CN213713220U - Dust collector and tuber pipe machine - Google Patents

Abstract

The utility model relates to an air conditioning technology field, concretely relates to dust collector and tuber pipe machine. The utility model provides a dust removing device, which comprises a dust collecting structure and a dust collecting structure, wherein the dust collecting structure is used for storing the materials sucked by the dust collecting structure; an airflow channel is arranged in the dust collection structure, a baffle plate assembly is arranged in the airflow channel, and the dust collection structure is arranged below the baffle plate assembly correspondingly. Like this, through being provided with baffle subassembly, and the dust collection structure sets up in the below that baffle subassembly corresponds, can be so that the inspiratory dust of follow dust collecting structure under the blockking of baffle, the dust falls into the dust collection structure just, the collection and the clearance of the dust of being convenient for.

Description

Dust collector and tuber pipe machine

Technical Field

The utility model relates to an air conditioner technical field particularly, relates to a dust collector and tuber pipe machine.

Background

The air inlet of the air duct machine is usually provided with a filter screen for filtering particles such as dust and dirt. In order to avoid the situation that the filter screen is full of dust, the duct machine is usually provided with a dust collection structure at the air inlet, the dust collection structure is used for sucking the dust on the filter screen, and the dust collection structure is used for receiving the dust sucked by the dust collection structure.

The existing dust collection structure has the advantages that only a small part of dust sucked from the filter screen falls into the dust collection structure, and other most of dust is scattered onto other parts to influence the service performance of other parts.

SUMMERY OF THE UTILITY MODEL

The utility model provides a problem be that the dust that current dust collection structure brushed from the filter screen only has a small part of dust to fall into dust collection structure, other most dust scatter on other parts.

In order to solve the above problems, the utility model provides a dust removing device, which comprises a dust collecting structure and a dust collecting structure, wherein the dust collecting structure is used for storing the substances sucked by the dust collecting structure;

an airflow channel is arranged in the dust collection structure, a baffle plate assembly is arranged in the airflow channel, and the dust collection structure is arranged below the baffle plate assembly correspondingly.

Like this, through being provided with baffle subassembly, and the dust collection structure sets up in the below that baffle subassembly corresponds, can be so that the inspiratory dust of follow dust collecting structure under the blockking of baffle, the dust falls into the dust collection structure just, the collection and the clearance of the dust of being convenient for. In addition, dust can be prevented from scattering on other parts to influence the service performance of other parts.

Optionally, the baffle plate assembly includes a first baffle plate and a second baffle plate, and the first baffle plate is fixed to the upper wall of the airflow channel and extends towards the lower wall of the airflow channel; the second baffle is fixed with the lower wall of the airflow channel and extends towards the upper wall of the airflow channel.

Therefore, the first baffle and the second baffle are arranged in a staggered manner from top to bottom, so that on one hand, dust sucked from the airflow channel can easily fall into the dust collecting structure, and the dust can be collected and cleaned conveniently; on the other hand, the dust can be prevented from being discharged along with the air, and the influence on other parts can be prevented.

Optionally, the first baffle plate is spaced from the lower wall of the airflow channel by a distance greater than the second baffle plate is spaced from the upper wall of the airflow channel.

In this way, the dust collection efficiency is improved by arranging the opening of the first baffle plate to be larger than the opening of the second baffle plate, namely, the opening at the position close to the air inlet is large, and the opening at the position far away from the air inlet is small, so that dust is prevented from being brought out due to the fact that the opening is too large.

Optionally, the dust removing device further comprises a filter structure, and the filter structure is arranged on the second baffle.

Therefore, the second baffle plate is provided with the filter structure, and the filter structure can block dust and prevent the dust from being brought out, so that the motor is blocked.

Optionally, the dust removing device further comprises a suspension assembly, and the suspension assembly is arranged on one side of the filter structure far away from the first baffle.

Like this, through being in the filtration keeps away from one side of first baffle sets up the suspension assembly, after the windbreak of sunction inlet, the suspension assembly can carry out the swing back and forth because inertial effect to fall into the dust collection structure with the adhesion at the dust of filtration through knocking, clear up the dust more thoroughly.

Optionally, the length of the second baffle is greater than the distance between the first baffle and the lower wall of the airflow channel.

Like this, through setting up the length of second baffle be greater than first baffle with the interval of airflow channel's lower wall, can make the second baffle can block the dust through first baffle, under the blockking of second baffle, make the dust can fall into dust collecting structure more fast.

Optionally, the dust collecting structure includes a holding tank, a buckle is arranged on the holding tank, a buckle fixing hole is arranged on the dust collecting structure, and the buckle is embedded into the buckle fixing hole for fixing.

Like this, dust collection structure passes through buckle and buckle fixed orifices cooperation with dust collection structure and fixes, and the fixity is better, prevents that dust collection structure in the course of the work, and dust collection structure is because the steadiness is not good and drop for can't collect dirt. In addition, the buckle and the buckle fixing hole are matched in a mode, so that the fixing device is convenient to disassemble relative to other fixing modes.

Optionally, the width of the accommodating groove is the same as the minimum distance between the first baffle and the second baffle.

In this way, by setting the width of the accommodating groove to be the same as the minimum interval between the first baffle and the second baffle, the dust in the airflow passage falls just into the accommodating groove, not onto other parts.

Optionally, a sliding part is arranged on the accommodating groove, the dust collection structure comprises a supporting rib, and a sliding groove matched with the sliding part for sliding is formed in the supporting rib.

Like this, through setting up slider and spout complex structure for can remove between dust collecting structure and the dust collecting structure, the dust collecting structure of being convenient for can dismantle, be convenient for to the cleanness of dust in the dust collecting structure.

The utility model also provides a tuber pipe machine, include as above-mentioned arbitrary dust collector.

Like this, through being provided with baffle subassembly, and the dust collection structure sets up in the below that baffle subassembly corresponds, can be so that the inspiratory dust of follow dust collecting structure under the blockking of baffle, the dust falls into the dust collection structure just, the collection and the clearance of the dust of being convenient for. In addition, dust can be prevented from scattering on other parts to influence the service performance of other parts.

Drawings

Fig. 1 is a schematic structural view of a dust removing device according to an embodiment of the present invention;

fig. 2 is a bottom view of the dust removing device according to an embodiment of the present invention;

FIG. 3 is a schematic structural view of a dust removing apparatus according to another embodiment of the present invention;

FIG. 4 is a schematic structural view of a dust removing apparatus according to still another embodiment of the present invention;

FIG. 5 is an enlarged view of a portion of A in FIG. 4;

FIG. 6 is a schematic structural view of a dust removing apparatus according to another embodiment of the present invention;

fig. 7 is a schematic structural view of a support rib according to an embodiment of the present invention;

fig. 8 is a schematic structural view of the accommodating groove in an embodiment of the present invention.

Description of reference numerals:

1-dust collection structure; 11-a baffle plate assembly; 111-a first baffle; 112-a second baffle; 113-a filter structure; 114-a suspension assembly; 12-a snap fixing hole; 13-supporting ribs; 14-a chute; 2-a dust collecting structure; 21-accommodating grooves; 22-buckling; 23-sliding member.

Detailed Description

The ducted air conditioner is a hidden air conditioner and is installed in the ceiling. The air return port of the air duct machine is provided with a filter screen for filtering impurities such as dust in the air. After the ducted air conditioner is used for a long time, a large amount of dirt can be accumulated on the filter screen, the air outlet efficiency of the ducted air conditioner is influenced, and the air outlet health is also influenced.

In order to avoid the situation that the filter screen is full of dust, the duct machine is usually provided with a dust collection structure at the air inlet, the dust collection structure is used for sucking the dust on the filter screen, and the dust collection structure is used for receiving the dust sucked by the dust collection structure.

The existing dust collection structure has the advantages that only a small part of dust sucked from the filter screen falls into the dust collection structure, and other most of dust is scattered onto other parts to influence the service performance of other parts.

In order to make the aforementioned objects, features and advantages of the present invention more comprehensible, embodiments accompanied with figures are described in detail below.

In the drawings of the embodiments of the present invention, coordinate system XYZ is provided, wherein X, Y, Z represents different directions, and the directions or positional relationships indicated by the terms "upper", "lower", etc. are based on the orientations or positional relationships shown in the drawings, and are only for convenience of description and simplification of description, rather than indicating or implying that the device referred to must have a specific orientation, be constructed and operated in a specific orientation, and therefore should not be construed as limiting the present invention.

In the description of the present invention, it is to be noted that, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.

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

As shown in fig. 1, fig. 2 and fig. 3, the schematic structural diagram of the dust removing device in one embodiment of the present invention is different from the schematic structural diagram of the dust removing device in another embodiment of the present invention, and fig. 3 is a schematic structural diagram of the dust removing device in another embodiment of the present invention. The utility model discloses an embodiment provides a dust removing device, which comprises a dust collecting structure 1 and a dust collecting structure 2, wherein the dust collecting structure 2 is used for storing the materials sucked by the dust collecting structure 1;

an air flow channel is arranged in the dust collection structure 1, a baffle plate assembly 11 is arranged in the air flow channel, and the dust collection structure 2 is arranged below the baffle plate assembly 11 correspondingly.

The dust collection structure is used for sucking substances on a filter screen at an air return opening, and the dust collection structure is used for storing the substances sucked by the dust collection structure, wherein the substances can be dust and the like. Specifically, dust collecting structure 1 includes the body, be equipped with the opening in the bottom of body, dust collection structure 2 sets up the below of body opening, the air current passageway in dust collecting structure 1 through the opening with dust collection structure 2 communicates. The dust suction structure comprises an air suction opening, and air and dust are sucked from the air suction opening and enter the dust suction structure along the airflow channel. Since the baffle plate assembly 11 is arranged in the airflow channel, under the blocking of the baffle plate assembly 11, dust falls into the dust collecting structure through the opening, and air is discharged along the airflow channel.

It should be noted that, for the definition of direction, the dust collecting structure is disposed below the baffle assembly, i.e., in the opposite direction along the Z-axis as shown in fig. 1 and 2. In addition, arrows shown in fig. 3 indicate air flow passages.

Like this, through being provided with the baffle subassembly, and the dust collection structure sets up in the below that the baffle subassembly corresponds, can be so that the inspiratory dust of follow dust collecting structure under the blockking of baffle, the dust falls into the dust collection structure, the collection and the clearance of the dust of being convenient for, in addition, can prevent that the dust from scattering on other parts, influence the performance of other parts.

Optionally, the dust collecting structure 2 is detachably connected to the dust collecting structure 1, and the dust collecting structure 2 can be detached from the body of the dust collecting structure 1, so that the substances in the dust collecting structure can be cleaned conveniently.

As shown in fig. 3, optionally, the baffle plate assembly 11 includes a first baffle plate 111 and a second baffle plate 112, and the first baffle plate 111 is fixed to the upper wall of the airflow channel and extends toward the lower wall of the airflow channel; the second baffle 112 is fixed to the lower wall of the airflow passage and extends toward the upper wall of the airflow passage.

The first baffle 111 is a baffle disposed near the air inlet, and the second baffle 112 is a baffle disposed on a side far from the air inlet. Since the first baffle is fixed with the upper wall of the airflow channel and extends towards the lower wall of the airflow channel, namely, when the airflow entering from the air suction opening enters the position of the first baffle, the airflow is blocked by the first baffle at the high position, and therefore the airflow can only flow through the low position. And because the second baffle 112 is fixed with the lower wall of the air flow channel and extends towards the upper wall of the air flow channel, when the air flow at the lower part passes through the second baffle, the dust in the air just falls into the dust collecting structure due to the blocking of the second baffle, and other air is discharged along the air flow channel. In addition, by changing the flow direction of the airflow, the airflow generates turbulence; the turbulent air flow has much lower capacity of carrying objects than the direct air flow, so that part of the dust can fall down. Therefore, the position of the air flow is limited at a lower position, namely, the position is limited to be closer to the dust collecting structure, so that dust in the air can fall into the dust collecting structure conveniently, and the dust is prevented from floating in the air flow channel along with the air due to overhigh height, and the dust and the air are discharged together. It should be noted that the upper wall of the airflow passage refers to an inner side wall located above along the Z-axis in fig. 3, and the lower wall of the airflow passage refers to an inner side wall located below along the Z-axis in fig. 3.

Therefore, the first baffle and the second baffle are arranged in a staggered manner from top to bottom, so that on one hand, dust sucked from the airflow channel can easily fall into the dust collecting structure, and the dust can be collected and cleaned conveniently; on the other hand, the dust can be prevented from being discharged along with the air, and the influence on other parts can be prevented.

Optionally, the first baffle 111 is perpendicular to the upper wall of the airflow channel, the second baffle 112 is perpendicular to the lower wall of the airflow channel, and the first baffle 111 and the second baffle 112 are arranged in parallel. Of course, the first baffle 111 and the second baffle 112 may also be disposed non-parallel, for example, the first baffle 111 is disposed obliquely to the upper wall of the airflow channel, and the second baffle is perpendicular to the upper wall of the airflow channel. In this way, since the first baffle is arranged at a position close to the suction inlet, the first baffle is inclined to facilitate air guiding, so that the air flow rapidly flows to a corresponding position of the dust collecting structure, and the second baffle is arranged vertically instead of being inclined to prevent dust from being brought out due to overlarge wind force.

Optionally, the distance between the first baffle 111 and the lower wall of the airflow channel is larger than the distance between the second baffle 112 and the upper wall of the airflow channel.

The distance between the first baffle and the lower wall of the airflow channel is equivalent to an air inlet entering the dust collecting structure, the distance between the second baffle and the upper wall of the airflow channel is equivalent to an air outlet leaving the dust collecting structure, and the air inlet is larger than the air outlet. The air inlet is arranged to be large, so that dust can enter along with air quickly, and the dust collection efficiency is improved; the air outlet is smaller, so that the dust is prevented from being discharged along with the air.

In this way, the dust collection efficiency is improved by arranging the opening of the first baffle plate to be larger than the opening of the second baffle plate, namely, the opening at the position close to the air inlet is large, and the opening at the position far away from the air inlet is small, so that dust is prevented from being brought out due to the fact that the opening is too large.

Fig. 4 and 5 are schematic structural views of a dust removing device according to another embodiment of the present invention. Optionally, the dust removing device further comprises a filtering structure 113, and the filtering structure 113 is disposed on the second baffle 112.

The filter structure 113 is disposed at a gap between the second baffle 112 and the upper wall of the airflow channel, and by disposing the filter structure, which may be a filter screen, for example, the filter structure can prevent dust from being brought out through the gap to affect normal operation of other components. Wherein the filter structure is arranged on the second baffle, i.e. in the positive direction of the Z-axis in fig. 4.

Therefore, the second baffle plate is provided with the filter structure, and the filter structure can block dust and prevent the dust from being brought out, so that the motor is blocked. In addition, by arranging the filtering structure, the required precision of the size of the gap between the second baffle and the upper wall of the airflow channel is reduced, the fault tolerance rate is relatively high for the size of the gap, and even if the size of the gap is a little larger or a little smaller, the gap cannot generate too large influence.

Optionally, the filtering structure 113 is exemplified by a filtering net, the filtering net may be disposed between the first baffle 111 and the second baffle 112, corresponding to the positive direction of the X axis in fig. 4, the filtering net is perpendicular to both the first baffle 111 and the second baffle, one end of the filtering net is fixed on the first baffle, and the other end of the filtering net is fixed on the second baffle. Like this, with the filter screen setting between first baffle and second baffle, can block the dust on the one hand, prevent that the dust from being taken out the jam motor, on the other hand, to the dust accumulation on the filter screen when more, can fall into the dust collection structure because the effect of gravity is automatic.

Optionally, the dust removing device further comprises a suspension assembly 114, and the suspension assembly 114 is disposed on a side of the filter structure 113 away from the first baffle 111.

Wherein the suspension assembly 114 comprises a suspension line and a suspension member, the suspension line is connected with the suspension member, and the suspension member is made of a hard material with low density, such as a steel ball or other suspension members. The suspension assembly is arranged on one side far away from the first baffle 111, when the dust collection structure works, the suspension object swings along with the wind direction and contacts with the second baffle or the filter structure, and when the dust collection structure stops working, the suspension assembly needs to be restored to the original state when the suspension structure is hung, and due to the fact that the suspension object swings back and forth under the action of inertia, the filter screen is repeatedly knocked, so that dust adhered to the surface of the filter structure can be knocked, the dust falls into the dust collection structure, and the dust is more cleanly and comprehensively treated.

Thus, by providing the suspension assembly between the filter structure and the first baffle, when the wind at the suction port blows, the suspension assembly is blown up to the outside, i.e., the opposite direction along the X-axis in fig. 4; after the windage of sunction inlet, hang the subassembly and can carry out the back and forth swing owing to inertial effect to fall into the dust collection structure with the dust of adhesion at filtration and baffle through the striking, more thorough with the clearance of dust.

Optionally, the length of the second baffle 112 is greater than the distance between the first baffle 111 and the lower wall of the airflow channel.

When the dust enters the air flow channel along with the air, the first baffle and the lower wall of the air flow channel are spaced, the dust flows to the position of the second baffle through the gap, and the second baffle can block the dust passing through the first baffle and can fall into the dust collecting structure because the length of the second baffle is greater than the spacing between the first baffle and the lower wall of the air flow channel.

Like this, through setting up the length of second baffle be greater than first baffle with the interval of airflow channel's lower wall, can make the second baffle can block the dust through first baffle, under the blockking of second baffle, make the dust can fall into dust collecting structure more fast.

Alternatively, the length of the first baffle 111 is greater than the length of the second baffle 112, so that the dust can be more completely blocked, so that the dust falls into the dust collecting structure as much as possible. The length direction of the first baffle 111 and the second baffle 112 is along the positive direction of the Z axis in fig. 4.

Fig. 6 is a schematic structural diagram of a dust removing device according to another embodiment of the present invention. Optionally, the dust collecting structure 2 includes a receiving groove 21, a buckle 22 is disposed on the receiving groove 21, a buckle fixing hole 12 is disposed on the dust collecting structure 1, and the buckle 22 is embedded in the buckle fixing hole 12 for fixing.

Wherein, the accommodating groove 21 is arranged below the body of the dust suction structure. Specifically, the bottom of body is equipped with the opening, holding tank 21 sets up body open-ended below, the air current passageway in dust collecting structure 1 through the opening with holding tank 21 communicates. The buckle 22 sets up a short side of holding tank 21, dust absorption structure body with buckle fixed orifices 12 has been seted up to one side that short side of holding tank corresponds, the buckle 22 embedding cooperation is fixed in the buckle is fixed detaining 12.

Like this, dust collection structure passes through buckle and buckle fixed orifices cooperation with dust collection structure and fixes, and the fixity is better, prevents that dust collection structure in the course of the work, and dust collection structure is because the steadiness is not good and drop for can't collect dirt. In addition, the buckle and the buckle fixing hole are matched in a mode, so that the fixing device is convenient to disassemble relative to other fixing modes. Of course, the dust collecting structure and the dust collecting structure may also be fixed by other fixing methods, such as a fixing method by a hook and loop fastener.

Alternatively, the width of the receiving groove 21 is the same as the minimum interval between the first shutter 111 and the second shutter 112.

When the first baffle 111 and the second baffle 112 are arranged in parallel, the distances between the parts of the first baffle 111 and the second baffle 112 are the same, and the minimum distance between the parts is a constant value. When the first barrier 111 and the second barrier 112 are not arranged in parallel, the distances between the first barrier 111 and the second barrier 112 of each portion are not equal, there is a minimum distance therebetween, and the width of the accommodating groove 21 is arranged to be the same as the minimum distance between the first barrier 111 and the second barrier 112.

In this way, by setting the width of the accommodating groove to be the same as the minimum interval between the first baffle and the second baffle, the dust in the airflow passage falls just into the accommodating groove, not onto other parts. Of course, the width of the accommodating groove may be larger than the minimum distance between the first baffle and the second baffle, so that the dust in the airflow channel can fall into the accommodating groove.

As shown in fig. 7 and 8, fig. 7 is a schematic structural view of the support rib in an embodiment of the present invention, and fig. 8 is a schematic structural view of the accommodating groove in an embodiment of the present invention. Optionally, a sliding part 23 is disposed on the accommodating groove 21, the dust collection structure 1 includes a supporting rib 13, and a sliding groove 14 that is matched with the sliding part 23 to slide is formed on the supporting rib 13.

The supporting rib 13 is arranged at the bottom of the body of the dust collection structure 1, and the sliding groove 14 is formed in the supporting rib 13, so that the sliding part 23 on the accommodating groove 21 can move relative to the accommodating groove through the sliding groove 14. When the holding tank 21 needs to be detached, the holding tank moves outwards along the sliding groove until the holding tank is separated from the rail of the sliding groove, so that the holding tank and the dust collection structure body can be detached.

Like this, through setting up slider and spout complex structure for can remove between dust collecting structure and the dust collecting structure, the holding tank can be dismantled, is convenient for clear up the dust in the holding tank.

Alternatively, as shown in fig. 6 and 7, the long side of the receiving groove corresponds to the direction of the X axis in the figure, and for the matching of the sliding groove 14 and the sliding piece 23, specifically, two sliding pieces 23 are arranged on the two long sides of the receiving groove 21, two sliding pieces 23 are arranged on the inner side of the receiving groove, two sliding pieces 23 are arranged near the opposite ends of the buckle 22, and both sliding pieces 23 are cylindrical. Correspondingly, there are two support ribs 13, and sliding grooves 14 matched with the sliding parts are respectively formed on the support ribs 13. The sliding piece and the sliding groove are respectively arranged on the two side edges, so that the sliding piece can keep balance when sliding. Of course, the number of the sliding members may be two or only one. Similarly, the sliding part may be disposed outside instead of inside, and when the sliding part is disposed outside, the supporting rib is correspondingly provided with a sliding groove, so that the sliding part and the sliding groove can slide in a matching manner.

Optionally, when the supporting rib is provided with the sliding groove, the height of the sliding groove can be set to be smaller than that of the supporting rib below the sliding groove on the premise that the width of the supporting rib is kept to be constant, so that the strength of the supporting rib is ensured.

Another embodiment of the utility model provides a ducted air conditioner, include as above-mentioned arbitrary dust collector.

Like this, through being provided with baffle subassembly, and the dust collection structure sets up in the below that baffle subassembly corresponds, can be so that the inspiratory dust of follow dust collecting structure under the blockking of baffle, the dust falls into the dust collection structure just, the collection and the clearance of the dust of being convenient for. In addition, dust can be prevented from scattering on other parts to influence the service performance of other parts.

Although the present invention is disclosed above, the present invention is not limited thereto. Various changes and modifications may be effected therein by one of ordinary skill in the pertinent art without departing from the scope or spirit of the present invention, and the scope of the present invention is defined by the appended claims.

Claims (10)

1. A dust removing device characterized by comprising: the dust collection structure comprises a dust collection structure (1) and a dust collection structure (2), wherein the dust collection structure (2) is used for storing substances sucked by the dust collection structure (1);

an air flow channel is arranged in the dust collection structure (1), a baffle plate component (11) is arranged in the air flow channel, and the dust collection structure (2) is arranged below the baffle plate component (11) correspondingly.

2. A dusting apparatus according to claim 1, characterized in that said baffle plate assembly (11) comprises a first baffle plate (111) and a second baffle plate (112), said first baffle plate (111) being fixed with the upper wall of said air flow channel and extending towards the lower wall of said air flow channel; the second baffle (112) is fixed with the lower wall of the airflow channel and extends towards the upper wall of the airflow channel.

3. A dusting device according to claim 2, characterized in that the distance between said first baffle (111) and the lower wall of said air flow channel is larger than the distance between said second baffle (112) and the upper wall of said air flow channel.

4. A dust extraction apparatus according to claim 2 or 3, further comprising a filter structure (113), the filter structure (113) being arranged on the second baffle (112).

5. A dusting device according to claim 4, characterized in that it further comprises a suspension assembly (114), said suspension assembly (114) being arranged at a side of said filtering structure (113) remote from said first baffle (111).

6. A dusting apparatus according to claim 2 or 3, characterized in that the length of said second baffle (112) is larger than the distance of said first baffle (111) from the lower wall of said air flow channel.

7. A dust collecting device according to claim 2 or 3, characterized in that the dust collecting structure (2) comprises a receiving groove (21), a buckle (22) is arranged on the receiving groove (21), a buckle fixing hole (12) is arranged on the dust collecting structure (1), and the buckle (22) is embedded in the buckle fixing hole (12) for fixing.

8. A dusting device according to claim 7, characterized in that the width of said containing groove (21) is the same as the minimum distance between said first baffle (111) and said second baffle (112).

9. A dust removing device according to claim 7, wherein a sliding part (23) is arranged on the accommodating groove (21), the dust collecting structure (1) comprises a supporting rib (13), and a sliding groove (14) which is matched with the sliding part (23) to slide is formed on the supporting rib (13).

10. A ducted air conditioner comprising a dust removal device as claimed in any one of claims 1 to 9.

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