KR20010012044A - dust collector in vacuum cleaner - Google Patents

Abstract

PURPOSE: A dust collector for the vacuum cleaner employs a cyclone to keep the regular suction force for collecting dust in the regular direction. CONSTITUTION: The dust collector has two extension tube sections, one connecting to a main body having a suction force generator in it and the other connecting to a hand grip and to a suction mouth. The air and dust in suction flow smoothly through the tube and cyclone in the regular direction of suction and discharge to the effect of better dust collection.

Description

Dust collector in vacuum cleaner

The present invention relates to a vacuum cleaner, and more particularly, to a dust collector attached to an extension tube of a vacuum cleaner so that contaminants sucked into the vacuum cleaner can be collected before being introduced into the main body constituting the vacuum cleaner.

In general, a vacuum cleaner generates a suction force for cleaning corners and other places that are difficult to clean with a broom or other cleaning tools in cleaning a house, a car, or other places, and removes foreign substances such as dust by the suction force. It is a device.

Such a vacuum cleaner forms the main body 1 by the lower cover 1a and the upper cover 1b as shown in FIG. 1, and the suction hose 3 is inserted into the insertion hole 2 of the upper cover 1b. Is detachably connected, and the other end of the suction hose 3 is attached to a handle portion 4 having a controller portion (not shown), and one end of the extension pipe 5 is attached to the handle portion 4. The detachable inlet body 6 is detachably connected to the other end of the extension pipe 5 according to the intended use.

In addition, in the lower cover 1a constituting the main body 1 as shown in FIG. 2, a fan 8 is installed to generate suction while rotating under the driving force of the motor 7. A dust collecting bag 9 is detachably inserted in the front inner surface to collect most of the dust and foreign matter sucked together with the air, and a discharge hole 10 is formed in the rear of the lower cover 1a to discharge the sucked air. have.

Referring to the general operation of the vacuum cleaner configured as described above in more detail.

First, according to the needs of the user, the type of the suction inlet 6 is connected, and the selected suction inlet is connected to the end of the extension tube 5 to supply power to the vacuum cleaner.

Subsequently, when the suction mode of the controller part provided in the handle part 4 is selected by holding the handle part 4 attached to the other end of the suction hose 3, the motor attached to the lower cover 1a of the main body 1 is attached. (7) is driven to rotate the fan 8, so suction force is generated.

When the suction force is generated in this way, the user performs cleaning by placing the suction port 6 at a desired position for cleaning using the handle portion 4.

Accordingly, foreign matter such as dust is sucked into the suction inlet 6 by the suction force of the fan 8 in the main body 1 together with the air, and the foreign matter such as dust sucked by the extension pipe 5 and the handle portion 4. And it passes through the suction hose 3 and enters the main body 1 inside.

At this time, the dust collecting bag 9 is inserted into the upper cover 1b constituting the main body 1 in a state in which the inlet portion is in contact with the insertion hole 2 forming part of the upper cover. The contaminants are collected in the dust collecting bag 9 and move out of the dust collecting bag 9 by the suction force according to the rotation of the fan 8 in which only air continues and move toward the rear of the main body 1.

The air moving toward the rear of the main body 1 is discharged to the outside through the discharge hole 10 formed on the rear surface of the lower cover 1a, thereby enabling the continuous cleaning.

On the other hand, the vacuum cleaner which performs the cleaning while operating as described above has a main body constituting the entire vacuum cleaner as the dust collecting part (dust collection bag 9) that collects contaminants sucked in its configuration is located in the main body 1 ( 1) has increased in size.

Accordingly, in order to implement a small vacuum cleaner that is easy to carry, the dust collecting unit 20 using the cyclone method is provided in the extension pipe 5 constituting the vacuum cleaner as shown in FIG. The size of the main body 1 is to be reduced.

Hereinafter, the state in which the cyclone dust collector is provided in the extension tube of the vacuum cleaner as described above will be described in detail.

First, the cyclone dust collector has a cyclone body 21 having a cylindrical shape as a whole, and suction is configured so that air and contaminants can be sucked in the tangential direction in the cyclone body at an upper portion of the circumferential surface of the cyclone body. The flow path tube 22 is provided.

In addition, the inside of the cyclone body is provided with an air discharge pipe 23 to discharge the sucked air to the outside of the cyclone body, the air discharge pipe is erected in the same direction as the forming direction of the cyclone body 21 As the state, the upper end is configured to penetrate the upper portion of the cyclone body.

The lower part of the cyclone body is provided with a dust collecting tube 24 so that the contaminants are collected in communication with the inside of the cyclone body.

In order to connect the cyclone dust collector 20 configured as described above to the extension pipe 5, the extension pipe is divided into two parts, and the extension pipe on the side into which air and contaminants are introduced from the outside of the two divided pipes, that is, the suction port and An extension pipe (hereinafter referred to as "first extension pipe") 5a of the connected side is connected to the suction flow path pipe 22 constituting the cyclone dust collector and connected to the handle portion 4 constituting the vacuum cleaner. The extension tube (hereinafter referred to as "second extension tube") (5b) of one end is connected to the air discharge pipe 23 of the cyclone dust collector.

Therefore, when the cleaning is performed according to the user's needs while the power is supplied, air and contaminants are introduced through the inlet port 6 by the suction force according to the rotation of the fan 8 in the main body 1 constituting the vacuum cleaner. The back is inhaled.

Air and contaminants sucked in this way are cycled through the suction flow path pipe 22 of the cyclone dust collector 20 connected to the extension pipe as shown in FIG. 3 in the process of flowing along each of the extension pipes 5a and 5b. It is introduced into the clone body 21.

At this time, the suction passage pipe is configured to make a tangential direction with respect to the cyclone body 21, so that air and contaminants sucked into the cyclone body are sucked in the tangential direction of the cyclone body. Will have

In addition, at this time, the suction force is continuously transmitted through the air discharge pipe 23 constituting the cyclone dust collector 20, so that the air and contaminants sucked in the tangential direction in the cyclone body are separated from the cyclone body. It descends while turning along the inner circumference of.

This is because the air inlet side of the air discharge pipe 23 through which the suction force is transmitted is located at the bottom side in the cyclone body 21 relative to the height of the intake passage pipe 22 formed in the cyclone body 21. In addition, it is understood that air and contaminants sucked through the suction passage pipe flow to the lower side of the cyclone body 21.

In addition, as described above, air and contaminants are subjected to different centrifugal forces by different weights in the process of turning along the inner wall surface of the cyclone body 21 to separate various contaminants from the air.

The dust can be separated from the air at the centrifugal force because it has a constant mass as described above.

That is, F = me Air close to zero due to (F; centrifugal force, m; mass, e; distance from the center of the cyclone body to the inner wall of the cyclone body, ω; angular acceleration) produces almost no centrifugal force, Is to orbit the inner wall of the cyclone body under the influence of centrifugal force.

As a result, various contaminants are collected in the dust collecting container 24 coupled to the bottom of the cyclone body 21 by the above-described process.

In addition, the air having almost no weight is again lifted along the center of the cyclone body from the lower part in the cyclone body 21 by the suction force generated through the air discharge pipe 23, and the vacuum cleaner is moved through the air discharge pipe. After being introduced into the main body 1, it is discharged out of the main body again.

As a result, the above-described process is continuously repeated to collect the contaminants.

However, as described above, the cyclone dust collector provided in the extension tube of the vacuum cleaner also causes problems as described below due to its configuration characteristics.

That is, in the process of introducing air and contaminants into the cyclone body, the inflow direction thereof becomes a tangential direction in the cyclone body, and the flow direction of the air discharged out of the cyclone body is again in relation to the inflow direction of the air. As the reverse flow occurs instantaneously during the entire flow of air, such as toward the tangential direction, it causes a sudden pressure drop.

This pressure drop caused a problem that greatly reduced the dust collection efficiency and noise.

In addition, due to the above problems, there is also a problem that can not maintain a constant suction rate.

In addition to the above problems, in general, contaminants such as fine dust particles should be smoothly collected among various contaminants sucked into the vacuum cleaner. However, the structure of the conventional cyclone dust collector as described above may include the fine contaminants. Dust collection is not performed smoothly, but the problem of being discharged back to the room also occurred.

The present invention has been made in order to solve the above-mentioned conventional problems, by providing a cyclone dust collector in which the flow direction of air in the forward direction of the extension pipe constituting the vacuum cleaner to reduce the overall pressure to reduce the noise to reduce noise In addition, the purpose is to be able to maintain a constant suction rate of the vacuum cleaner.

In addition, another object of the present invention to remove the various contaminants contained in the air sequentially according to the size in the process of passing through the cyclone dust collector provided in the vacuum cleaner, and even fine contaminants that could not be removed The purpose is to be able to remove it completely.

1 is an exploded perspective view showing a conventional general vacuum cleaner

2 is a cross-sectional view taken along line II of FIG. 1.

Figure 3 is a sectional view of the main part showing a state where the cyclone dust collector is provided in the extension tube of the conventional vacuum cleaner

Figure 4 is an exploded perspective view showing an exploded first embodiment of the dust collecting means according to the present invention

5 is a sectional view showing the principal parts of a first embodiment of a dust collecting means according to the present invention coupled to an extension tube of a vacuum cleaner;

Figure 6 is an exploded perspective view showing an exploded second embodiment of the dust collecting means according to the present invention

7 is a sectional view showing the principal parts of a second embodiment of the dust collecting means according to the present invention coupled to an extension tube of a vacuum cleaner;

8 is an exploded perspective view showing main parts of a third embodiment of the present invention;

9 is a sectional view showing the main parts of a state in which a filter according to a third embodiment of the present invention is coupled to a dust collecting means.

Explanation of symbols for main parts of the drawings

200. Dust collection means 210. Cyclone body

220. Air inlet 230. Swirl flow grant means

240. Air discharge line 250. Pollutant discharge line

260. Pollutant Dust Collector 271. Air Filter

280. Euro guide 290. Primary air outlet

371. Metal Filters 372. Filter Structures

372a. Communication holes 375. Filter guide

According to an aspect of the present invention for achieving the above object, the main body is provided with a suction force generating means to generate a suction force therein, the inside and one end of the main body is connected to receive the suction force generated in the main body A vacuum cleaner comprising a suction hose, a handle portion attached to the other end of the suction hose, an extension tube detachably connected to the handle portion, and a suction port detachably connected to the other end of the extension tube. The extension pipe is divided into two parts, and between each of the divided pipes is provided with dust collecting means for collecting contaminants by the cyclone principle so that the air flows in the forward direction and the air is also discharged in the forward direction. There is provided a dust collecting device for a vacuum cleaner.

Hereinafter, with reference to Figures 4 and 5 showing a first embodiment of the present invention in more detail.

Figure 4 is an exploded perspective view showing an exploded view of the first embodiment of the dust collecting means according to the present invention, Figure 5 is a sectional view showing the main portion of the first embodiment of the dust collecting means according to the present invention coupled to the extension tube of the vacuum cleaner, According to the present invention, the extension pipe constituting the vacuum cleaner is divided into two parts, and the inflow of the air between each of the divided extension pipes 51 and 52 is in the forward direction and the discharge of the air is also continuously in the forward direction. It is to be provided with a dust collecting means 200 for collecting dust using the principle.

That is, one end of the dust collecting means is connected to an extension tube (hereinafter referred to as a “first extension tube”) 51 on the side connected to the suction port 6, and an extension tube on the side connected to the handle part 4 (hereinafter, “ And the other end of the dust collecting means.

At this time, the dust collecting means is a cyclone body 210 provided to form a forward direction between each of the extension pipes 51 and 52 along the same direction with respect to the direction of each extension pipe 51, 52, and the An air inlet 220 which is detachably provided in the first extension pipe 51, which is an air inlet side of the cyclone body, into which air and contaminants are introduced into the cyclone body 210, and an air inlet side of the cyclone body Is provided in the pivot flow granting means 230 for imparting a turning force to the air and contaminants introduced into the cyclone body 210 through the air inlet, and the second extension pipe 52 constituting the vacuum cleaner is detachably provided Air is discharged into the cyclone body 210, the air discharge pipe 240 is discharged, and the circumferential surface of the side where the air discharge pipe 240 is located among the cyclone body is provided by the swirl flow grant means Clone body (210) Contaminant discharge pipe 250 for discharging the contaminants separated from the air while turning in the inside, and a contaminant dust collector 260 is provided to be separable in the contaminant discharge pipe to collect the contaminants discharged through the contaminant discharge pipe.

In the air inlet 220 is an inlet body 221 coupled to the cyclone body 210 and the air inlet pipe 222 connected to the first extension pipe 51 in a state formed integrally with the inlet body. It is composed of

In addition, the swirl flow imparting means 230 is generally any shape as long as it can impart a turning force to the air in the process of passing air, but the flow of air can be made smoothly to the air and contaminants It is more preferable to configure a spiral blade so as to give a smoother turning force.

Then, the cyclone body 210, the air inlet 220, the swirl flow imparting means 230 and the contaminant dust collector 260 is configured to be separated from each other to clean the dust collecting means 200 by smoothly It is desirable to be able to perform the wash.

At this time, the upper surface of the contaminant dust collecting container 260 is provided with a cover 261 to selectively close or open the internal space of the contaminant dust collecting container can be a smooth operation during discharge of contaminants.

In this case, it is preferable to use the fastening means such as screws and hooks so that the connection can be made more firmly so that the mutual connection does not easily fall.

The operation of the general vacuum cleaner among the operations of the present invention configured as described above will be omitted since the detailed description thereof will be omitted, and the operation process according to the present invention will be described in detail later. .

First, when the power is applied to the vacuum cleaner according to the user's needs, the handle part 4 constituting the vacuum cleaner is held and the suction mode of the controller part (not shown) provided in the handle part is selected. , While the motor 7 installed in the main body 1 is driven to rotate the fan 8, the suction force is generated by the rotation of the fan as described above.

When the suction force is generated in this way, the user performs the cleaning by placing the suction port 6 at the position to be cleaned using the handle 4.

Therefore, various contaminants such as dust and the like are sucked into the suction port 6 together with air by the suction force transmitted through the suction port, and the sucked contaminants are connected to the handle part 4 via the first extension pipe 51. It flows to the second extension pipe (52) side.

At this time, as the dust collecting means 200 using the cyclone principle is provided between the first extension pipe and the second extension pipe, air and various contaminants flowing through the first extension pipe are collected as shown in FIG. 5. It is introduced into the inlet body 221 through the air inlet pipe 222 of the air inlet 220 constituting the means.

As described above, air and various contaminants introduced into the inlet body 221 pass through the swirl flow granting means 230 provided between the inside of the inlet body and the cyclone body 210. The turning force is generated under the guidance of the spiral blade constituting the imparting means.

Accordingly, the air and the various contaminants passing through the swirl flow granting means 230 are rotated along the circumferential surface of the cyclone body 210 to flow to the side where the air discharge pipe 240 is located.

Various contaminants are separated from the air by the above process, and the various contaminants thus separated are circumferentially formed around the cyclone body 210, which is the side of the air discharge pipe 240 in the process of turning on the inner wall of the cyclone body 210. The dust is collected in the pollutant collecting container 260 separately provided through the pollutant discharge pipe 250 formed on the surface.

At this time, the various contaminants can be separated from the air by the mass difference between the air and the various contaminants, which have been described in the prior art, so a detailed description thereof will be omitted.

In addition, the air from which the various contaminants are separated as described above is discharged to the second extension pipe 52 through the air discharge pipe by the suction force transmitted from the inside of the main body 1 of the vacuum cleaner through the air discharge pipe 240, As described above, the air discharged to the second extension pipe 52 is discharged back into the room through the same process as the conventional vacuum cleaner.

The configuration of the dust collector according to the present invention as described above, as the flow direction of the air and contaminants sucked through the suction inlet 6 constituting the vacuum cleaner is made only in the forward direction eventually, to prevent a sudden drop in pressure Being able to understand is understandable.

On the other hand, despite the configuration as in the present invention, contaminants having a relatively small size among various contaminants sucked by the vacuum cleaner may pass through the dust collecting means 200 without dust collection.

Accordingly, the air discharge side (hereinafter referred to as “filter mounting portion”) 274 of the dust collecting means 200 can be attached to and detached from a separate filter in communication with the air discharge pipe 240 to collect the fine dust as described above. It is preferable to further include a filter structure 272 to be seated.

At this time, the filter is composed of an air filter (271) used in automobiles, such that a smooth dust collection, such as relatively fine dust can be made.

The air filter 271 is mainly configured as a filter configured to collect various foreign substances therein while the air is discharged through the circumferential surface in the tangential direction of the air inflow direction as shown in the arrow of FIG. 5. It is used to collect fine dust.

In addition, the air filter 271 as described above should be detachable from the outside in order to facilitate the frequent cleaning and replacement of the filter guide portion 274 to guide the removal of the filter structure 272 smoothly guide guide 273 To form.

At this time, the filter structure 272 inserted into the filter mounting portion through the guide guide 273 is an air discharge pipe 240 in which the bottom surface of the air filter 271 seated in the filter structure constitutes the dust collecting means 200. It should be configured to communicate with the air discharge side of, and should be configured so that the suction force can be transmitted through the outer peripheral surface of the air filter 271 inserted into the filter structure.

Therefore, air and fine dust discharged through the air discharge pipe 240 of the dust collecting means is discharged only air in the process of passing through the outer peripheral surface of the air filter by the suction force transmitted along the outer circumference of the air filter 271 And fine contaminants can be collected by the air filter.

At this time, the upper surface of the air filter is closed, and the lower surface of the air filter is in communication with the air discharge pipe 240 of the dust collecting means 200, the fine dust must be the only outer peripheral surface of the air filter 271 Passing is understandable.

On the other hand, in the filter mounting portion 274 may be configured separately from the dust collecting means 200, one end of the dust collecting means, that is coupled to the side provided with the air discharge pipe 240, or of the dust collecting means As this may be formed integrally at one end, limitation to this is not done.

As a result, when the cleaning is completed by each process of the vacuum cleaner as described above, the pollutant collecting container 260 constituting the dust collecting means 200 and the air filter 271 provided on the air discharge side of the dust collecting means are separated, respectively. By removing the various contaminants collected.

At this time, the contaminant dust collecting container is simply inserted into the contaminant discharge pipe 250 constituting the dust collecting means 200, and thus can be separated smoothly. Also, the filter structure 272 of the air filter 271 also has a drawer shape. As a result of being inserted into the filter mounting portion 274 along the guide guide 273 formed at the filter mounting portion 274, smooth separation is possible.

Meanwhile, the turning force is primarily applied to the air and contaminants introduced into the cyclone body 210 through the air inlet to the air discharge side of the air inlet 220 in the cyclone body 210 constituting the dust collecting means 200. It may further be provided with the flow path guide 280 which forms a part of spherical shape as a whole.

This is to allow a smoother separation of air and various contaminants by allowing the air and various contaminants sucked into the dust collecting unit 200 to make a predetermined turning from the moment of introduction thereof.

At this time, the air discharge direction of the flow path guide is configured to face the circumferential surface inside the cyclone body 210, it is possible to generate a more smooth swirl flow.

It is understood that the flow path guide 280 provided as described above can be used not only by itself but also with a structure for generating a separate swirl flow, such as the swirl flow granting means 230, and preferably As described above, the flow guide 280 and the swirl flow imparting means 230 may be provided at the same time.

On the other hand, according to the second embodiment of the dust collecting means according to the present invention, it is possible to remove each of the various pollutants collected in sequence according to the size, so that a smooth dust collection can be carried out, and the discharge also to the type of pollutants Therefore, each of them can be separated and discharged.

That is, according to the second embodiment of the present invention, as shown in FIGS. 6 and 7, an additional air discharge pipe (hereinafter, ““) is provided on the air inlet side of the dust collecting unit between the air inlet unit 220 and the swirl flow granting unit 230. The first air discharge pipe ”(290) is further provided so that relatively large particles of contaminants are collected in the air inlet 220 without being discharged into the cyclone body.

The primary air discharge pipe 290 is formed to form the shape of the other hole formed with a plurality of through holes 291 along the outer circumferential surface of the air and various contaminants introduced into the air inlet 220 through the air inlet pipe 222 The air and the fine dust can be smoothly discharged to the swirl flow imparting means 230 through each through hole 291 of the primary air discharge pipe 290 and at the same time the relatively large particles of contaminants constitute the air inlet It is to be collected in the inlet body (221).

In this case, the air inlet 220 and the contaminant dust collecting container 260 constituting the dust collecting means 200 may be separated from each other so as to perform their respective roles, but it is collected in the air inlet. In order to be able to discharge various contaminants collected in the contaminants or the contaminant dust collector 260 having relatively large particles at a time, it is preferable to integrate the air inlet and the contaminant dust collector with each other.

At this time, the interior of the air inlet unit integrated as described above and the inside of the contaminant dust collector 260 should be partitioned with each other, in order to prevent the dispersion of air flow due to the mutual communication.

In addition, by providing a cover 261 to the top of the contaminant dust collector 260 to selectively close or open the internal space of the contaminant dust collector can be smoothly performed during the discharge of contaminants.

In the description of the operation according to the second embodiment of the present invention configured as described above, the same parts as the operation of the first embodiment will be omitted in more detail by explaining the operation of the second embodiment of the present invention in detail.

First, as shown in FIG. 7, air and various contaminants flow through the suction port 6 and the first extension pipe 51 by the suction force generated as the user operates the vacuum cleaner, thereby configuring the dust collecting means 200. Is introduced into the air inlet 220 through the air inlet pipe 222.

In this process, as the flow guide 280 is formed at the air discharge side of the air inlet pipe 220, which is inside the air inlet, the air passing through the air inlet pipe is flow-through by the flow guide 280. As the guided state is discharged to the inner wall surface of the air inlet 220 to make a turn.

In this case, as the continuous suction force is transmitted through the primary air discharge pipe 290 provided inside the air inlet, air and various contaminants turning in the air inlet 220 may be reduced by the suction force. Passed through each through-hole 291 formed in the primary air discharge pipe 290 is discharged into the cyclone body 210.

At this time, each of the through holes 291 formed in the primary air discharge pipe is formed so that the size is not so large, contaminants smaller than the size of each of the through holes through each of the through the cyclone body 210 Although it may be discharged, contaminants and the like larger than the size of the through hole are primarily maintained in the state in the inlet body 221 constituting the air inlet 220.

In addition, as the primary air discharge pipe 290 is formed in the other hole, the through hole 291 is partially interfered with the suction force by various contaminants collected in the air inlet 220. Even if it does not have a big influence on the overall suction force it is understood that the transmission of the suction force through the primary air discharge pipe 290 can be carried out smoothly continuously.

On the other hand, the air from which the first large particles are removed by the above process is sucked into the cyclone body 210, the sucked air is a swirl flow imparting means provided on the air inlet side in the cyclone body ( 230, that is, the turning force is applied in the process of passing through the spiral blade, and the centrifugal force is generated in various contaminants while turning along the circumferential surface of the cyclone body.

Accordingly, various contaminants are separated from the air, and the various contaminants thus separated are contaminated through the contaminant discharge pipe 250 formed on the circumferential surface of the cyclone body 210 in the process of turning on the inner wall surface of the cyclone body 210. Secondary dust is collected in the contaminant dust collecting container 260 provided separately.

At this time, the various contaminants can be separated from the air by the mass difference between the air and the various contaminants, which have been described above, so a detailed description thereof will be omitted.

In addition, the air from which the various contaminants are separated as described above is an air filter 271 provided in the filter mounting part 274 constituting the dust collecting means 270 through the air discharge pipe 240 provided in the cyclone body 210. In this process, ultra-fine dust and the like contained in the air are removed by the air filter, and only air is discharged to the second extension pipe 52.

As described above in the first embodiment, the process of removing the ultra fine dust discharged through the air discharge pipe 240 by the air filter 271 will be omitted.

When the cleaning is completed as described above, the user separates the air inlet 220, the contaminant dust collector 260 and the air filter 271 from the cyclone body 210 constituting the dust collecting means 200, respectively The various pollutants collected in the interior may be discharged.

At this time, the contaminant dust collector and the inlet body 221 of the air inlet portion is configured to be integrated with each other, so that it is understood that the user can more smoothly discharge during the discharge of contaminants collected in each interior. .

On the other hand, the third embodiment of the dust collecting means according to the present invention relates to a dust collecting apparatus to which a filter of a different type from the air filter in each of the above-described embodiments is applied.

That is, as shown in FIG. 8 and FIG. 9, the filter 371 according to the third embodiment of the present invention has a metal mesh shape as a whole.

The filter may be made of the same material as the nonwoven fabric, but such a material should be frequently replaced since only the cleaning operation of dusting off various fine dusts on the filter may be performed to clean the filter after dust collection is completed. This is because there is a problem that requires a lot of maintenance costs accordingly.

Therefore, in the present invention, by using the above-described mesh-shaped metal filter 371, it is possible to clean the water, it is possible to achieve a reduction in maintenance costs by being able to continue to recycle.

At this time, the mesh-shaped metal filter is preferably formed so as to be able to improve dust collection performance by increasing the contact area with the discharged air by forming a plurality of bends.

In this case, the shape of the filter structure 372 mounted on the filter mounting part 274 may be simplified in each of the above-described embodiments.

That is, the communication hole 372a is formed at one side of the filter structure 372 so as to communicate with the air discharge pipe 240 of the dust collecting means 200, and the other side thereof may be formed only in a completely open cylindrical shape.

Further, the metal filter 371 according to the third embodiment of the present invention is configured to close the open side of the filter structure when coupled to the cylindrical filter structure 372.

It is understood that this is to allow the fine dust in the air discharged through the air discharge pipe 240 to be completely collected by the metal filter 371.

In this case, the metal filter is formed between the one side of the filter structure and the metal filter by forming a spaced distance (d) from one side of the filter structure 372, the communication hole 372a is formed 372 The inner space of) is used as a separate dust collector.

In addition, the filter structure 372 according to the third embodiment of the present invention described above may be simply mounted in the filter mounting portion 274 in its own shape, but has a separate filter guide 375 as shown. It is more preferable to configure the filter structure 372 to be smoothly attached and detached from the filter mounting portion 274.

Accordingly, in the process of discharging air including fine dust through the air discharge pipe 240, it passes through the communication hole 372a of the filter structure 372 provided with the mesh-shaped metal filter 371 to the inside of the filter structure. In the process of passing through the metal filter 371 by the suction force, the fine dust is caught by the mesh-shaped metal filter and collected in the interior space of the filter structure 372. Only air passes through the metal filter to remove the fine dust. It is discharged through the two extension pipe (52).

Then, when all cleaning is completed, the user simply removes the filter structure 372 mounted on the dust collecting container 260 and the filter mounting part 274 constituting the dust collecting means 200, and various foreign substances and filters inside the dust collecting container. The fine dust in the structure 372 may be discharged.

At this time, the filter 371 provided in the filter structure may be rinsed with water according to the needs of the user since the material is made of metal.

On the other hand, the dust collecting means according to the present invention is the most preferred form to be configured in a state coupled to each of the extension pipes 51, 52 by dividing the extension pipes as shown in the embodiment, respectively, but the extension pipe as described above Even if not divided, it can be provided between the suction port and the extension tube, and can be provided between the extension tube and the handle portion, and can also be provided as a useful invention that can be applied to the suction hose.

As described above, the present invention allows the flow direction of air between the extension tubes of the vacuum cleaner to achieve a continuous forward direction and at the same time to provide a dust collector capable of separately collecting only contaminants to prevent a sudden pressure drop. do.

The pressure reduction prevention as described above not only generates the effect of reducing the noise, but also has the effect of keeping the suction rate constant at all times.

In addition, as the configuration of the dust collecting means is configured to achieve multiple dust collection, it is possible to perform more smooth cleaning, thereby improving the reliability of the user.

Claims (12)

A main body provided with a suction force generating means so as to generate a suction force therein, a suction hose connected to the inside and one end of the main body to receive a suction force generated in the main body, and a handle part attached to the other end of the suction hose; In the vacuum cleaner having an extension pipe detachably connected to the handle portion, and the suction inlet body detachably connected to the other end of the extension pipe, The dust collecting means which divides the extension pipe which comprises the said vacuum cleaner into two parts, and collects contaminants by the principle of a cyclone so that the inflow of air may be forward and the air may also be forward between each divided extension pipes. Dust collector of a vacuum cleaner, characterized in that provided with. The method of claim 1, The dust collecting means includes a cyclone body provided to make a forward direction with respect to the direction in which the extension pipe is directed; An air inlet part detachably provided in an extension tube connected to an inlet port, which is an air inlet side of the cyclone body, to introduce air and contaminants into the cyclone body; A swirl flow grant means provided on the air inlet side of the cyclone body to impart swirling force to air and contaminants introduced into the cyclone body through the air inlet; An air discharge pipe detachably provided in an extension pipe positioned on a main body side of the vacuum cleaner, through which air flows through the cyclone body; Contaminant discharge pipe is provided in place on the circumferential surface of the side of the cyclone body in which the air discharge pipe is located, the pollutant discharge pipe is discharged while the pollutant separated from the air is discharged while turning in the cyclone body by the swirl flow grant means; Dust collector of the vacuum cleaner, characterized in that provided with a contaminant dust collector is separable in the pollutant discharge pipe to collect the pollutant discharged through the pollutant discharge pipe. The method of claim 2, The swirl flow imparting means is a dust collecting device of a vacuum cleaner, characterized in that the spiral blade (spiral blade). The method of claim 2, A dust collector of the vacuum cleaner, characterized in that it further comprises a filter structure having a separate filter in communication with the air discharge pipe to collect fine dust in the air discharged to the air discharge side of the dust collecting means. The method according to any one of claims 2 and 4, The dust collecting device of the vacuum cleaner, characterized in that the guide structure is formed on the air discharge side of the dust collecting means is guided from the side to be detachably coupled. The method of claim 4, wherein The filter is a dust collector of the vacuum cleaner, characterized in that configured to discharge the air toward the tangential direction of the air inflow side, such as a car air filter. The method of claim 4, wherein Dust collecting device of the vacuum cleaner, characterized in that the filter is made of a metal mesh. The method of claim 7, wherein The dust collecting device of the vacuum cleaner, characterized in that the metal filter bent a number of times to form a larger dust collecting area. The method of claim 2, Further comprising a flow path guide forming a part of the spherical shape as a whole to give a primary turning force to the air and contaminants introduced into the cyclone body through the air inlet to the air discharge side of the cyclone body constituting the dust collecting means Dust collector of a vacuum cleaner, characterized in that the. The method of claim 9, Dust collecting device of the vacuum cleaner, characterized in that the air discharge direction of the flow guide is configured to face the circumferential surface inside the cyclone body. The method of claim 2, It is further provided with a perforated tube formed with a plurality of through-holes along the outer circumferential surface between the swirl flow granting means provided in the cyclone body and the air inlet, so as to achieve the preferential dust collection of various contaminants introduced in the air inlet. Dust collector of vacuum cleaner made with. The method according to any one of claims 2 to 11, Integrating the contaminant dust collector provided in the cyclone body and the air inlet portion in which the dust collection is primarily performed in a state separated from each other so as to discharge various contaminants collected in the air inlet and the contaminant dust collector at once. Dust collecting device of the vacuum cleaner, characterized in that.