RU2281680C1 - Suction opening unit and vacuum cleaner equipped with such a unit - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: suction opening unit comprises upper and lower housings connected with one another. Lower housing has central part arranged between first and second sides, plurality of suction holes provided though lower housing, and plurality of suction channels defined between upper and lower housings for directing air drawn from plurality of suction holes. The given unit is used as part of vacuum cleaner.

EFFECT: increased efficiency in cleaning of surfaces having vast area.

20 cl, 10 dwg

Description

The present invention relates generally to a vacuum cleaner and, in particular, to a suction port assembly of a vacuum cleaner for drawing garbage from a surface to be cleaned.

Vacuum cleaners draw in debris from the surface to be cleaned using the suction force created by the vacuum source installed in its main body. A vacuum cleaner typically comprises a vacuum cleaner housing in which a vacuum motor is installed; a suction port assembly facing the surface to be cleaned to draw dust from the surface, and an extension channel guiding the trash drawn into the suction port assembly to the vacuum cleaner body. The extension channel often comprises an extension pipe connector movably connected to the suction port assembly, an extension pipe connected to the extension pipe connector, and a suction hose between the vacuum cleaner body and the extension pipe.

So, from patent EP No. 0576174, A 47 L 9/02, 1993, a vacuum cleaner is known comprising a vacuum cleaner body, a vacuum source, an extension vacuum channel having first and second ends, the first end of the channel being connected to the vacuum cleaner body in such a way that air can pass through an extension channel to the rarefaction source, and a suction port assembly comprising upper and lower housings connected to each other, said upper housing having a central part between the first and second side sides, a plurality of suction openings, o brezovany in the lower casing.

In addition, from the same patent a suction port assembly is also known, comprising upper and lower casings connected to each other, said upper casing having a central part between the first and second side sides, a plurality of suction holes formed in the lower casing.

Attached to the present invention Figa and 1B show in perspective schematically the lower and upper sides, respectively, of the node of the suction hole. 1A and 1B, the suction hole assembly comprises an upper casing 10 and a lower casing 11. A suction hole 14 for drawing debris from the work surface is made in the lower casing 11. The lower casing 11 also has a dust transfer duct 12 formed on its opposite sides, to which the dust located on its opposite lateral sides S is drawn into the vacuum source through the suction hole 14.

The suction port assembly in FIGS. 1A and 1B has a single suction channel for transmitting a vacuum, with which dust can be drawn into the vacuum cleaner. Therefore, the vacuum is the strongest in the center C of the suction port 14, but decreases in the direction from the center C. Therefore, the cleaning efficiency in the center C of the suction port 14 is good, but deteriorates towards the sides S of the suction port assembly. Accordingly, the suction port assembly is not effective in processing a large surface area. In addition, since the top of the suction port assembly is typically made of opaque material, it is not possible to determine if debris is stuck in the suction port assembly. Therefore, it is necessary to check the entire suction channel of the vacuum cleaner in order to find the place where the suction channel is clogged. The suction port assembly, which provides a more uniform vacuum and which allows visual inspection of the suction channels, will be an improvement of the prior art.

The technical task of the present invention is to solve at least these problems and / or disadvantages and to create at least the advantages mentioned above. Accordingly, the technical result of the present invention is to create an improved site suction holes, allowing you to effectively clean the surface of a large area, and a vacuum cleaner equipped with such a site.

Another technical result of the present invention is to provide an improved suction port assembly to visually inspect the channel outside the suction port assembly and to create a vacuum cleaner equipped with this suction port assembly.

To achieve the technical results, a suction port assembly has been created comprising upper and lower casings connected to each other, said lower casing having a central part between the first and second side sides, a plurality of suction holes formed in the lower casing, and a plurality of suction channels, formed between the upper and lower casings, for directing air drawn in from the plurality of suction openings. Due to this solution, it is possible to process a large area more efficiently.

Preferably, the plurality of suction openings includes a first suction opening and a second suction opening formed in the lower casing and spaced apart from each other, the plurality of channels including a first suction channel and a second suction channel that communicate with the first suction hole and the second suction hole , respectively.

Preferably, a first suction opening is formed between the central part and one side of the lower casing; and a second suction port is formed between the central part and the other side of the lower casing.

Preferably, the suction opening assembly further comprises side channels extending from the lower surface of the lower casing and opening through the sides of the lower casing operatively connected to the first and second suction openings, a central dust-transporting channel extending from the lower surface of the lower casing so that the first and second the suction openings are fluidly coupled to one another and one or more dust conveying channels extending from the lower surface of the lower of the casing and extending through the front of the lower housing so that the front end of the lower housing is connected in fluid communication with the first and second suction holes.

Preferably, the upper casing comprises a suction channel cover forming the top of the first and second suction channels and attached to the lower casing, and an upper cover located above the channel cover and connected to the lower casing.

Preferably, the suction channel cover has an arcuate cross-section from a direction perpendicular to the direction of flow of the drawn in air.

Preferably, the suction port assembly further comprises a first connecting part formed along the edge of the channel cover and a second connecting part formed in the lower housing and corresponding to the first connecting part, as a result of which it is adapted to engage with the first connecting part, while maintaining air tightness.

Preferably, the first and second connecting parts are a pair of parts having corresponding ledges.

Preferably, the first and second connecting parts consist of a connecting rib and a connecting recess corresponding to the connecting rib.

Preferably, the suction port assembly further comprises a compression rib formed on the lower surface of the upper cover and a guide rib formed on the upper surface of the channel cover and having a shape substantially corresponding to the compression rib, whereby the compression rib can be mounted on the guide rib.

Preferably, the channel cover is made of a transparent material.

Preferably, the suction port assembly further comprises a flow guiding rib on the first and second channels, configured to direct the drawn air to the rarefaction source.

Preferably, the flow guiding rib comprises a first part of the flow guiding rib formed on the first channel and a second part of the flow guiding rib formed on the second channel such that the second part of the flow guiding rib is connected to one end of the first flow guiding rib.

Preferably, the first and second parts of the flow guiding rib have a guiding surface of a predetermined curvature.

To achieve these technical results, a vacuum cleaner is created comprising a vacuum cleaner body having a vacuum source, an extension vacuum channel having first and second ends, the first end of the channel being connected to the vacuum cleaner body so that air can pass through the extension channel to the vacuum source, and a suction hole assembly connected to the second end of the extension rarefaction channel, wherein the suction hole assembly comprises upper and lower housings, a plurality of suction holes, OF DATA in the lower case, and a plurality of suction channels formed in the upper and lower housings to direct air drawn in from these suction holes.

Preferably, the plurality of suction openings of the suction port assembly consists of a first suction port and a second suction port formed in the lower casing of the suction port assembly and spaced apart from each other, the plurality of suction channels including a first channel and a second channel that communicate with the first suction port the hole and the second suction hole, respectively.

Preferably, the upper casing of the suction opening assembly comprises a channel cover forming the top of the first and second suction channels and connected to the lower casing of the suction opening assembly and an upper cover located above the channel cover and connected to the lower casing of the suction opening assembly.

Preferably, in the vacuum cleaner, the suction opening assembly further comprises a first connecting part formed along the edge of the channel cover and a second connecting part formed in the lower casing and corresponding to the first connecting part, as a result of which it can engage with the first connecting part.

Preferably, in the vacuum cleaner, the suction port assembly further comprises a compression rib formed on the lower surface of the upper cover and a guide rib formed on the upper surface of the channel cover and whose shape corresponds to the shape of the compression rib.

Preferably, in the vacuum cleaner, the suction port assembly further comprises a flow guiding rib formed on the first and second channels and configured to direct the drawn air to the vacuum source.

Mentioned and other objectives, features and advantages of the present invention are explained in the following detailed description with reference to the accompanying drawings, in which:

1A and 1B are perspective views schematically showing the upper and lower sides of a conventional suction port assembly;

Figure 2 is a perspective view schematically showing a vacuum cleaner according to an embodiment of the present invention;

FIG. 3 is an exploded perspective view of a suction port assembly according to an embodiment of the present invention; FIG.

4 is a perspective view schematically showing the lower side of the lower casing according to an embodiment of the present invention;

FIG. 5 is a perspective view schematically showing a top cover according to an embodiment of the present invention; FIG.

6 is a cross section of the channel cover, made along the line VI-VI in figure 3;

Fig.7 is a cross section of the main part, made along the line VII-VII in figure 2;

Fig. 8 is a perspective view schematically showing a lower side of a channel according to an embodiment of the present invention;

Fig. 9 is a partial cutaway and a perspective view schematically showing a swirl of a stream of air drawn into a suction port assembly in which there is no flow guide rib;

FIG. 10 is a partial cutaway and perspective view schematically showing a swirl of a flow of air drawn into a suction port assembly having a flow guiding rib according to an embodiment of the present invention; and

11 is a cross section showing a connecting relationship between a channel cover, an upper cover and a lower casing according to another embodiment of the present invention.

The following is a detailed description of some embodiments of the present invention with reference to the accompanying drawings.

Figure 2 shows a perspective image of a vacuum cleaner according to one embodiment of the present invention. The vacuum cleaner comprises a vacuum cleaner housing 100 in which a vacuum source is installed, a suction port assembly 200 for drawing debris from a surface to be cleaned using the vacuum generated by the vacuum source, and an extension duct 110 connected to the suction port assembly 200 and to the vacuum cleaner body 100. Garbage is drawn through the suction port assembly 200 into the housing 100 via an extension channel 110.

The extension channel 110 comprises an extension tube connector 116, one end of which has a swivel joint or hinge 118 that can be rotatably connected to the suction port assembly 200. The first end of the extension tube 114 is connected to the second or opposite end of the extension tube connector 116. One end of the suction hose 112 is connected to an extension tube 114; its other end is connected to the housing 100 of the vacuum cleaner. Due to this technical solution, the debris coming in with the air is drawn in through the suction port assembly 200 and is transported to the vacuum cleaner body 100 via the extension pipe connector 116, extension pipe 114 and the suction hose 112.

Figure 3 shows a schematic, in perspective, with a spatial separation of the parts, the image of the node 200 of the suction hole shown in Figure 2. 3, a suction port assembly 200 includes a molded upper casing 210 defining an upper portion of a suction port assembly 200. The molded lower casing 22 forms the lower part of the suction port assembly 200.

The upper casing 210 has a suction channel cover 250, which, when assembled, is mounted on a first connecting portion 234 formed in the lower casing 222. The upper casing also has a upper cover 212 mounted above the suction channel cover 250 and is connected to the lower casing 222.

The suction channel cover 250 has a substantially arcuate cross-section, which is made of transparent plastic in a direction perpendicular to the direction of flow of the drawn-in air, and therefore, the stream of drawn-in debris is visible from the outside with the possibility of checking for jammed debris. A polycarbonate polymer or a ternary copolymer of acrylonitrile, butadiene and styrene can be used.

The upper cover 212 is connected to the lower casing 222 by a plurality of connecting holes 238 and a plurality of fasteners 236. The fasteners 236 can be threaded screws or bolts known in the art. The cover 250 of the suction channel passes through the upper cover 212 and through a cutout 214 made in the upper cover 212. In addition, the rear end of the lower casing 222 and the rear end of the upper cover 212 have lower and upper fasteners 224 and 264 of the extension pipe connector the swivel joint 118 of the extension pipe connector 116.

The lower casing 222 has a first and second suction holes 226 and 228, separated from each other in the lateral direction. Both the first and second suction holes 226 and 228 are located between the central part C and opposite sides S of the lower casing 222. The first and second suction holes 226 and 228 are preferably located essentially in the middle between the central part C and the opposite sides S. the location of the suction holes 226 and 228, the suction force created by the rarefaction source can be uniformly applied across the entire width of the suction hole assembly 200, making it possible to more efficiently clean fabrics of wide surfaces.

The first and second suction channels 230 and 232, in fluid communication with the first and second suction holes 226 and 228, respectively, are formed between the upper and lower casings. The first and second suction channels 230 and 232 are air channels and spaces formed in such a way that the lower casing 222 defines a lower surface 231 of the suction channels, the channel cover 250 forms the top of the suction channels 230 and 232 when the channel cover 250 is connected to the first connecting portion 234 formed in the lower casing 222. The following is a detailed description of a flange 258 formed along the edge of the channel cover 250.

FIG. 4 schematically shows a perspective view of the lower side of the lower casing 222. The lower side of the lower casing 222 contains dust moving side channels 240 formed on two opposite sides S of the lower casing 222 and connected to said suction openings 226 and 228 so that the dust located near the opposite sides S of the suction hole assembly 200, could be drawn in and moved into the suction holes 226 and 228. The front dust transfer duct 244 was also formed in the lower casing 222 and seals the possibility of drawing in and moving dust in front of the suction port assembly 200 through one or more central dust conveying ducts 242 formed between the first suction port 226 and the second suction port 228.

The central dust transfer ducts 242 extend from the lower surface of the lower casing 222 and are located between the first and second suction holes 226 and 228. As shown, the central dust transfer ducts 242 are separated from each other by a dividing rib 246. Separate central dust transfer ducts 242 on the left and right the sides of the ribs 246 are connected to the first suction hole 226 and the second suction hole 228, respectively. With this technical solution, the dust drawn from the central part C of the suction port assembly 200 is drawn into the suction ports 226 and 228 through the central dust conveying ducts 242.

FIG. 5 is a schematic perspective view of a lower side of a top cover according to an embodiment of the present invention. In FIG. 5, the top cover 212 has a cutout 214 formed therein, through which the fluid cover 250 projects so that it is open from the outside. A compression rib 216 is formed around the cutout 214 so that the compression rib 216 protrudes downward. The compression rib 216 has a shape similar to that of the cutout 214 and is mounted on a guide rib 254 (see FIG. 6) formed on the upper surface of the channel cover 250.

FIG. 6 is a sectional view of a channel cover taken along line VI-VI of FIG. 3. In FIG. 6, a section of the channel cover 250 is made in a direction perpendicular to the direction of flow of the drawn in air, and in it the guide rib 254 projects upward along the edge of the channel cover 250. The guide rib 254 has a shape corresponding to the compression rib 216 (see Fig. 5); and a compression rib 216 is located on the guide rib 254, connecting the upper cover 212 and the lower casing 222. A second connecting portion 262 is formed at the end of the lower surface of the channel cover 250. According to this embodiment, the second connecting portion 262 has a shoulder shape and engages with the first connecting portion 234 in an airtight manner. A description of the first connecting portion 234 follows.

FIG. 7 is a sectional view showing a main part taken along line VII-VII shown in FIG. 2. In FIG. 7, the first connecting portion 234 has a shoulder shape in the lower casing 222, and the second connecting part 262 also has a shoulder shape along the edge of the lower surface of the channel cover 250 to match the shape of the first connecting part 234. Since the first connecting part 234 and the second connecting part 262 engage friend, the channel cover 250 (see Fig. 3) and the lower casing 222 can be connected to each other, while ensuring air tightness between them. Accordingly, it is possible to ensure the airtightness of the channel and thereby prevent the weakening of the suction force.

On the upper surface of the channel cover 250, a guide rib 254 is made along its edge and protrudes upward; and a compression rib 216 is formed on the lower surface of the upper cover 212 in a shape corresponding to the shape of the guide rib 254. Due to this technical solution, a compression rib 216 formed on the lower surface of the upper cover 212 compresses a flange 258 formed on the channel cover 250 (see FIG. . 3). Therefore, the first connecting portion 234 and the second connecting portion 262 are pressed against each other by a compression rib 216 and thereby more reliably engage with each other. Due to this engagement, it is possible to more reliably ensure air tightness. In this case, the compression rib 216 is located on the guide rib 254, pressing the flange 258. This prevents the movement of the upper cover 213 on the channel cover 250.

FIG. 8 is a perspective view of the lower side of a channel cover 250 according to one embodiment of the present invention. In FIG. 8, a flow guiding rib 270 is formed in the central portion of the front end of the inner wall of the channel cover 250. The guide rib 270 comprises a first rib guide portion 274 extending from the central front end of the channel cover 250 to the first suction port 226 (see FIG. 3), and a second rib guide portion 278 extending to the second suction port 228 (see FIG. . 3). The front sides of the flow guide ribs 274 and 278 have guide surfaces 280 with a predetermined curvature, along which the air drawn in along the guide surfaces 280 changes its direction so that the drawn air rotates and is introduced into the vacuum source. The guide surfaces 280 have an optimal curvature along which the swirling flow generated at the junction of the first and second channels 230 and 232 is reduced as much as possible. The optimal curvature of the guide surfaces will depend on air flow and other parameters and is better determined experimentally. By experimentally optimizing the flow guiding portions 274 and 278, a change in flow direction can be minimized. In the shown embodiment, the flow guiding rib 270 is formed on the channel cover 250. Since the flow guiding rib 270 serves as a means of changing the direction of flow of the retracted air, the flow guiding rib 270 can, as an option, be performed in the lower casing 222 (see Fig. 3). Or, the flow guiding rib 270 can be made both in the lower casing 222 and in the channel cover 250.

FIG. 9 shows a partial cutaway perspective view schematically depicting a swirl of air drawn into a suction port assembly in which a flow guiding rib 270 is not provided. FIG. 10 shows a partial cutaway perspective view of a suction port assembly, with a schematic illustration of the flows of drawn air into a suction port assembly having a flow guide rib 270.

In FIG. 9, the air drawn into the first suction port 226 and the second suction port 228 moves along the first channel 230 and the second channel 232. The air flows moving along the first channel 230 and the second channel 232 collide with each other at the junction of the first channel 230 and the second channel 232, since the directions of their flow do not change smoothly. Due to this collision, a swirling turbulent flow is created at this junction. Swirling turbulent flow not only reduces the flow rate of the drawn-in air, but also causes a weakening of the suction force.

In FIG. 10 to a suction port assembly 200 having a flow guiding rib 270, air flows drawn through the first suction port 226 and the second suction port 228 are moved along the first channel 230 and the second channel 232 and their flow directions smoothly change at the junction of the first channel 230 and the second channel 232 using the flow guiding rib 270, respectively. As a result, the swirling flow created at the joint can be significantly reduced, thereby reducing the attenuation of the suction force.

FIG. 11 shows a cross section of the first and second connecting parts according to another embodiment of the present invention. In FIG. 11, the first and second connecting parts 234 and 262 are a rib and a groove to further increase the airtightness of the channel. In addition to the aforementioned embodiments, it is also possible to further provide an airtightness such as rubber.

The following describes a method for assembling a suction port assembly 200 according to an embodiment of the present invention with reference to FIG. 3.

First, the pivot joint 118 of the extension pipe connector 116 is coupled to a bottom side extension pipe connector mount 224; said mount is formed at the rear end of the lower casing 222; and then the channel cover 250 is mounted on the lower casing 222. This installation is performed by connecting the first connecting portion 234 formed in the lower casing 222 and the second connecting part 262 (see FIG. 7) formed on the channel cover 250.

Then, the upper cover 212 is mounted on the lower casing 222 and the channel cover 250. In this case, the hinge 118 of the extension pipe connector 116 is connected to the upper side extension pipe connector fastener 264; wherein said mount is formed on the upper cover 212, as a result of which the extension tube connector 116 is pivotally connected to the upper casing 210.

Then, a plurality of connecting elements, such as screws, are inserted into the plurality of connecting holes 238 formed in the upper cover 212 and the lower casing 222. The compression rib 216 (see FIG. 5) formed on the lower surface of the cutout 214 of the upper cover is engaged with a guide rib 254 (see FIG. 6) formed at the end of the flange 258 and compressing a flange 258 formed in the channel cover 250. As a result, the channel cover 250 is securely connected while providing air tightness.

In this embodiment, the channel cover 250 is installed in the suction port assembly 200 and is located between the upper cover 212 and the lower casing 222. But it is also possible to form the channel cover 250 in conjunction with the upper cover 212.

Since two suction channels are formed in the suction port assembly 200, it is possible to increase the cleaning efficiency of the sides of the suction port assembly 200. Therefore, it is possible to efficiently process wide surfaces.

In addition, due to the implementation of the channel cover 250 from a transparent material, it is possible to check the presence of debris drawn into and passing through the suction hole assembly 200 outside the suction port assembly. Therefore, the need to check the entire suction channel of the vacuum cleaner is eliminated to solve the problem caused by stuck debris in the suction hole assembly.

According to the present invention, the flow guiding rib 270 formed in the suction channel can reduce the swirl of the drawn in air, thereby reducing the attenuation of the suction force.

Due to the fact that the first connecting part 234 formed on the channel cover and the second connecting part 262 formed on the lower casing are engaged with each other, the channel cover can be mounted on the lower casing and the upper cover will compress the first and second connecting parts. This makes assembly easier and reliable airtightness. Due to air tightness, it is possible to eliminate the weakening of the suction force.

Although embodiments of the present invention have been set forth with reference to their characterization to explain the principle of the present invention, the present invention is not limited to these embodiments. It is understood that those skilled in the art can make various modifications and changes within the scope of the idea and scope of the present invention as defined in the appended claims. Therefore, it is understood that all of these modifications, changes, and equivalents of the invention are included within the scope of the present invention.

Claims (20)

1. A suction port assembly comprising an upper and lower casing connected to each other, wherein said lower casing has a central portion between the first and second side sides, a plurality of suction openings formed in the lower casing, a plurality of suction channels formed between the upper and lower casings, for directing air drawn in from a plurality of suction openings. 2. The suction hole assembly according to claim 1, wherein the plurality of suction holes includes a first suction hole and a second suction hole formed in the lower casing and spaced apart from each other, the plurality of channels including a first suction channel and a second suction channel which communicate with the first suction port and the second suction port, respectively. 3. The suction hole assembly according to claim 2, in which the first suction hole is formed between the Central part and one side of the lower casing and the second suction hole is formed between the Central part and the other side of the lower casing. 4. The suction hole assembly according to claim 2, which further comprises side channels extending from the lower surface of the lower casing and opening through the sides of the lower casing, operatively connected with the first and second suction holes, a central dust-moving channel extending from the lower surface of the lower casing so that the first and second suction openings are fluidly coupled to one another and one or more dust-moving channels extending from the lower surface of the lower air and passing through the front of the lower casing so that the front end of the lower casing is fluidly connected to the first and second suction openings. 5. The suction hole assembly according to claim 2, in which the upper casing comprises a suction channel cover forming the top of the first and second suction channels and attached to the lower casing, and an upper cover located above the channel cover and connected to the lower casing. 6. The suction port assembly according to claim 5, wherein the suction channel cover has an arcuate cross-section from a direction perpendicular to the direction of flow of the retracted air. 7. The suction hole assembly according to claim 6, which further comprises a first connecting part formed along the edge of the channel cover and a second connecting part formed in the lower housing and corresponding to the first connecting part, as a result of which it is adapted to engage with the first connecting part , while maintaining air tightness. 8. The suction hole assembly according to claim 7, in which the first and second connecting parts are a pair of parts having corresponding ledges. 9. The suction port assembly according to claim 7, in which the first and second connecting parts consist of a connecting rib and a connecting recess corresponding to the connecting rib. 10. The suction port assembly according to claim 7, which further comprises a compression rib formed on the lower surface of the upper cover and a guide rib formed on the upper surface of the channel cover and having a shape substantially corresponding to the compression rib, whereby the compression rib can install on the guide rib. 11. The suction port assembly according to claim 5, wherein the channel cover is made of a transparent material. 12. The suction port assembly according to claim 2, which further comprises a flow guiding rib on the first and second channels, configured to direct the drawn air to the vacuum source. 13. The suction port assembly according to claim 7, wherein the flow guiding rib comprises a first part of the flow guiding rib formed on the first channel and a second part of the flow guiding rib formed on the second channel so that the second part of the flow guiding rib is connected to one end of the first flow guiding rib. 14. The suction port assembly of claim 13, wherein both the first and second parts of the flow guide ribs have a guide surface of a predetermined curvature. 15. A vacuum cleaner comprising a vacuum cleaner body having a vacuum source, an extension vacuum channel having first and second ends, the first end of the channel being connected to the vacuum cleaner body so that air can pass through the extension channel to the vacuum source, and a suction port assembly, connected to the second end of the extension vacuum channel; wherein the suction port assembly comprises an upper and lower casing, a plurality of suction openings formed in the lower casing, and a plurality of suction channels formed in the upper and lower casings to direct air drawn from these suction openings. 16. The vacuum cleaner according to claim 15, wherein the plurality of suction openings consists of a first suction opening and a second suction opening formed in the lower casing and spaced apart from each other, wherein the plurality of suction channels includes first and second channels that communicate with the first suction port and the second suction port, respectively. 17. The vacuum cleaner according to clause 16, in which the upper casing contains a channel cover forming the top of the first and second suction channels and connected to the lower casing, and an upper cover located above the channel cover and connected to the lower casing. 18. The vacuum cleaner according to claim 17, wherein the suction hole assembly further comprises a first connecting part formed along an edge of the channel cover and a second connecting part formed in the lower casing and corresponding to the first connecting part, as a result of which it can engage with the first connecting part . 19. The vacuum cleaner according to claim 18, wherein the suction port assembly further comprises a compression rib formed on the lower surface of the upper cover and a guide rib formed on the upper surface of the channel cover and whose shape corresponds to the shape of the compression rib. 20. The vacuum cleaner according to claim 18, wherein the suction port assembly further comprises a flow guiding rib formed on the first and second channels and configured to direct the drawn air to the vacuum source.

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