RU2295273C2 - Suction inlet unit for vacuum cleaner - Google Patents

Abstract

FIELD: mechanical engineering.

SUBSTANCE: suction inlet unit for vacuum cleaner having low pressure source is equipped with lower casing including first and second suction openings, upper casing connected to lower casing so as to define connection channel for first and second suction openings, and noise volume decreasing unit extending along connection channel which is in fluid communication with low pressure source.

EFFECT: increased efficiency in sucking of dust at both sides of vacuum cleaner.

20 cl, 7 dwg

Description

CROSS REFERENCE TO RELATED APPLICATIONS

The priority of this application is claimed on Korean Patent Application No. 2004-88648, which was filed November 3, 2004 with the Korean Intellectual Property Office, the description of which is fully incorporated into this application by reference.

BACKGROUND OF THE INVENTION

Field of Invention

The present invention relates to a vacuum cleaner. More specifically, this invention relates to a suction inlet assembly of a vacuum cleaner for drawing contaminants from a surface to be cleaned.

Description of the prior art

In general, vacuum cleaners draw dust from a surface to be cleaned due to the suction force created by a vacuum source installed inside the vacuum cleaner body. Such vacuum cleaners include a housing in which a vacuum source is installed, a suction inlet for dust intake, facing the surface to be cleaned, and an extension channel for guiding dust drawn through the suction inlet.

Since conventional suction inlet assemblies have a suction port to which a suction force is transmitted to allow dust to be drawn in in the middle, the suction force is concentrated in the middle part of the suction inlet, where the suction port is located, while the side parts of the suction inlet are smaller exposed to suction forces. The consequence of this is a deterioration in the absorption efficiency in the lateral parts compared to the middle part.

To overcome these drawbacks, US Pat. No. 6,532,622 proposed a method according to which a pair of suction openings is located on both sides of the suction inlet assembly. However, in this case, the disadvantage is that the dusty air flows drawn through a pair of suction openings converge together near a narrow outlet connected to the extension connector, resulting in noise caused by an increase in the speed of air flows and swirling air created by the collision of air flows together.

SUMMARY OF THE INVENTION

In one aspect of the present invention, there is provided a solution to at least the above problems and / or addressing the disadvantages, as well as providing at least the following advantages. Accordingly, an aspect of the present invention is to provide a suction inlet of a vacuum cleaner in which suction efficiency on both sides of a suction inlet is equally improved.

To implement the above aspects of the present invention, there is provided a suction inlet assembly of a vacuum cleaner comprising a lower housing in which there are first and second suction holes, an upper housing connected to the lower housing to form a connecting channel for the first and second suction holes, and a noise reducing assembly located along the connecting channel. The upper case comprises a channel cover and an upper cover attached to the lower case above the channel cover.

The noise reduction assembly may comprise a first noise reduction rib that has first inclined holes and a second noise reduction rib that has second inclined holes. The first and second noise reducing ribs can be substantially symmetrical to each other.

The connecting channel in the middle of the rear wall may have an air outlet, wherein a first noise reducing rib can be installed along the rear wall of the connecting channel to the right of the air outlet, and a second noise reducing rib can be installed along the rear wall of the connecting channel to the left of the outlet for air.

The heights H2 and H3 of the first and second noise reducing ribs can decrease to the right and left of the air outlet, respectively, while these ribs can be bent respectively in the direction of the first and second suction holes.

The first and second inclined openings can be tilted at angles θ1 and θ2 in the direction of discharge of dusty air through the air outlet. Angles θ1 and θ2 can range from approximately 40 ° to 70 °.

The widths W1 and W2 of the first and second inclined openings, respectively, can be approximately 0.5 to 1.0 from the distances D1 and D2 between the first inclined openings and between the second inclined openings.

The suction inlet assembly may further comprise first and second noise absorbing elements mounted on both sides of the connecting channel.

The first noise attenuating element may be located between the first noise attenuating rib and the connecting channel, and the second noise attenuating element may be installed between the second noise attenuating rib and the connecting channel.

The heights of H5 and H6, respectively, of the first and second sound-absorbing elements can gradually decrease to the right and left of the air outlet, and these elements can also be bent in the direction of the first and second suction holes respectively.

The first and second noise absorbing elements can be made of porous material.

BRIEF DESCRIPTION OF THE DRAWINGS

The above aspect and other features of the present invention will be more apparent from the detailed description of exemplary embodiments of the present invention with reference to the accompanying drawings, in which:

figure 1 depicts a schematic view of a vacuum cleaner containing a suction inlet node in accordance with a variant implementation of the present invention;

figure 2 depicts an exploded view in perspective view of the suction inlet node shown in figure 1;

figure 3 depicts a rear view in a perspective view of the suction inlet node shown in figure 1;

figure 4 depicts a top view of the suction inlet node shown in figure 1;

FIG. 5 is an enlarged top view of a portion of the suction inlet assembly shown in FIG. 4, which shows a first noise reduction rib and a first noise absorption element;

Fig.6 depicts an enlarged perspective view of part of the suction inlet node shown in Fig.4, which shows the first noise reduction rib;

FIG. 7 is an enlarged perspective view of a portion of the suction inlet assembly shown in FIG. 4, showing a first sound absorbing member.

DETAILED DESCRIPTION OF EXAMPLE OPTIONS

Below is described in more detail a typical embodiment of the present invention with reference to the accompanying drawings.

In the following description, like reference numerals refer to like elements even in different drawings. The objects defined in the description, such as design and elements, are only means of a better understanding of the invention. Thus, it is obvious that the present invention can be performed without defining these objects. In addition, well-known functions or designs are not described in detail since they interfere with the understanding of the description by introducing non-essential details.

As shown in FIG. 1, a vacuum cleaner 100 comprising a suction inlet 200 in accordance with an embodiment of the present invention includes a housing 110 having a vacuum source (not shown), a suction inlet 200 designed to draw dust from a surface to be cleaned by the suction force created by the rarefaction source, and an extension channel 120 connected to the suction inlet assembly 200 and designed to direct the dust drawn through the assembly 200 to the cleaner body 110. The extension channel 120 comprises an extension connector 126 rotatably attached to the assembly 200, an extension pipe 124 and a suction hose 122, connected at one end to an extension pipe 124 connected to the connector 126, and the second end to the cleaner body 110.

As shown in FIGS. 2 and 3, the suction inlet assembly 200 according to an exemplary embodiment of the present invention comprises a lower housing 210, an upper housing 250 and a noise reducing assembly 300.

The lower housing 210 has a first suction port 211 and a second suction port 212 spaced apart from each other and designed to draw dust from a surface to be cleaned.

The hole 211 is made in the lower part of the lower case 210 at a predetermined distance to the right of the partition 213, and the hole 212 is made in the lower part of the lower case 210 at a predetermined distance to the left of the partition 213.

Due to the presence of the first and second openings 211 and 212, the suction force is preferably uniformly transmitted to the middle part M and the side parts S of the suction inlet 200. That is, dusty air drawn into the middle part M in the direction Q1 shown by the arrow and dusty air drawn into the side portions S in the directions Q2 and Q3 shown by arrows can flow smoothly into the suction inlet 200.

Therefore, it is possible to ensure suction efficiency in the side portions S with the same success as in traditional designs of the suction inlet assembly with one suction port located only in the middle part M. Also, due to an increase in the suction efficiency in the middle part M, the area of the surface to be cleaned can be increased. Although the first and second holes 211 and 212 in the present embodiment are semicircular in shape, this is not limited to their shape. Suction openings 211 and 212 may be of any shape, for example, an oval or a triangle.

To increase the cleaning efficiency, the first and second lower holes 216 and 217, as well as the first and second dust channels 214 and 215, are made in the lower case 210. Top cover 230 may include first and second top openings 231 and 232.

The first and second lower holes 216 and 217 are made in the lower part of the lower housing 210, while the first lower hole 216 has a slope to the right, and the second lower hole 217 has a slope to the left with respect to the partition 213.

In this embodiment, the first and second lower holes 216 and 217 are rectangular in shape, however, they can be of any shape, for example, an oval or a triangle. Also, their location may vary depending on the location of the first and second suction holes 211 and 212.

The first dust channel 214 passes through the first lower hole 216 in the lower part of the lower housing 210, and also through the first suction hole 211, starting to the right of the partition 213 and ending at the right side wall 210b of the lower housing 210. The second dust channel 215 passes through the second the lower hole 217 in the lower part of the lower housing 210, as well as through the second suction hole 212, starting to the left of the partition 213 and ending at the left side wall 210c of the lower housing 210.

Due to the above construction, the outside air drawn in through the first and second upper openings 231 and 232, respectively, in the directions F1 and F2 shown by arrows, passes into the sealed intake suction unit 200 (FIG. 1) in the directions F3 and F4 shown by arrows, and is directed to the lower part of the lower housing 210 through the first and second lower holes 216 and 217.

The directed outside air scatters the dust accumulated between the first and second channels 214 and 215, while the dusty air containing the scattered dust is drawn into the first and second suction holes 211 and 212 through the first and second channels 214 and 215 in the directions F3 and F4 shown arrows. Accordingly, dust located between the first and second channels 214 and 215 can be easily cleaned, thereby improving cleaning efficiency.

As shown in FIGS. 2 and 4, the upper case 250 comprises a channel cover 220 and a upper cover 230. The cover 220 and the upper cover 230, which in this exemplary embodiment are separate, can be made as a unit.

The cover 220 is attached to the lower housing 210 to form a connecting channel 221, designed to connect the first and second suction holes 211 and 212.

More specifically, the upper wall of the channel 221 is formed by a cover 220, and the lower part and the rear wall 210d of the channel 221 are formed by the lower housing 210.

The cover 220 has a substantially vaulted or arcuate portion located vertically with respect to the direction of flow of the air drawn in, while it is U-shaped along its length when viewed in the direction X1 shown by the arrow. As such, cover 220 has a maximum height H1 at its center, which gradually decreases towards both sides.

The cover 220 is preferably made of a transparent material so that the user can observe the movement of the retracted dust.

As shown in FIG. 2, the upper cover 230 is connected to the lower housing 210 above the cover 220 to form a sealed space inside the suction inlet 200. The upper cover 230 has first and second upper openings 231 and 232 for communicating with the outside air, as described above. External air passing through the sealed space and drawn in through the first and second upper openings 231 and 232 can be discharged into the first and second lower openings 216 and 217 (FIG. 3).

The top cover 230 comprises a cut section 233 in a shape corresponding to the cover 220, so that the cover 220 is visible relative to the inlet assembly 200. In other words, the cover 220 protrudes outward from the top cover 230 through the cut section 233.

Although the first and second upper holes 231 and 232 are made in the form of slots in accordance with an exemplary embodiment, other numbers, other shapes and sizes of holes, such as through holes, are also possible. Alternatively, it is possible to create a protective element or valve for the first and second upper holes 231 and 232 so that the first and second upper holes 231 and 232 open only for the incoming air.

As shown in FIGS. 2-4, an air outlet 210e is formed in the middle of the rear wall 210d of the channel 221, while an extension connector 126 (FIG. 1) is inserted into this hole 210e, which is rotatably and / or rotationally mounted.

Dusty air flows drawn from the first suction port 211 in the direction Q5 shown by the arrow, as well as from the second suction port 212 in the direction Q6 shown by the arrow, converge to the outlet 210e.

Since dusty air streams drawn in through openings 211 and 212 and then converging to outlet 210e are discharged together through connector 126, noise may occur due to an increase in air velocity and air swirl created when air streams collide with each other. In addition, noise can be caused by pressure and direct collision of air flows with the rear wall 210d.

As shown in figure 2, the channel 221 contains a noise reduction unit 300, preventing such noise and having a first and second noise reducing ribs 310 and 320, as well as the first and second noise absorbing elements 330 and 340.

The first and second ribs 310 and 320 are preferably symmetrical to each other relative to the channel 221, while they can be made of plastic, for example acrylic. It is also possible to use other materials, such as glass and metal, to make ribs 310 and 320.

Since the first and second ribs 310 and 320 have the same shape, only the first rib 310 shown in FIGS. 5 and 6 is described below as a detailed description of the first and second ribs 310 and 320.

The first rib 310 is installed along the rear wall 210d of the channel 221 in the direction R shown by the arrow, that is, to the right of the hole 210e.

This allows dusty air, as far as possible, to come into contact with the rear wall 210d, since the dusty air most likely deflects to the rear wall 210d of the channel 221 during passage from the first suction port 211 to the channel 221 due to the curved shape of the channel 221. Therefore By installing the first rib 310 along the rear wall 210d, it is more effective in counteracting the occurrence of noise.

As shown in FIG. 5, a first element 330 is inserted between the first rib 310 and the rear wall 210d of the channel 221.

As shown in FIG. 2, the first rib 310 is made with a gradual decrease in the height H2 in the direction R shown by the arrow, that is, to the right, while the structure is curved in the direction of the first suction hole 211.

The first rib 310 is made as described above, taking into account the height of the cover 220 and the shape of the rear wall 210d of the channel 221, which facilitates its installation in the channel 221. In addition, dusty air can pass through the channel 221, experiencing less resistance from the first rib 310.

As shown in FIG. 5, the first rib 310 has first inclined openings 310a inclined at an angle θ1 to the vertical in the direction Q5 shown by the arrow, that is, in the direction of movement of dusty air from the first suction port 211 to the outlet 210e. In this case, the value of the tilt angle θ1 lies in the range of about 40 ° to 70 °.

This inclination prevents the direct passage of dusty air passing through the channel 221 into the first inclined holes 310a. More specifically, the dusty air during passage through the channel 221 in the direction Q5 shown by the arrow enters the first inclined holes 310a in the direction Q8 shown by the arrow, with a change driving directions. For this, the angle θ1 can limit the scattering and deviation of dusty air passing in the direction Q5 shown by the arrow.

The width W1 of the first inclined holes 310a is approximately 0.5 to 1.0 from the distance D1 between these holes 310a. Dusty air partially enters through the first openings 310a having a width W1.

As shown in FIGS. 2 and 7, the first element 330 has a height H5 gradually decreasing in the direction R shown by the arrow, that is, to the right of the outlet 210e, while it is curved in the direction of the first suction hole 211 to allow installation or other placement between the first rib 310 and the rear wall 210d of the channel 221.

The first element 330 secondarily reduces the noise that was initially reduced by the first rib 310, for which porous materials such as sponge materials, conventional filters and foams can be used in the first element 330.

The following describes the relationship between the first element 330 and the first rib 310.

As shown in FIGS. 2, 5 and 7, the rear side 330b of the first element 330 is preferably attached to the rear wall 210d of the channel 221 using glue. Further, the first rib 310 is attached to the front side 330a of the first element 330 with glue, so that the first rib 310 and the first element 330 are installed along the channel 221.

However, the first sound absorbing element 330 is not an indispensable element of the present invention. In the absence of the first element 330, the first rib 310 can be attached directly to the rear wall 210d of the channel 221. In addition, instead of glue, other methods of fastening the first rib 310 and the first element 330 can be used, for example, using screws or welding.

As shown in FIGS. 2 and 4, a second rib 320 is attached along the rear wall 210d of the channel 221 in the L direction shown by the arrow, that is, to the left of the outlet 210e. A second element 340 is inserted between the second rib 320 and the rear wall 210d of the channel 221.

The second rib 320 has a height H3 gradually decreasing in the direction L shown by the arrow, that is, to the left of the air outlet 210e, while it is curved in the direction of the second suction hole 212.

The reason for the specified shape and location of the second rib 320 is the same as for the first rib 310.

The second rib 320 has second inclined openings 320a inclined at an angle θ2 to the vertical in the direction Q6 shown by the arrow, that is, in the direction of moving dusty air from the second suction port 212 to the outlet 210e. In this case, the value of the tilt angle θ2 lies in the range of about 40 ° to 70 °.

Said inclination prevents the direct passage of dusty air passing through channel 221 into the second inclined holes 320a. More specifically, dusty air during passage through the channel 221 in the direction Q6 shown by the arrow enters the second inclined holes 320a in the direction Q9 shown by the arrow, with a change driving directions. For this, angle θ2 can limit the scattering and deflection of dusty air passing in the direction Q6 shown by the arrow.

The width W2 of the second inclined holes 320a is from about 0.5 to 1.0 times the distance D2 between said holes 320a. The dusty air partially enters through the second inclined openings 320a having a width W2.

As shown in FIG. 2, the second element 340 has a height H6 gradually decreasing in the direction L shown by the arrow, that is, to the left of the air outlet 210e, while it is curved in the direction of the second suction hole 212 for installation or other placement between the second rib 320 and rear wall 210d of channel 221.

The second element 340 secondly reduces the noise that was initially reduced by the second rib 320, for which porous materials, for example spongy materials, conventional filters and foams, can be used in the second element 340.

Since the relationship between the rear wall 210d, the second element 340 and the second rib 320 is similar to the relationship between the rear wall 210d, the first element 330 and the first rib 310, the description of this relationship is not repeated.

The following is a description of the operation of a vacuum cleaner 100 that uses a suction inlet assembly 200 in accordance with an embodiment of the present invention.

As shown in FIG. 1, the suction force generated by a vacuum source (not shown) that is installed in the cleaner body 110 is transmitted to the suction inlet assembly 200, passing through the suction hose 122, extension pipe 124 and extension pipe connector 126.

As illustrated in FIGS. 2 and 4, the suction force transmitted to the suction inlet 200 is then transmitted to the first and second suction openings 211 and 212, respectively, in directions opposite to the directions Q5 and Q6 shown by arrows.

Due to the transmitted suction force, dusty air drawn in in the direction Q1 in the middle part M of the suction inlet 200, as well as dusty air flows drawn in the directions Q2 and Q3 shown by arrows in the side parts S of the suction inlet 200, are drawn into the first and a second suction port 211 and 212.

In addition, as illustrated in FIGS. 2 and 4, the suction force transmitted to the first and second suction holes 211 and 212 is then transmitted to the first and second lower holes 216 and 217, respectively, through the first and second dust channels 214 and 215.

The suction force transmitted to the first and second lower holes 216 and 217 is transmitted to the first and second upper holes 231 and 232 through a sealed space formed by connecting the upper cover 230 to the lower housing 210. Due to the suction force, the outside air is drawn in through the first and second upper holes 231 and 232 in the directions F1 and F2 shown by arrows.

In the process of passing through the sealed space formed by the connection of the upper cover 230 with the lower case 210, as well as through the first and second lower holes 216 and 217, the air drawn in through the first and second upper holes 231 and 232 collides with the surface being cleaned and thereby disperses dust accumulated in the first and second channels 214 and 215.

Air containing dispersed dust passes through the first and second channels 214 and 215 in the directions F3 and F4 shown by arrows, and enters the openings 211 and 212.

As shown in FIG. 4, dusty air drawn into the openings 211 and 212 in the directions Q1, Q2, Q3, F3 and F4 moves in the directions Q5 and Q6 shown by arrows to pass through the channel 221, where the noise reduction unit 300 is installed, which contains the first and second ribs 310 and 320, as well as the first and second elements 330 and 340.

At this stage, dusty air can flow into the first and second inclined holes 310a and 320a made in the first and second ribs 310 and 320, in the directions Q8 and Q9 shown by arrows, and accordingly dusty air can be partially trapped by the holes 310a and 320a.

It is also possible to disperse the impact and pressure arising from the collision of dusty air with the first and second ribs 310 and 320 due to the first and second inclined openings 310a and 320a.

As a result, it is possible to reduce the noise encountered in conventional vacuum cleaners, which is caused by the convergence of dusty air flows in the air outlet 210e and the dusty air colliding with the rear wall 210d of channel 221. Noise can be further reduced by using the first and second elements 216 and 217 .

According to experimental data, in the presence of node 300, the total noise can be reduced by approximately 1.5 dB (A), i.e., from 74.5 dB (A) to 73.0 dB (A).

As shown in FIGS. 1 and 2, dusty air flows converge to the air outlet 210e and move to the cleaner body 110, passing through the connector 126, extension pipe 124 and suction hose 122. During this process, dust is collected and exhaust separated from dust of air out.

We list some of the advantages of the suction inlet assembly 200 for the vacuum cleaner described above.

Firstly, the suction force can be uniformly transmitted to the middle and side parts due to the presence of the first and second suction holes 211 and 212 located at a distance from each other, while the suction efficiency is improved.

Secondly, due to the fact that the node 300 can prevent the increase in the speed of air flow and the swirl of air created by the collision of air flows, there is a reduction in noise, which allows for a quieter cleaning.

Thirdly, the presence of the node 300 can reduce the noise caused by the impact and pressure generated during the direct collision of dusty air with the rear wall 210d of the channel 221, which allows for a quieter cleaning.

While the present invention has been shown and described with reference to certain embodiments, it will be understood by those skilled in the art that various changes in form and detail are possible without departing from the spirit and scope of the invention as defined in the attached claims.

Claims (20)

1. The suction inlet assembly of a vacuum cleaner having a vacuum source comprising a lower housing having first and second suction openings, an upper housing connected to the lower housing to form a connecting channel for the first and second suction openings, and a noise reducing assembly mounted along the connecting channel, which flowingly communicates with the source of rarefaction. 2. The suction inlet assembly according to claim 1, wherein the upper housing comprises a channel cover and an upper cover attached to the lower housing above the channel cover. 3. The suction inlet assembly according to claim 2, wherein the noise reducing assembly comprises a first noise reducing rib having first inclined holes and a second noise reducing rib having second inclined holes. 4. The suction inlet according to claim 3, wherein the first and second noise reducing ribs are substantially symmetrical to each other. 5. The suction inlet according to claim 3, in which the connecting channel in the middle of its rear wall has an air outlet, wherein the first noise reducing rib is installed along the rear wall of the connecting channel to the right of the air outlet, and the second noise reducing rib is installed along the back wall of the connecting channel to the left of the air outlet. 6. The suction inlet assembly according to claim 5, in which the height of the first and second noise reducing ribs decreases respectively in the direction of removal from the air outlet, said ribs being curved in the direction from the first and second suction holes, respectively. 7. The suction inlet according to claim 3, wherein each of the first and second inclined openings is inclined at angles θ1 and θ2, respectively, in the direction of discharge of dusty air through the air outlet, wherein the angles θ1 and θ2 are approximately 40 to 70 ° . 8. The suction inlet according to claim 3, in which the width W1 and W2 of each of the first and second inclined holes, respectively, is from about 0.5 to 1.0 from the distances D1 to D2 between each of the first inclined holes and between each of the second inclined holes. 9. The suction inlet according to claim 3, further comprising first and second noise absorbing elements along the connecting channel. 10. The suction inlet according to claim 9, in which the first noise reduction element is located between the first noise reduction rib and the connecting channel, and the second noise absorption element is located between the second noise reduction rib and the connecting channel. 11. The suction inlet according to claim 9, in which the height of H5 and H6, respectively, of the first and second sound-absorbing elements decreases in the direction of removal from the air outlet, while the first and second sound-absorbing elements are curved in the direction of the first and second suction holes, respectively. 12. The suction inlet assembly of claim 11, wherein the first and second noise absorbing elements are at least partially made of a porous material. 13. A vacuum cleaner comprising a rarefaction source and a suction inlet assembly, fluidly communicating with a rarefaction source and comprising upper and lower housings and a noise reducing assembly, the lower housing having first and second suction openings, and the upper housing connected to the lower housing and at least partially restricting a connecting channel for the first and second suction openings, which in its middle part has an air outlet for air to pass to the vacuum source and along which noise is located step-down unit. 14. The vacuum cleaner of claim 14, wherein the noise reducing assembly comprises a first noise reducing rib having first inclined openings and a second noise reducing rib having second inclined openings. 15. The vacuum cleaner of claim 14, wherein the first and second noise reducing ribs are substantially symmetrical to each other and are located on opposite sides of the air outlet. 16. The vacuum cleaner according to 14, in which the air outlet is located along the rear wall of the connecting channel, and the first and second noise reducing ribs are located on opposite sides of this hole. 17. The vacuum cleaner according to 14, in which the height of the first and second noise reducing ribs decreases, respectively, in the direction of removal from the air outlet, while these ribs are bent in the direction of the first and second suction holes respectively. 18. The vacuum cleaner according to 14, in which the connecting channel contains the first and second sound absorbing elements. 19. The vacuum cleaner according to claim 18, wherein the first noise reduction element is located between the first noise reduction rib and the connecting channel, and the second noise absorption element is located between the second noise reduction rib and the connecting channel. 20. The vacuum cleaner according to claim 18, wherein the first and second noise absorbing elements are at least partially made of a porous material.

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