CN215383654U - Cleaning tool with separating component - Google Patents

Abstract

The present application provides a cleaning tool having a separator assembly, the separator assembly comprising: the side wall of the dust cup is provided with a fluid inlet; a rotating separator which is cylindrical with an opening at one end and is provided with a plurality of separation holes on a side surface area, wherein the side surface area at least comprises an area facing the fluid inlet; and the driving motor is arranged inside the rotary separator and fixedly connected with the rotary separator, so that the rotary separator can be driven by the driving motor to rotate, and the particulate matters in the mixed fluid sucked through the fluid inlet are separated to the bottom of the dust cup. Utilize this burnisher, can separate particulate matter and air in the thing of inhaling high-efficiently, slow down burnisher's suction decay speed, and simple structure, small in size, convenient operation.

Description

Cleaning tool with separating component

Technical Field

The present invention relates to the field of household appliance technology, and more particularly, to a cleaning tool having a separating assembly.

Background

With the development of society and the increasing living standard of people, the vacuum cleaner is used in more and more families as a household cleaning appliance. In general, a fan is used to drive an impeller to rotate at a high speed, and an air negative pressure is generated in a sealed housing, so that dirt such as dust and garbage is sucked into the vacuum cleaner. Then the dirt is separated from the air in the interior, the dirt is kept at the designated position, and simultaneously the clean air is discharged out of the dust collector. Currently, vacuum cleaners commonly employ a dust bag or a rotating separator for dirt separation. Both separation methods have their disadvantages: the dust bag needs to be replaced frequently, so that the dust bag is not economical and environment-friendly; the rotating separator has a large volume and consumes a lot of pressure during operation. And the rotary separator has a complex structure and high design difficulty, the separation effect of the rotary separator is influenced by multiple structural parameters, and the requirement on the die is high. This results in poor cyclonic separation for most products and the dust which cannot be separated will gradually clog downstream filtration, such as HEPA. As the user uses, the suction force of the vacuum cleaner will be smaller and smaller, which seriously affects the user experience.

SUMMERY OF THE UTILITY MODEL

To the problem among the above-mentioned prior art, this application has proposed a neotype burnisher that has compact and efficient separation assembly, can separate particulate matter and air in the suction high-efficiently, slows down burnisher's suction decay rate, and simple structure, small in size, convenient operation.

The present application provides a cleaning tool having a separator assembly, the separator assembly comprising: the side wall of the dust cup is provided with a fluid inlet; a rotating separator which is cylindrical with an opening at one end and is provided with a plurality of separation holes on a side surface area, wherein the side surface area at least comprises an area facing the fluid inlet; and the driving motor is arranged inside the rotary separator and fixedly connected with the rotary separator, so that the rotary separator can be driven by the driving motor to rotate, and the particulate matters in the mixed fluid sucked through the fluid inlet are separated to the bottom of the dust cup.

In a possible embodiment, a plurality of said separation holes are also distributed on the bottom surface area of said rotating separator.

In one possible embodiment, a plurality of the separation holes are uniformly distributed in the side surface region and the bottom surface region.

In one possible embodiment, in the axial direction of the rotating separator, the side surface area includes a first sub-area facing the fluid inlet and a second sub-area away from the fluid inlet, and the shape and/or size of the separation holes in the first and second sub-areas are different.

In one possible embodiment, the shape of the separation holes on the side surface area is circular, oval, rectangular, diamond-shaped or polygonal.

In a possible embodiment, the separating holes in the side surface region are inclined polygonal separating holes, the axes of the polygonal separating holes being oriented at an angle to the axial direction of the rotating separator.

In one possible embodiment, at the bottom surface of the rotating separator, a plurality of separation holes are distributed in the form of at least one concentric ring at the edge thereof.

In one possible embodiment, the plurality of separation holes are evenly distributed in the form of a plurality of concentric rings over the bottom surface area of the rotating separator.

In one possible embodiment, the dirt cup includes a cup body and a bottom cover that is tightly snap fit to the bottom of the cup body.

In one possible embodiment, the separation assembly further comprises a primary filter fixedly disposed at a fluid outlet location of the dirt cup.

In one possible embodiment, the cleaning tool is a vacuum cleaner.

The application provides a burnisher with separable set compares in prior art, has following beneficial effect:

(1) by arranging the separation component, the particle (large particle sundries and small particle dust) and the air in the suction can be efficiently separated, the suction attenuation speed of the cleaning tool is reduced, and the cleaning tool is simple and compact in structure and convenient to operate;

(2) by configuring the shape of the separation holes in the side surface area of the rotating separator as inclined polygonal holes, a part of large particles can be cut and prevented from winding;

(3) the surface of the stator of the driving motor is provided with a plurality of surface bulges, so that residual particles entering the rotary separator through the separation holes can be further cut and knocked down and fall into the bottom of the dust cup through the separation holes in the bottom surface area, and the particles are prevented from blocking the primary filter;

(4) through setting up two-stage filter, can filter the air current after the separator separation to furthest, ensure that exhaust air is clean, realize clean effect.

The features mentioned above can be combined in various suitable ways or replaced by equivalent features as long as the object of the utility model is achieved.

Drawings

The utility model will be described in more detail hereinafter on the basis of embodiments and with reference to the accompanying drawings, in which:

fig. 1 shows a perspective view of a vacuum cleaner according to an embodiment of the present invention;

FIG. 2 shows a partial cross-sectional view of a vacuum cleaner according to an embodiment of the present invention;

FIG. 3 shows a cross-sectional view of a separating assembly of the cleaner according to an embodiment of the utility model;

FIG. 4 shows a perspective view of a dirt cup in accordance with an embodiment of the present invention;

FIGS. 5-10 show schematic structural views of a rotating separator according to an embodiment of the utility model;

fig. 11a and 11b show a perspective view and a front view of a driving motor according to an embodiment of the present invention;

fig. 12a and 12b show a perspective view and a front view of a driving motor according to another embodiment of the present invention;

FIG. 13 illustrates a cross-sectional view of a fan assembly according to an embodiment of the present invention;

FIG. 14 shows an exploded view of a handle according to an embodiment of the present invention;

FIG. 15 shows a perspective view of a dust suction port according to an embodiment of the present invention.

In the drawings, like parts are provided with like reference numerals. The figures are not drawn to scale.

List recording with attached chart:

100-a vacuum cleaner; 110-a handle; 111-a control section; 112-a grip portion; 113-battery compartment-114-battery; 120-a separation assembly; 121-dust cup; 1211-cup body; 1212-a bottom cover; 1213-cavity; 1214-a fluid inlet; 1215-a fluid outlet; 1216-a button; 122-a primary filter; 123-driving a motor; 1231-a stator; 1232-a rotating shaft; 1233-surface protrusions; 124-a rotating separator; 1241-side surface area; 1241A — first subregion; 1241B — second subregion; 1242-bottom surface area; 1243-separation orifice; 1244-mounting part of motor shaft; 125-dust suction port; 1251-joint; 1252-dust collector; 130-a fan assembly; 131-an upper cover body; 132-a secondary filter; 133-a fan; 134-motor compartment.

Detailed Description

The cleaning tool of the present invention will be further described with reference to the attached drawings by taking a vacuum cleaner as an example.

Fig. 1 is a schematic structural view of a vacuum cleaner 100 provided in the present application. As shown in FIG. 1, the vacuum cleaner 100 may include a handle 110, a separating assembly 120, and a fan assembly 130, wherein the fan assembly 130 is fixedly coupled to the separating assembly 120 and disposed above the latter, while the separating assembly 120 is fixedly coupled to the fan assembly 130 and the handle 110; when the vacuum cleaner 100 is in operation, an operator can hold the handle 110 to operate the vacuum cleaner 100, the fan assembly 130 is used for generating negative pressure inside the vacuum cleaner 100, and the separation assembly 120 is used for absorbing large-particle impurities and small-particle dust and separating the large-particle impurities and the small-particle dust from air, so that cleaning is completed.

Specifically, fig. 2 is a partial cross-sectional view of the vacuum cleaner 100 provided in the present invention, which shows the internal structure of the separation assembly 120 and the fan assembly 130. As shown, the separating assembly 120 includes a dirt cup 121, a primary filter 122, a drive motor 123, a rotating separator 124, and a dirt suction opening 125; the fan assembly 130 includes an upper cover 131, a secondary filter 132 and a fan 133; wherein the dirt cup 121 and upper cover 131 are fixedly engaged to form a substantially sealed body structure.

Alternatively, as shown in FIG. 2, a step structure is provided at the bottom edge of the upper cover 131, while a complementary step structure is provided at the top edge of the dirt cup 121, which when snapped together complementarily engage to form a sealed body structure.

Alternatively, the upper cover 131 and the dirt cup 121 may be screwed or the like to form a substantially sealed structure.

As shown in fig. 3, in the separating assembly 120, the dirt cup 121 is generally cylindrical and includes a cup 1211 and a bottom cap 1212, and the bottom cap 1212 can be fastened to the bottom of the cup 1211 to form a cavity 1213 for containing the separated large particles and small particles of dirt. A fluid inlet 1214 (fig. 4) is formed on the sidewall of the cup 1211, and the dust suction port 125 is fixedly connected to the sidewall of the cup 1211 and at least partially faces the fluid inlet 1214, so that the mixed fluid of the large particle impurities, the small particle dust and the air flow sucked from the dust suction port 124 can enter the interior of the dust cup 121 through the fluid inlet 1214, and then after separation, the small particle dust and the large particle impurities are retained in the cavity 1213, and the air is discharged out of the dust cup 121 through a fluid outlet 1215 formed in the top of the cup 1211.

Optionally, an engagement mechanism may be provided at the junction of the bottom cap 1212 and the cup 1211, which may include, for example, a spring catch (not shown) and a button 1216 (FIG. 4) protrudingly provided on a side wall of the cup 1211. in the engaged state, the spring catch can be compressed by pressing the button 1216 to remove the bottom cap 1212 from the cup 1211 to remove small particle dust and large particle debris and the like accumulated therein; similarly, the spring clip can be compressed by depressing the button 1216, and the bottom 1212 can be snapped onto the bottom of the cup 1211, releasing the button 1216 to securely snap the two together.

As shown in fig. 2 and 3, inside the bowl 1211, a primary filter 122 is fixedly disposed at the fluid outlet 1215 of the bowl 1211 to filter the separated air, a drive motor 123 is centrally and partially fixedly disposed on the primary filter 122 with its axis of rotation 1232 (fig. 11 a-12 b) oriented downward, and the rotational separator 124 and the axis of rotation 1232 of the drive motor 123 are fixedly connected such that the rotational separator 124 can be rotated about the rotational axis by the drive motor 123.

Specifically, a motor shaft mounting member 1244 (shown in fig. 8 and 9) is provided at a center position on the bottom inner wall of the rotating separator 124, and is used to fixedly connect the shaft 1232 of the driving motor 123. The shaft 1232 of the drive motor 123 may be fixedly coupled to the motor shaft mount 1244 by any of a number of known means, such as, for example, by threading, adhesive bonding, key bonding, or interference fit. The rotating speed of the driving motor 123 can be a constant value, and can also be adjusted according to the working gear of the vacuum cleaner 100; or the driving motor 123 is matched with a constant rotation speed or different rotation speeds according to the operating gear of the cleaner 100.

Preferably, the primary filter 122 partially protrudes from the fluid outlet 1215 of the cup 1212, so that when the dust vent body 1212 is engaged with the upper cover 131 of the fan assembly 130, the primary filter 122 can further seal the engagement interface (step surface) of the primary filter and the upper cover from the inside, and the sealing effect is enhanced, so that the separated air can completely enter the inside of the fan assembly 130 through the primary filter 122.

Here, the rotating separator 124 may have a cylindrical, conical, cylinder-like or cone-like shape with an upper end opened, and it is understood that, in order to achieve the effect of separating the particulate matter from the air, the rotating separator 124 should be opened with separation holes 1243 allowing the clean air to pass through at least in a side surface area 1241.

When the vacuum cleaner 100 of the present application is in operation, the driving motor 123 drives the rotating separator 124 to rotate at a certain speed in a certain direction according to specific use requirements, the mixed fluid containing the small particle dust, the large particle impurities and the air enters the interior of the dirt cup 121 through the fluid inlet 1214 under the negative pressure generated by the fan assembly 130 (described in detail below), and the mixed fluid enters tangentially along the cylindrical surface of the rotating separator 124 and flows along the cylindrical surface of the rotating separator 124 in the rotating direction thereof. Large particle debris in the combined air stream will be struck by the rotating separator 124 and thrown into the chamber 1213 at the bottom of the dirt cup 121. At the same time, the rotation of the rotating separator 124 can agitate the air at a high rate in the direction of fluid entry, creating a cyclone-like effect of the air in the dirt cup 121. The small particles of dirt in the combined air flow are subjected to the cyclonic action and are also separated into the chamber 1213 at the bottom of the dirt cup 121. The air and possibly also the participating particles in the mixed fluid flow at least from the separating openings 1243 distributed over the lateral surface area 1241 of the rotating separator 124 into the primary filter 122 for filtering.

In the vacuum cleaner 100 provided herein, the rotating separator 124 can take many different forms to accomplish the separation of the mixed fluid. The rotating separator 124 of the present application will be described in detail with reference to fig. 5 to 10, taking a cylindrical shape as an example.

Fig. 5 is a structural side view of an embodiment of the rotating separator 124, and the rotating separator 124 is provided with a plurality of uniformly distributed separation holes 1243 in a side surface area 1241, that is, the intervals between adjacent rows of separation holes are the same, the intervals between adjacent columns are also the same, and the sizes of the separation holes 1243 are the same. Here, the side surface area 1241 is at least a circumferential area of the side surface of the rotating separator 124 facing the fluid inlet 1214, so that the mixed air flow entering the dirt cup 121 from the fluid inlet 1214 can directly contact the plurality of separation holes 1213, enhancing the separation effect.

Alternatively, the separation holes 1243 may have various shapes, such as a circle, an ellipse, a rectangle, a diamond, or a polygon, etc. Preferably, as shown in fig. 5, the separation hole 1243 has a circular shape, which can effectively reduce the complexity of manufacturing and increase the efficiency of manufacturing.

In alternative embodiments, different rows or columns of the separation apertures 1243 may have different shapes in the side surface area 1241.

In another embodiment, as shown in FIG. 6, the separation orifice 1243 is a polygonal orifice that is at an angle φ from the rotational axis of the rotational separator 124, i.e., the axial centerline of the separation orifice is at an angle φ from the rotational axis of the rotational separator 124. The inclined polygonal holes distributed on the side surface of the rotating separator 124 make the dirt less likely to pass through and be separated. Meanwhile, as the rotary separator 124 rotates stably, the inclined polygonal holes can cut off hairs in dirt, so that the hairs are prevented from being wound; the air separated by the rotating separator 124 passes through the polygonal holes of its surface and enters the inside of the rotating separator 124 in an oblique direction defined by the polygonal holes.

In the structural side view of another embodiment of the rotating separator 124 depicted in fig. 7, the rotating separator 124 is provided with a plurality of non-uniformly distributed separation holes 1243 in a side surface area 1241. The "uneven distribution" here means that the plurality of separation holes 1243 are unevenly distributed in the axial direction of the rotating separator 124 (i.e., the up-down direction in fig. 7).

Specifically, in the axial direction of the rotational separator 124, the side surface area close to the fluid inlet and the side surface area far from the fluid inlet are distributed with the separation holes 1243 different in size and/or shape, and the interval between adjacent separation hole rows is not constant. In the preferred embodiment of fig. 7, the side surface area includes, in the axial direction, a first sub-area 1241A close to the fluid inlet and a second sub-area 1241B far from the fluid inlet, in which rows of the plurality of separation holes are uniformly distributed, respectively, and in order to ensure the separation effect, the distance between the adjacent rows of the separation holes of the first sub-area 1241A is smaller than the distance between the adjacent rows of the separation holes of the second sub-area 1241B, and the size of each separation hole of the first sub-area 1241A is smaller than the size of the separation hole of the second sub-area 1241B, so that more large particle impurities and small particle dusts cannot pass through the separation holes of the first sub-area 1241A to be separated into the cavity 1213 at the bottom of the dirt cup 121, while the separated air can be discharged out of the dirt cup through the separation holes of the second sub-area as soon as possible. In order to further maintain the balance of the average ventilation area per unit area over the entire side surface area 1241, the number of the separation holes 1243 of the second sub-area 1241B should be made smaller than the number of the separation holes 1243 of the first sub-area 1241A.

Likewise, the separation holes 1243 may have various shapes, such as a circle, an ellipse, a rectangle, a diamond, a regular polygon, or the like. Preferably, in fig. 6, the separation holes 1243 distributed in the first sub-area 1241A have a circular shape, and the separation holes 1243 distributed in the second sub-area 1241B have a square shape.

In the embodiment depicted in fig. 5, 6 or 7, the side surface area 1241 should comprise at least a side area close to the fluid inlet. Preferably, the side surface area 1241 is the entire side surface of the rotating separator 124, i.e. the separation holes 1243 are distributed over the entire side surface of the rotating separator 124.

It is understood that the separation holes 1243 may be provided only on the side surface area 1241 of the rotating separator 124, and the separation holes 1243 may not be provided on the bottom surface area 1242, as shown in fig. 8, on the premise of securing the separation effect. In an alternative embodiment shown in fig. 9 and 10, besides the plurality of separation holes 1243 distributed on the side surface area 1241, the rotating separator 124 may further include a plurality of separation holes 1243 on the bottom surface area 1242 to assist the separation work of the mixed air flow by the separation holes 1243 of the side surface area 1241.

In the embodiment depicted in fig. 9, a plurality of discrete holes 1243 are evenly distributed around the center of a circle on the bottom surface area 1242, with the motor shaft mount 1244 disposed at the center of the circle. Specifically, a plurality of concentric rings are formed around the center, each concentric ring includes a plurality of separation holes 1243 that are equidistantly distributed, and the radial intervals between adjacent concentric rings are the same.

Alternatively, the separation holes 1243 may have various shapes, such as a circle, an ellipse, a rectangle, a diamond, or a polygon, etc. Preferably, in fig. 9, the separation hole 1243 has a circular shape, which can effectively reduce the complexity of manufacturing and increase the processing efficiency.

In further alternative embodiments, the plurality of separation apertures 1243 may be non-uniformly distributed about the center of the circle on the bottom surface area 1242 with the plurality of separation apertures 1243. By "non-uniform distribution" is meant that the separation apertures 1243 in adjacent concentric rings are of different shapes and/or sizes and are not uniformly spaced. For example, the separation holes in the concentric rings may have different shapes and/or sizes in the radial direction, and the spacing between adjacent concentric rings becomes gradually larger in the outward direction from the center of the circle.

Preferably, in this embodiment, the bottom surface area 1242 is the entire bottom surface of the rotating separator 124, i.e. the separation holes 1243 are distributed over the entire bottom surface of the rotating separator 124.

In an alternative embodiment, the bottom surface area 1242 may be an edge area of the bottom surface of the rotating separator 124, i.e. the plurality of separation holes 1243 may be distributed in the form of at least one concentric ring at the edge area of the bottom surface. In the embodiment of fig. 10, only one circular ring in which a plurality of separation holes 1243 are arranged in a circumferential direction is distributed at an edge area of the bottom surface (bottom surface area 1242).

It will be appreciated that for optimal separation, the rotating separator 124 should be made of a material that is strong and lightweight, such as stainless steel, to withstand the large shear stresses it experiences when in contact with the mixed gas stream. Meanwhile, the rotating separator 124 should have smooth side and bottom surfaces so that large-sized foreign materials or small-sized dust in the mixed air flow cannot stick to the surface thereof or get stuck in the separation holes, while protecting the safety of the operator and preventing scratches when the rotating separator is mounted, dismounted, and cleaned.

To obtain a relatively high separation efficiency, the rotary separator of conventional cleaners usually comprises two or more separation stages. The first stage typically comprises a single relatively large cyclone chamber for removing coarse dirt, while the second stage comprises a plurality of relatively smaller cyclone chambers for removing fine dirt. As a result, the overall size of the rotating separator may be relatively large. Another difficulty with rotating separators is that they require high fluid velocities to achieve high separation efficiency. In addition, the fluid moving through the rotating separator typically follows a relatively long path as it flows from the inlet to the outlet. The long path and high velocity result in high aerodynamic losses, such that the pressure drop associated with the rotating separator can be high. With the rotating separator described herein, relatively high separation efficiency can be achieved in a more compact manner.

Fig. 11a and 11b are schematic structural views of the driving motor 123 of the separating assembly 120. As shown, the driving motor 123 includes a stator 1231, a rotor (inside the motor, not shown), and a rotating shaft 1232. In addition, a plurality of surface protrusions 1233 may be uniformly disposed on the surface of the stator 1231, and by these surface protrusions 1233, the residual particulate matters entering the inside of the rotating separator 124 can be further pulverized and then fall into the cavity 1213 at the bottom of the dirt cup 121 through the separating holes 1243 distributed on the bottom surface area 1242 of the rotating separator 124, so that the air flow entering the primary filter 122 is cleaner, and the primary filter 122 is prevented from being blocked.

In the particular embodiment shown in fig. 11a and 11b, the surface protrusions 1233 are configured as a sheet-like structure, which extends over at least part of the axial length of the stator surface, and whose projection on the stator surface is parallel to the axial direction of the drive motor 123. In addition, each of the surface protrusions 1233 should have the same size to ensure stability when the motor is rotated.

In another embodiment of the drive motor 123 depicted in fig. 12a and 12b, the surface protrusions 1233 are configured as a sheet-like structure, which extends over at least part of the axial length of the stator surface and whose projection onto the stator surface is at an angle θ to the axial direction of the drive motor 123. In the embodiment where the separation holes 1243 of the rotating separator 124 are inclined polygonal holes as shown in fig. 6, the inclined direction of the inclined polygonal holes is preferably opposite to the inclined direction of the inclined surface protrusions 1233 in this embodiment, so that it is more advantageous to crush and knock off residual particulate matters (e.g., dust) entering the inside of the rotating separator 124.

Fig. 13 shows a schematic structural diagram of the fan assembly 130 of the vacuum cleaner 100, which includes an upper cover 131, a secondary filter 132, and a fan 133, wherein the secondary filter 132 and the fan 133 are fixedly disposed in a motor compartment 134 of the upper cover 131. Specifically, the upper cover 131 is tightly connected to the dust cup 121, the secondary filter 132 is in a ring structure and the outer wall of the secondary filter is fixedly disposed on the inner wall surface of the top of the upper cover 131, and a plurality of air outlet holes (not shown) are disposed along the circumferential direction at the position of the side wall of the upper cover 131 contacting the outer wall of the secondary filter 132 or at the edge position of the top wall, so as to discharge the air after secondary filtration out of the vacuum cleaner 100; the fan 133 is interference-fitted with the secondary filter 132 in such a manner that an impeller (not shown) faces the separation assembly 120, and a bottom portion thereof is fixedly provided (e.g., screwed or snap-fitted) on an inner top wall of the upper cover 131.

During the operation of the vacuum cleaner 100, the fan 133 rotates to generate a negative pressure inside the vacuum cleaner 100, so that large-particle impurities and small-particle dust enter the vacuum cleaner through the dust suction port 125 and the fluid inlet 1214 to be separated, the separated particles are retained inside the dust cup 121, the separated air flow is filtered by the primary filter 122 and then discharged from the dust cup 121, enters the fan assembly 130, and is secondarily filtered by the secondary filter 132, and cleaner air is discharged from the vacuum cleaner 100 through the air outlet holes on the side wall and/or the top wall edge of the upper cover 131, so as to achieve a cleaning effect.

In a preferred embodiment, the primary filter 122 and the secondary filter 132 may be HEPA (HEPA) or filter cotton.

Fig. 14 is a schematic view of the structure of the handle 110 of the vacuum cleaner 100 of the present application. The handle 110 may include a control portion 111, a grip portion 112, and a battery compartment 113 for accommodating a battery 114, which are configured to be integrally formed to increase strength and reliability of the handle structure.

Specifically, the control section 111 may house therein a control component, such as an integrated circuit board or the like, which may communicate with the driving motor 123 and the blower fan 133 to control the driving motor 123 and the blower fan 133 to rotate, respectively; additionally, a touch-sensitive display screen (not shown) may be disposed on the control portion 111 for displaying information such as the rotation speed of the driving motor 123 and the fan 133, the dust suction mode, and the dust suction time, so that an operator can operate the dust collector 100 more conveniently.

As shown in fig. 1 and 2, the outer wall of the separating assembly 120, the outer wall of the blower assembly 130 and the handle 110 are fixedly connected, for example, by means of screw connection, key connection, adhesive bonding, etc.

Preferably, the diameter of the lower part of the outer wall of the dust cup 121 is larger than that of the upper part of the outer wall, and the upper part and the lower part are in smooth step transition; accordingly, the portion of the handle 110 connected to the dirt cup 121 is also correspondingly provided with a complementary transition step to increase the firmness of the connection.

In a preferred embodiment, the handle 110, the upper cap 131, and the cup 1212 of the present application should be made of a high strength and lightweight material, for example, the handle 110 and the upper cap 131 may be made of an Acrylonitrile Butadiene Styrene (ABS) material. In addition, in general, the cup 1212 may be constructed of a transparent material, such as a Polycarbonate (PC) material, in order to facilitate an operator to intuitively perceive the suction effect of the cleaner.

Fig. 15 is a schematic structural view of the dust suction port 125 provided in the present application. In this figure, the suction port 125 may include an engaging portion 1251 and a suction portion 1252 that are integrally formed, the engaging portion 1251 having an arcuate engaging surface with the same curvature as the dirt cup 121 to achieve a tight engagement. In addition, the joining manner of the two can be a connecting means known to those skilled in the art, such as screw connection, key connection, adhesive bonding, etc., and the utility model is not limited herein.

It should be understood that the dust suction port 125 can be directly used for sucking particles and dust, and can be connected to the dust suction portion 1252 by a snap connection or the like according to different dust suction requirements.

The application provides a dust catcher 100, through the inside separating assembly 120 that sets up, can effectively separate large granule filth and the tiny particle dust among the rubbish of inhaling, simple structure, it is small to can carry out high-efficient separation, the suction decay speed that slows down the dust catcher to air and rubbish.

In the description of the present invention, it is to be understood that the terms "upper", "lower", "bottom", "top", "front", "rear", "inner", "outer", "left", "right", and the like, indicate orientations or positional relationships based on the orientations or positional relationships shown in the drawings, are only for convenience in describing the present invention and simplifying the description, and do not indicate or imply that the device or element being referred to must have a particular orientation, be constructed in a particular orientation, and be operated, and thus, should not be construed as limiting the present invention.

Although the utility model herein has been described with reference to particular embodiments, it is to be understood that these embodiments are merely illustrative of the principles and applications of the present invention. It is therefore to be understood that numerous modifications may be made to the illustrative embodiments and that other arrangements may be devised without departing from the spirit and scope of the present invention as defined by the appended claims. It should be understood that features described in different dependent claims and herein may be combined in ways different from those described in the original claims. It is also to be understood that features described in connection with individual embodiments may be used in other described embodiments.

Claims (10)

1. A cleaning implement having a separator assembly comprising:

the side wall of the dust cup is provided with a fluid inlet;

a rotating separator which is cylindrical with an opening at one end and is provided with a plurality of separating holes on a side surface area, the side surface area at least comprises an area facing the fluid inlet, and the rotating separator is arranged in the dust cup;

the driving motor is arranged inside the rotary separator and fixedly connected with the rotary separator, so that the rotary separator can be driven by the driving motor to rotate, and the particulate matters in the mixed fluid sucked through the fluid inlet are separated to the bottom of the dust cup;

the primary filter is arranged at the position of the fluid outlet of the dust cup;

the fan assembly includes:

the upper cover body is provided with an air outlet, is arranged on the dust cup and is communicated with the interior of the dust cup;

the fan is arranged in the upper cover body;

the fan rotates in the upper cover body to generate negative pressure to provide suction force for the cleaning tool, under the action of the suction force, the mixed fluid is sucked into the rotary separator through the fluid inlet to be separated, and the separated mixed fluid is filtered by the primary filter and then is discharged through the air outlet.

2. The cleaning tool of claim 1, wherein a plurality of the separation apertures are also distributed on a bottom surface area of the rotating separator.

3. The cleaning implement of claim 2, wherein a plurality of the separation apertures are evenly distributed across the side surface region and the bottom surface region.

4. The cleaning tool of claim 1, wherein the side surface area comprises, in the axial direction of the rotational separator, a first sub-area facing the fluid inlet and a second sub-area remote from the fluid inlet, the separation holes in the first and second sub-areas being different in shape and/or size.

5. The cleaning implement of claim 1, wherein the shape of the separation aperture on the side surface area is circular, oval, rectangular, diamond, or polygonal.

6. The cleaning implement of claim 1, wherein the separation apertures on the side surface regions are slanted polygonal separation apertures oriented with their axes at an angle to the axial direction of the rotating separator.

7. The cleaning tool of claim 2, wherein a plurality of separation holes are distributed in at least one concentric ring at the edge of the bottom surface of the rotating separator.

8. The cleaning tool of claim 3, wherein a plurality of separation holes are evenly distributed in a plurality of concentric rings across a bottom surface area of the rotating separator.

9. The cleaning implement of claim 1, wherein the dirt cup includes a cup body and a bottom cover that tightly snaps over a bottom of the cup body.

10. The cleaning implement of any of claims 1-9, wherein the cleaning implement is a vacuum cleaner.

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