air quality sensor, 210 mounting plate, 230 spacing member, 300 adsorption assembly, 400 driving assembly, 410 driving gear, 420 conveyor belt assembly, 500 partition plate assembly, 510 first partition plate, 511 second mounting port, 600 first air supply assembly, 700 second air supply assembly, 800 heating assembly.

Detailed Description

In order that the above-recited objects, features and advantages of the present invention will be more clearly understood, a more particular description of the invention will be rendered by reference to the appended drawings and appended detailed description. It should be noted that, in the case of no conflict, the embodiments of the present application and the 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 invention, however, the present invention may be practiced in other ways than those described herein, and therefore the scope of the present invention is not limited to the specific embodiments disclosed below.

An air treatment apparatus provided according to some embodiments of the present invention is described below with reference to fig. 1 to 6.

As shown in conjunction with fig. 1, 2 and 3, the present embodiment proposes an air treatment apparatus including: the air conditioner comprises a shell 100, a mounting plate 210, an adsorption assembly 300, a driving assembly 400 and a limiting piece 230, wherein a first air port 101 and a second air port 102 which are communicated with the outside of the shell 100, and a third air port 103 and a fourth air port 104 which are communicated with the inside of the shell, the first air port 101 is communicated with the third air port 103 to form a second air channel 120, the second air port 102 is communicated with the fourth air port 104 to form a first air channel 110, and the first air channel 110 and the second air channel 120 are not communicated with each other; the mounting plate 210 is arranged in the shell 100, the mounting plate 210 extends along the length direction of the shell 100, a first mounting through hole is formed in the mounting plate 210, the first air port 101 and the third air port 103 are respectively positioned at two sides of the mounting plate 210, and the second air port 102 and the fourth air port 104 are respectively positioned at two sides of the mounting plate 210; the limiting piece 230 is connected with the first mounting through hole and extends along a direction away from the mounting plate 210, and the limiting piece 230 defines an accommodating space; the adsorption assembly 300 is accommodated in the accommodating space and can rotate in the accommodating space, and the first region of the adsorption assembly 300 can reciprocally rotate between the first air duct 110 and the second air duct 120; the driving assembly 400 is disposed in the housing 100, and the driving assembly 400 can drive the adsorbing assembly 300 to rotate.

In the air treatment device provided in this embodiment, the first air duct 110 and the second air duct 120 are disposed in the casing 100, one of the first air duct 110 and the second air duct 120 may be used as an air intake channel, and the other of the first air duct 110 and the second air duct 120 may be used as an air exhaust channel. Outdoor air can enter the first air channel 110 through the second air port 102, then enter the room through the fourth air port 104, indoor air can enter the second air channel 120 through the third air port 103, and then be discharged to the outside through the first air port 101, so that indoor and outdoor air exchange is realized.

In summer, compared with the indoor environment, the outdoor environment has higher temperature and humidity, when the outdoor air enters the first air duct 110, the outdoor air encounters the adsorption component with relatively lower temperature and humidity, and the first area on the adsorption component 300 can adsorb the heat and moisture of the outdoor air, so that the temperature and humidity of the air entering the indoor environment are reduced. The adsorbed first region is in a high temperature and high humidity state, and rotates to the second air duct 120 as the adsorption assembly 300 rotates, and when the indoor gas is discharged outward, the indoor gas takes away heat and moisture at the first region, so that the heat and moisture are discharged outdoors. The wind entering the room is dry wind, and the discharged wind is wind with moisture, which is equivalent to the function of dehumidifying the indoor air.

Through setting up the adsorption module 300 between first wind channel 110 and second wind channel 120, can realize the function to indoor dehumidification, do not need to design dehumidification module isotructure, simplified the structure of air treatment facility, be favorable to reducing the processing cost of air treatment facility.

In addition, because the air treatment equipment with simple structure can reduce indoor humidity, the indoor air conditioner does not need to be independently started to dehumidify the indoor space, so that electric energy can be saved, and the running pressure of the air conditioner can be reduced.

The first air duct 110 and the second air duct 120 are two independent channels, so that the air in the first air duct 110 and the air in the second air duct 120 are not easy to mix with each other, thereby stably realizing the functions of humidification and dehumidification and improving the working stability of the air treatment equipment.

Since the first air port 101 and the third air port 103 are located at two sides of the mounting plate 210, the mounting plate 210 divides the second air duct 120 into two parts, so that the air flow entering the second air duct 120 can completely flow through the adsorption assembly 300. Similarly, the second air port 102 and the fourth air port 104 are respectively located at two sides of the mounting plate 210, and the mounting plate 210 divides the first air duct 110 into two parts, so that the air flow entering the first air duct 110 can flow through the adsorption assembly 300 completely, which is beneficial to improving the effects of humidification and dehumidification.

The adsorption component 300 can extend into the accommodating space of the limiting piece 230 from the first mounting through hole, and the setting of the limiting piece 230 can be favorable for reducing the gap between the adsorption component 300 and the mounting plate 210, so that the mixing of the gases in the first air duct 110 and the second air duct 120 is avoided, and the dehumidification effect of the air treatment device is further improved.

In this embodiment, the adsorption component 300 is made of a material with better water absorption, such as silica gel, molecular sieve, etc.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment, the mounting plate 210 separates the first duct 110 into a first sub-duct 111 and a second sub-duct, the first sub-duct 111 and the second sub-duct being stacked; the mounting plate 210 partitions the second duct 120 into a third sub-duct 121 and a fourth sub-duct 122, and the third sub-duct 121 and the fourth sub-duct 122 are stacked.

In this embodiment, since the first sub duct 111 and the second sub duct are distributed in the height direction, the extending direction of the first duct 110 is changed from the inlet of the first duct 110 to the outlet of the first duct 110. Similarly, the third sub-duct 121 and the fourth sub-duct 122 are distributed in the height direction, so that the extending direction of the second duct 120 is changed from the inlet of the second duct 120 to the outlet of the second duct 120. The air flow entering the first air duct 110 and the air flow entering the second air duct 120 need not only to flow transversely but also to flow vertically, so that the first air duct 110 and the second air duct 120 do not occupy more space in a single direction, the difference between the height and the width of the air treatment equipment is smaller, the air treatment equipment is further suitable for being installed at the installation position with smaller difference between the height and the width, and the applicability of the air treatment equipment is improved on the basis of simplifying the structure of the air treatment equipment.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment the air treatment device further comprises: the baffle assembly 500, the baffle assembly 500 is disposed in the housing 100, the baffle assembly 500 divides the upper space of the mounting plate 210 into the first sub-air duct 111 and the fourth sub-air duct 122, and the baffle assembly 500 divides the lower space of the mounting plate 210 into the second sub-air duct and the third sub-air duct 121.

In this embodiment, the baffle assembly 500 divides the upper space of the case 100 into the first sub-air duct 111 and the fourth sub-air duct 122, and the lower space of the case 100 into the second sub-air duct and the third sub-air duct 121, and the separation of the baffle assembly 500 prevents the gas in the first air duct 110 and the second air duct 120 from mixing, improving the humidification and dehumidification effects.

In one possible embodiment, septum assembly 500 includes: a first diaphragm 510 and a second diaphragm, the first diaphragm 510 being positioned above the mounting plate 210; the second spacer is positioned below the mounting plate 210.

In this embodiment, the first partition 510 divides the upper space of the housing 100 into the first sub-air duct 111 and the fourth sub-air duct 122, and the second partition divides the lower space of the housing 100 into the second sub-air duct and the third sub-air duct 121. By providing the first septum 510 and the second septum, the septum assembly 500 is of a split type structure, facilitating disassembly and assembly of the septum assembly 500.

The materials of the first and second partition plates 510 and the same as the installation of the housing 100 are described by way of example with the first partition plate 510, and the first partition plate 510 is detachably coupled to the housing 100, and after the air treatment apparatus is used for a long time, the first partition plate 510 can be removed to facilitate cleaning of the inside of the housing 100. Illustratively, the first diaphragm 510 may be secured to the housing 100 by a lock or a catch. The first partition 510 includes a heat insulation partition, or a first heat insulation layer is disposed on the first partition 510, and the heat insulation partition or the heat insulation layer can reduce heat exchange between the first air duct 110 and the second air duct 120, thereby having a better heat insulation effect.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment, the first diaphragm 510 and/or the second diaphragm includes a second mounting port 511, and the axis of the adsorption assembly 300 passes through the second mounting port 511.

In this embodiment, the axis of the adsorption assembly 300 can extend into the second mounting opening 511, when the adsorption assembly 300 rotates, the rotating shaft can rotate in the second mounting opening 511, the second mounting opening 511 can play a limiting role on the rotating shaft, so that the adsorption assembly 300 is prevented from deflecting when rotating, and the stability of the adsorption assembly 300 when rotating is improved. Illustratively, a bearing may be installed in the second installation opening 511, where the bearing is assembled with the axis of the adsorption assembly 300, so that the adsorption assembly 300 can stably rotate, friction between the adsorption assembly 300 and other components is avoided, noise generated when the adsorption assembly 300 rotates can be effectively avoided, and the use experience of a user on the air treatment device is improved.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment, the housing 100 comprises: the first air port 101 and the second air port 102 are arranged on the first side wall, and the first air port 101 and the second air port 102 are distributed along the diagonal direction of the first side wall; the third tuyere 103 and the fourth tuyere 104 are provided at the second side wall, and the third tuyere 103 and the fourth tuyere 104 are distributed along the diagonal direction of the second side wall.

In this embodiment, the first and second tuyeres 101 and 102 are distributed in a diagonal direction, and the third and fourth tuyeres 103 and 104 are distributed in a diagonal direction, so that the second and fourth tuyeres 102 and 104 are adapted to the inlet and outlet positions of the first air duct 110, and pipes for connecting the second and fourth tuyeres 102 and 104 are not required to be provided at the inlet and outlet of the first air duct 110, which is advantageous in simplifying the structure of the product. Likewise, the first and third tuyeres 101 and 103 are adapted to the inlet and outlet positions of the second air duct 120, and it is not necessary to provide pipes for connection with the first and third tuyeres 101 and 103 at the inlet and outlet of the second air duct 120.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment the air treatment device further comprises: the first air supply assembly 600 and the second air supply assembly 700, the first air supply assembly 600 is arranged in the second sub-air duct; the second air supply assembly 700 is disposed in the fourth sub-duct 122.

In this embodiment, the first air blowing assembly 600 is installed in the second sub duct, and the first air blowing assembly 600 can drive the air flow such that the first air blowing assembly 600 can suck the outdoor air into the room. The second air supply assembly 700 is installed in the fourth sub-duct 122, and the second air supply assembly 700 can drive the air flow such that the second air supply assembly 700 can pump indoor air to the outside. Providing the first and second air supply assemblies 600 and 700 increases the flow rate of the air, and can achieve better humidification and dehumidification effects in a shorter time.

In this embodiment, the first air supply assembly 600 and the second air supply assembly 700 are volute assemblies. In other embodiments, the first and second air supply assemblies 600, 700 may be fans.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment the air treatment device further comprises: the heating assembly 800, the heating assembly 800 is disposed in the second air duct 120.

In this embodiment, the heating assembly 800 is installed in the first air duct 110, and the heating assembly 800 is capable of heating the gas introduced into the first air duct 110. In winter, the heating assembly 800 can be started, and the gas entering the room is heated by the heating assembly 800 to be at a higher temperature, so that the function of heating the room is realized, and the use experience of a user on the air treatment equipment is improved. The temperature of the air inlet is increased through the heating component, the indoor air conditioner does not need to be started to heat the indoor, or the air conditioner can be controlled to operate at lower power, so that the energy consumption of the indoor air conditioner is effectively reduced. Moreover, since the heating assembly 800 can heat the gas entering the first air duct 110, the high-temperature gas can efficiently carry away the moisture on the adsorption assembly 300, thereby further improving the indoor humidifying effect.

In winter, when the temperature and humidity of indoor air are high and indoor air is discharged outwards, and when the temperature and humidity of the adsorption assembly 300 are relatively low, the first area on the adsorption assembly 300 can adsorb heat and moisture of the air. The heating assembly 800 heats the air in the first air duct 110, and when the first region rotates into the first air duct 110, the high temperature air in the first air duct 110 can evaporate the moisture on the adsorption assembly 300 and blow back into the room along with the inlet air to bring the moisture back into the room. Under the condition of ensuring that the moisture of indoor gas is basically not lost, the moisture of outdoor gas also enters the room, and the function of humidifying the room is realized. The gas is heated by the heating unit 800, and the gas entering the chamber is ensured to be a high-temperature and high-humidity gas.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment the air treatment device further comprises: the first filter 130 and/or the second filter 140, the first filter 130 is disposed in the first air duct 110, and the first filter 130 is located between the second air port 102 and the adsorption assembly 300; the second filter 140 is disposed in the second air duct 120, and the second filter 140 is disposed between the third tuyere 103 and the adsorption assembly 300.

In this embodiment, the first filter 130 is installed in the first air duct 110, and the air entering the first air duct 110 can pass through the first filter 130, and the first filter 130 can filter the air intake, so that the impurities in the air are prevented from entering the room, and the air quality is improved. Moreover, the filtering action of the first filtering member 130 can prevent impurities from contacting the adsorption assembly 300, prevent the adsorption assembly 300 from being blocked by the impurities, and ensure the functional stability of the adsorption assembly 300.

The first filter 130 contacts with the inner wall of the first air duct 110, so that the air entering the first air duct 110 needs to pass through the first filter 130, and the filtering effect on the air intake is improved.

The second filter 140 is installed in the second air duct 120, and the gas entering the second air duct 120 can pass through the second filter 140, and the second filter 140 can filter exhaust air, so that impurities in air are prevented from entering and contacting the adsorption assembly 300, the adsorption assembly 300 is prevented from being blocked by the impurities, and the functional stability of the adsorption assembly 300 is ensured.

The second filter 140 contacts with the inner wall of the second air duct 120, so that the air entering the second air duct 120 needs to pass through the second filter 140, and the filtering effect on the exhaust air is improved.

Illustratively, the first filter 130 and the second filter 140 may be filter screens.

The first filter 130 and the second filter 140 can be detached from the housing 100, so that the first filter 130 and the second filter 140 can be replaced, and the first filter 130 and the second filter 140 can have better filtering effect.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment, the heating assembly 800 is a heating grid; the first filter 130 is located between the second tuyere 102 and the heating net.

In this embodiment, the heating net comprises a plurality of heater strips for the heating net can heat the gas that passes through, improves the indoor gas temperature that gets into, and the area of contact of heating net and gas is great, can improve the heating rate of gas, thereby is favorable to rising indoor temperature fast. In order to enable the gas to pass through the heating net, a gap is required to be arranged on the heating net, if impurities are contacted with the heating net, the heating net can be blocked, and safety accidents can occur when the impurities are contacted with the high-temperature heating net. In order to avoid the above problem, in this embodiment, the first filter 130 is disposed between the second air port 102 and the heating net, the first filter 130 can block impurities in the air inlet, the air inlet is already filtered by the first filter 130 when contacting the heating net, so as to avoid contact between the impurities and the heating net, avoid blockage of the heating net caused by the impurities, and also avoid possible safety accidents caused by contact between the impurities and the high-temperature heating net, and improve the stability of the air treatment device during operation.

In other embodiments, the heating assembly 800 may also include a heating wire or rod.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment the air treatment device further comprises: the air quality sensor 150, the air quality sensor 150 is disposed in the second air duct 120, and the air quality sensor 150 is used for monitoring indoor air quality.

In this embodiment, the air quality sensor 150 is installed in the second air duct 120, and the air quality sensor 150 can detect the quality of the air entering the second air duct 120, and then can feed back the detection result to the user, for example, a display screen can be arranged on the air processing device, and the display screen displays the detection result of the air exhaust quality, so that the user can conveniently know the current indoor air quality. The air treatment equipment can also carry out data transmission with the electronic equipment of the user, so that the air treatment equipment can send data such as air quality to the user, and the user can know the data in time conveniently. When the air quality is poor, prompt information such as sound prompts or light prompts can be output, and a user can know the indoor air quality in time.

In one possible application, the air quality sensor 150 may be at least one of a formaldehyde sensor, a carbon dioxide sensor, and a PM2.5 sensor.

As shown in connection with fig. 1, 3 and 4, in one possible embodiment, the air quality sensor 150 is located between the third tuyere 103 and the suction assembly 300.

In this embodiment, the air quality sensor 150 is located between the third tuyere 103 and the adsorption assembly 300, so that detection of a part of impurities in the air after the adsorption assembly 300 adsorbs the impurities is avoided, and accuracy of the detection result can be effectively provided.

As shown in connection with fig. 2, 4 and 5, in one possible embodiment, the drive assembly 400 includes: a motor assembled with the adsorption assembly 300; or drive assembly 400 includes: a motor provided in the housing 100; and a driving member provided at the driving shaft of the motor, the driving member being assembled with the adsorption assembly 300.

In this embodiment, the motor may be directly assembled with the adsorption assembly 300, the adsorption assembly 300 includes a rotating shaft, and the driving shaft of the motor is assembled with the rotating shaft of the adsorption assembly 300, for example, through a coupling, so that the motor can drive the rotating shaft to rotate, no transmission component is arranged between the motor and the adsorption assembly 300, the number of used components is reduced, the internal structure of the air treatment device can be simplified, and the volume of the air treatment device is effectively reduced.

The motor can also drive the adsorption component 300 through the driving piece and rotate, the driving piece is assembled with the drive shaft of motor, the driving piece still is connected with the adsorption component 300, can drive the driving piece to rotate, the driving piece can drive the adsorption component 300 to rotate, through setting up the driving piece between motor and adsorption component 300, can adjust the rotational speed of adsorption component 300, exemplarily, can select the driving piece of corresponding model according to the in-service use demand, thereby make the transmission ratio between motor, driving piece and the adsorption component 300 satisfy the condition of predetermineeing, can reduce the rotational speed of adsorption component 300, thereby satisfy the operating condition of adsorption component 300, the adsorption component 300 rotational speed is in a certain range, can improve humidification and dehumidification effect.

As shown in connection with fig. 1, 2, 5 and 6, in one possible embodiment the transmission member comprises: a speed reducer; or the transmission member includes: the outer circumference of the adsorption assembly 300 is provided with meshing teeth, and the transmission gear 410 is meshed with the meshing teeth; or the transmission member includes: the conveyor belt assembly 420 is assembled with the suction assembly 300.

In this embodiment, the driving medium can be the reduction gear, and motor and reduction gear assemble mutually, and the pivot assembly of reduction gear and adsorption component 300, motor drive reduction gear rotate, and the reduction gear drives adsorption component 300 and rotates, through setting up the reduction gear between motor and driving medium, can reduce the rotational speed of adsorption component 300 to satisfy the operating condition of adsorption component 300, adsorption component 300 rotational speed is in a certain limit, can improve humidification and dehumidification effect.

The transmission member may be a transmission gear 410, and a driving shaft of the driving motor is assembled with the transmission gear 410, so that the driving motor can drive the transmission gear 410 to rotate. The periphery of the adsorption assembly 300 is provided with meshing teeth, and the transmission gear 410 is meshed with the meshing teeth, so that the transmission gear 410 can drive the adsorption assembly 300 to rotate, and the rotation speed of the adsorption assembly 300 can be reduced by selecting the transmission gear 410 with a specific size, thereby meeting the working condition of the adsorption assembly 300, and the rotation speed of the adsorption assembly 300 is within a certain range, so that the humidifying and dehumidifying effects can be improved.

In order to set up the meshing teeth in the periphery of the adsorption component 300, the adsorption component 300 comprises an adsorption roller and an annular shell, the adsorption roller is located in the annular shell, the annular shell is provided with the meshing teeth in a machining mode, compared with the adsorption roller, the annular shell is higher in hardness, the meshing teeth are convenient to machine and form, and the transmission gear 410 and the adsorption component 300 can be matched stably.

The transmission member may also be a conveyor belt assembly 420, and the driving motor is assembled with the conveyor belt assembly 420, so that the driving motor can drive the conveying member to be assembled to operate, and the conveyor belt assembly 420 can drive the adsorption member 300 to be assembled, so that the adsorption member 300 is driven to rotate by the conveyor belt assembly 420. Specifically, the conveyor belt assembly 420 includes a belt pulley and a conveyor belt, the driving motor and the belt pulley are assembled, the driving motor can drive the belt pulley to rotate, the outer periphery of the adsorption assembly 300 is provided with an annular groove, and the conveyor belt can be clamped in the annular groove, so that the conveyor belt can be sleeved on the belt pulley and the adsorption assembly 300, the belt pulley drives the conveyor belt to rotate, and the conveyor belt drives the adsorption assembly 300 to rotate. Through set up conveyer belt subassembly 420 between driving motor and adsorption component 300, can reduce the rotational speed of adsorption component 300 to satisfy the operating condition of adsorption component 300, adsorption component 300 rotational speed can improve humidification and dehumidification effect in a certain range.

In one possible embodiment, the transmission member comprises: a transmission gear 410; the air treatment apparatus further includes: an annular baffle plate is provided on the mounting plate 210, and the annular baffle plate shields a part of the axial end surface of the adsorption assembly 300.

In this embodiment, the transmission member is defined as the transmission gear 410, since the periphery of the adsorption assembly 300 is provided with the engagement teeth, in order for the adsorption assembly 300 to be able to rotate stably, a gap needs to be provided between the engagement teeth and the inner wall of the first installation opening, and the air flow between the first air duct 110 and the second air duct 120 easily flows through the gap between the engagement teeth and the inner wall of the first installation opening, and in order to avoid the above-mentioned problem, a baffle is provided opposite to the axial end face of the transmission gear 410, and the baffle can shield the gap between the engagement teeth and the inner wall of the first installation opening, effectively avoiding the circulation of the air flow between the first air duct 110 and the second air duct 120, which is beneficial to improving the humidification and dehumidification effects of the air treatment apparatus.

In the present invention, the term "plurality" means two or more, unless explicitly defined otherwise. The terms "mounted," "connected," "secured," and the like are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; "coupled" may be directly coupled or indirectly coupled through intermediaries. The specific meaning of the above terms in the present invention can be understood by those of ordinary skill in the art according to the specific circumstances.

In the description of the present specification, the terms "one embodiment," "some embodiments," "particular embodiments," and the like, mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the present invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

The above description is only of the preferred embodiments of the present invention and is not intended to limit the present invention, but various modifications and variations can be made to the present invention by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (12)

1. An air treatment apparatus, comprising:

the shell is provided with a first air port and a second air port which are communicated with the outside of the room, and a third air port and a fourth air port which are communicated with the inside of the room, wherein the first air port is communicated with the third air port to form a second air channel, and the second air port is communicated with the fourth air port to form a first air channel;

The mounting plate is arranged in the shell, the mounting plate extends along the length direction of the shell, a first mounting through hole is formed in the mounting plate, the first air port and the third air port are respectively positioned at two sides of the mounting plate, and the second air port and the fourth air port are respectively positioned at two sides of the mounting plate;

the limiting piece is connected with the first mounting through hole and extends along the direction deviating from the mounting plate, and the limiting piece defines an accommodating space;

the adsorption assembly is accommodated in the accommodating space and can rotate in the accommodating space, and the first area of the adsorption assembly can rotate back and forth between the first air duct and the second air duct;

the driving assembly is arranged in the shell and can drive the adsorption assembly to rotate;

the first air duct is divided into a first sub-air duct and a second sub-air duct by the mounting plate, and the first sub-air duct and the second sub-air duct are stacked;

the second air duct is divided into a third sub-air duct and a fourth sub-air duct by the mounting plate, and the third sub-air duct and the fourth sub-air duct are stacked;

the housing includes:

The first air port and the second air port are arranged on the first side wall and distributed along the diagonal direction of the first side wall;

the third air port and the fourth air port are arranged on the second side wall and distributed along the diagonal direction of the second side wall;

the drive assembly includes:

the motor is arranged on the shell;

the transmission part is arranged on the driving shaft of the motor and is assembled with the adsorption component;

the transmission member includes:

a speed reducer; or (b)

The periphery of the adsorption component is provided with meshing teeth, and the transmission gear is meshed with the meshing teeth; or (b)

And the conveyor belt assembly is assembled with the adsorption assembly.

2. The air treatment device of claim 1, further comprising:

the baffle assembly is arranged in the shell, the baffle assembly divides the upper space of the mounting plate into the first sub-air duct and the fourth sub-air duct, and the baffle assembly divides the lower space of the mounting plate into the second sub-air duct and the third sub-air duct.

3. An air treatment device according to claim 2, wherein the baffle assembly comprises:

the first baffle plate is positioned above the mounting plate;

and the second baffle is positioned below the mounting plate.

4. An air treatment apparatus according to claim 3, wherein,

the first partition plate and/or the second partition plate comprises a second installation through hole, and the axis of the adsorption component passes through the second installation through hole.

5. The air treatment device of claim 1, further comprising:

the first air supply assembly is arranged in the second sub-air duct;

and the second air supply assembly is arranged in the fourth sub-air duct.

6. An air treatment device according to any one of claims 1 to 4, further comprising:

and the heating component is arranged in the second air duct.

7. The air treatment device of claim 6, further comprising:

the first filter piece is arranged in the first air duct and is positioned between the second air port and the adsorption component; and/or

The second filter piece is arranged in the second air duct and is positioned between the third air port and the adsorption component.

8. An air treatment device according to claim 7, wherein,

the heating component is a heating net;

the first filter element is positioned between the second tuyere and the heating net.

9. The air treatment device of claim 7, further comprising:

and the air quality sensor is arranged in the second air duct and is used for monitoring indoor air quality.

10. An air treatment device according to claim 9, wherein,

the air quality sensor is located between the third tuyere and the adsorption assembly.

11. An air treatment device according to any one of claims 1 to 4, wherein the drive assembly comprises:

a motor assembled with the adsorption assembly; or (b)

The drive assembly includes:

the motor is arranged on the shell;

the transmission piece is arranged on the driving shaft of the motor and assembled with the adsorption component.

12. An air treatment device according to claim 1, wherein,

the transmission member includes: a transmission gear;

the air treatment apparatus further comprises: the annular baffle is arranged on the mounting plate and shields a part of the axial end face of the adsorption assembly.