RU2181253C2 - Vacuum cleaner with cyclone-type dust-collection apparatus - Google Patents

Abstract

FIELD: vacuum cleaners. SUBSTANCE: vacuum cleaner includes cyclone apparatus for dust collection arranged along other axis relative to extension branch pipe joining main housing of vacuum cleaner with suction air-intake device. Such cyclone apparatus is designed for collecting duct in the form of comparatively large particles to be sucked through suction air-intake device together with air by action of centrifugal force. Cyclone apparatus includes housing of cyclone collector having first and second connection pipes joined with extension branch pipe of vacuum cleaner. At one side of cyclone dust collector there is air inlet opening joined with first connection pipe. Air discharge opening is provided on other side of cyclone collector and it is joined with second connection pipe. Housing of cyclone collector is designed for creating turbulence air flow of sucked air. Dust trap is built in housing of cyclone collector and it is designed for trapping dirt separated from air by means of turbulence air flow in housing of cyclone collector. Dust-separating grate is flared downwards from air inlet opening and it is closed at lower end. Grate has large number of fine passing holes in order to prevent dirt penetration together with air flow through air discharge opening. In lower end of grate there is member for holding dust raised together with air by means of rising air flow before dust-separating grate; it provides secondary settling of dust. Dust trap is removably mounted on housing of cyclone collector with use of fixing member. EFFECT: improved design allowing to empty dust trap only at partial separation of cyclone apparatus from extension branch pipe of vacuum cleaner. 10 cl, 12 dwg

Description

Field of Invention
The present invention relates to a vacuum cleaner and, in particular, to a vacuum cleaner with a cyclone dust collecting device, which mainly collects and collects dirt or dust in the form of relatively large particles or dirt in the form of pieces of toilet paper, vinyl and hair.

Description of the prior art
A typical vacuum cleaner, as shown in FIG. 1, includes a main body 1 of the vacuum cleaner, a connecting hose 2 connected to the main body 1, several extension pipes 3 connected to the connecting hose 2, and a suction air intake 4 connected to the end of the extension pipe 3. The cover 5 is mounted on the main body 1 and can be opened or closed, and the connecting hose 2 is connected to the cover 5. The dust collection chamber 6 is located inside the main body 1, and the paper filter 7 for collecting dirt or dust is placed in dust collection chamber 6 and can be removed as necessary. Number 8 represents a pen.

 A typical vacuum cleaner, as described above, sucks in dirt along with intake air through the intake air intake 4 under the action of the suction force of an electric motor (not shown) installed inside the main body 1. The intake air and dirt enter the main body 1 through extension pipes 3 and a connecting hose 2. In the main body, dirt is collected in the paper filter 7 in the dust collection chamber 6 of the main body 1, and the incoming air is discharged outside from the main body 1 of the vacuum cleaner through the paper filter 7.

 In a typical vacuum cleaner, as described above, since all dust and dirt sucked in through the intake air intake 4 is collected in one paper filter 7 in the dust collection chamber 6 of the main body 1, the paper filter 7 is quickly filled with dirt. When filling the paper filter 7 with dirt, the suction force decreases, and the motor may be overloaded. For this reason, a conventional vacuum cleaner is inconvenient, since the paper filter 7 must often be replaced.

 To solve the above problem, a vacuum cleaner with a cyclone dust collection device has been proposed. A cyclone collector is a device for separating particles from a stream using centrifugal force. This device has a simple design and is able to withstand high temperatures and pressures. It is widely used as a dust collector in industry and is used in a vacuum cleaner.

 Such a vacuum cleaner with a cyclone dust collector is designed primarily to trap and collect dirt in the form of relatively large particles that are sucked in through the intake air intake before the dirt enters the paper filter in the main body of the vacuum cleaner. Thus, the amount of dirt collected in the paper filter can be reduced, and the paper filter can be used for a longer time period. In addition, the advantage of this design is to prevent a decrease in the suction force and overload of the motor.

 Examples of a vacuum cleaner with a cyclone dust collector, as described above, are vacuum cleaners according to the patent of the Republic of Korea 1993-4891 called a vacuum cleaner with a cyclone collector and according to the patent of the Republic of Korea 1993-5099 called a vacuum cleaner.

 In the design of the first (93-4891) vacuum cleaner, a cyclone trap that separates and collects dirt is located coaxially with respect to the connecting tube of the vacuum cleaner. The cyclone collector has an outer tube, an inner tube located in the outer tube, a loading funnel placed at the bottom of the inner tube, a suction hose to connect the vacuum cleaner cover to the outer tube, a swirl detection device passing through the inner tube and the upper part of the outer tube, and an inlet a cyclone trap hole formed on one side of the outer tube. In such a vacuum cleaner, dirt in the form of large particles, sucked through the intake air intake, is captured and collected in a cyclone collector, and thus the amount of dust collected in the paper filter in the main body of the vacuum cleaner is reduced.

 In the design of the second (93-5099) vacuum cleaner, a cyclone trap that separates and collects dirt is located on the connecting pipe that connects the main body of the vacuum cleaner to the intake air intake. The device for separating and collecting dirt has a casing that has first and second dust collection chambers inside the casing, a swirl detection device formed on the upper part of the casing, a connecting link formed in the lower part of the casing and connected to the first dust collecting chamber, a cyclone separator, which located inside the casing and has a conical structure, the inner diameter of which gradually decreases from the upper part to the lower part of the conical structure, a loading funnel, which is combined with the lower It has a cyclone separator and has a conical structure, the inner diameter of which gradually increases from the upper part to the lower part of the conical structure, an inlet filter that is combined with the central part of the cyclone separator and separates the first dust collection chamber from the second dust collection chamber, a filter that is combined with the upper part of the cyclone separator and divides the second dust collection chamber into two parts, and a swirl absorber formed at the bottom of the cyclone separator. Such a vacuum cleaner also collects and collects dirt in the form of large particles, which is sucked through the intake air by a device for separating and collecting dirt, and thus reduces the amount of dust collected in the paper filter in the main body of the vacuum cleaner.

 However, in conventional vacuum cleaners with a cyclone dust collector, as described above, since the cyclone collector (or device for separating and collecting dirt) is placed coaxially on the extension pipe of the vacuum cleaner, then to remove dirt collected inside the cyclone collector or device for separating and collecting dirt, he (or it) must (o) be completely disconnected (o) from the extension pipe of the vacuum cleaner.

 In addition, the cyclone trap or device for separating and collecting dirt from a conventional vacuum cleaner with a cyclone dust collector has a complex structure, causing difficulties in the production process and increasing production costs.

SUMMARY OF THE INVENTION
It is an object of the present invention to provide a vacuum cleaner with a cyclone dust collecting device that can conveniently remove dirt collected in a dust collecting device without completely separating the cyclone dust collecting device from the extension of the vacuum cleaner.

 Another objective of the present invention is the development of a vacuum cleaner with a cyclone dust collection device, which has a simple design that ensures manufacturability and profitability of mass production due to the low cost of production.

 To achieve the above objectives, the vacuum cleaner of the present invention has a cyclone dust collecting device, which is placed on an extension pipe connecting the main body of the vacuum cleaner to the intake air intake, separating and collecting dust and dirt in the form of relatively large particles sucked through the intake air intake by centrifugal force. The cyclone dust collector is placed on a different axis relative to the extension of the vacuum cleaner so that it is possible to remove dirt collected by the cyclone dust collector without completely separating the cyclone dust collector from the extension nozzle.

 The cyclone dust collector includes a cyclone body with first and second connecting tubes connected to an extension pipe of the vacuum cleaner, a dust collector combined with a cyclone body and replaceable, and fixing means for securing the dust collector.

 The cyclone body is divided into the upper part of the body and the lower part of the body, and the upper and lower parts of the body are connected together by several screws. An air inlet communicating with the first connecting tube is formed in the lower part of the housing, and an air outlet communicating with the second connecting tube is formed in the upper part of the housing. The first connecting pipe is connected to an extension pipe near the suction inlet of the vacuum cleaner, and the second connecting pipe is connected to an extension pipe near the main body of the vacuum cleaner. Dirt-containing air drawn in through the suction inlet of the vacuum cleaner passes through the air inlet of the cyclone body in an oblique direction with respect to the cyclone body so that the vortex air is excited inside the cyclone body. Using this vortex airflow, the dirt contained in the air is separated from the air by centrifugal force and then collected in a dust collector, and the air begins to reverse upward movement from the base and is discharged through the air outlet.

 In this case, dust can rise up along with air through the air outlet of the cyclone body. To prevent this, the cyclone dust collecting device of the present invention is provided with a dirt separating grate having a plurality of tiny transmission openings and expanding downward from an air outlet of the cyclone collector body such that air rising in the dust collector passes through the tiny transmission openings, while the dirt particles which are larger than the diameter of the smallest transmission holes, cannot pass through the smallest transmission holes and are re-deposited and collected dust collector.

 In addition, an anti-mud agent for retaining dirt rising with the air before it reaches the dirt separating grate and subsequently settling it is formed at the bottom of the dirt separating grate. As a result, dirt in the form of pieces of toilet paper cannot completely rise to the upper part of the cyclone trap body; it is delayed and re-deposited. In this way, it is possible to significantly reduce the amount of dirt that flows through the smallest passing holes of the dirt separating grate and to prevent clogging of the smallest passing holes of the dirt separating grate, such as, for example, pieces of toilet paper.

 The anti-mud agent may be in the form of an anti-mud plate having a conical shape with a diameter of the lower part greater than the diameter of the upper part, and may be formed at the lower end of the dirt-separating grate and combined with it or may be in the form of an additional conical anti-mud rotating plate placed at the bottom of the dirt separating lattice with the possibility of rotation under the action of a swirling air flow. Moreover, an additional anti-mud element may be placed at the bottom of the anti-mud plate or anti-mud rotary plate. The additional anti-mud element may be a brush and has an expanding shape with the same angle as the downward-expanding portion of the anti-mud plate or anti-mud rotating plate.

 At the same time, the dust collector may have a cylindrical shape and be sufficiently solid and not break when exposed to external factors. The supporting element for fixing the dust collector to the extension pipe is placed on one side of the lower part of the dust collector for combining them into a single whole. The support element is inserted into the sliding groove of the retaining ring, which should be fixed on the extension pipe, and connected to the cyclone body when combining the upper part of the dust collector with the cyclone body using fixing means. The dust collector may be in the form of a cylinder with a given diameter or may have a shape that decreases in the lower part, that is, the diameter of which decreases with the transition from the upper part to the lower part. In addition, the dust collector may have a shape increasing in the lower part, that is, in which the diameter of the lower part is larger than the diameter of the upper part. In the case of the lower part of a larger cylindrical shape, the speed of rotation of air in the dust collector may decrease when it enters the lower part, and thus the counterflow of dirt is prevented. A dust collector with an expanded shape of the lower part has a first cylindrical part which is formed in the upper part and a second cylindrical part which is formed in the lower part and has a diameter larger than the diameter of the first cylindrical part. Accordingly, the air sucked into the dust collector rotates in the first cylindrical part at a relatively high speed to effectively separate the dirt, and in the second cylindrical part the air rotates at a lower speed. Thus, it is possible to minimize the amount of dirt that rises with a swirling air stream. The second cylindrical part may have a shape in which the diameter of the lower part becomes larger than the diameter of the upper part or may have the shape of a straight cylinder whose diameter is larger than the diameter of the first cylindrical shape.

 The locking means has a pair of suspension holes formed on both sides of the lower part of the housing; a pair of clamps that are pivotally fixed to a pair of support elements of the clamps formed on both sides of the upper part of the dust collector, which are combined into one, and having hooks at their ends that engage with the holes of the suspension; and a spring, which is located between the inner part of the rear side of the latch and the supporting element of the latch of the dust collector and springs the latch in one direction. At the same time, each latch is spring-loaded in the direction in which the latch hook engages with the suspension hole on the lower part of the housing. Thus, if the dust collector is inserted into the lower part of the cyclone trap body, the latch hook engages with the suspension hole, and thus the dust collector is combined with the cyclone trap body as a whole. To separate the dust collector from the cyclone trap body, push and pull both locks. In this case, the hooks of the clamps are released from the holes of the suspension on the lower part of the housing, and the supporting element on the lower part of the dust collector is released from the locking ring on the extension pipe. Accordingly, for convenient removal of dirt collected in the dust collector, only the dust collector can be separated.

 According to a preferred embodiment of the invention, a cyclone dust collecting device for separating and collecting relatively large particles and dirt sucked through the intake air intake by centrifugal force is arranged on a different axis relative to the extension pipe. The cyclone dust collector includes a cyclone body with first and second connecting tubes connected to an extension pipe of the vacuum cleaner, an air inlet communicating with the first connecting pipe and formed on one side of the cyclone collector, and an air outlet communicating with the second connecting pipe and formed on the other side cyclone trap, and serves to excite the vortex air flow; a dust collector, which is combined with the housing of a cyclone trap with the possibility of replacement, to collect dirt separated from the air; a dirt separating grate, which has a shape extending downward from the air outlet of the cyclone body and the tiniest of many holes to prevent dirt from flowing to the air outlet of the cyclone body together with air; an anti-mud block, which is placed at the lower end of the dirt-separating grate and traps dirt that rises with the air in an ascending air stream before the dirt reaches the dirt-separating grate and re-precipitates it; and a fixing device that secures the dust collector and provides the ability to separate the dust collector from the cyclone body.

 In accordance with the above description, since the cyclone dust collector mainly collects and collects dust or dirt in the form of relatively large particles or dirt in the form of pieces of toilet paper or vinyl, the time interval between replacing the paper filter of the vacuum cleaner can be increased.

 In addition, when the dust collector of the cyclone dust collector is filled with dirt, the dirt can be removed by simply separating the dust collector without completely separating the cyclone dust collector from the extension of the vacuum cleaner.

Brief Description of the Drawings
Features and advantages of the present invention will become more apparent from the following detailed description with the accompanying drawings, in which:
FIG. 1 is a perspective view of a typical vacuum cleaner;
figure 2 is a perspective view of a vacuum cleaner with a cyclone dust collection device in accordance with the present invention;
FIG. 3 is an exploded perspective view of a cyclone dust collecting device according to a first preferred embodiment of the present invention;
FIG. 4 is a perspective view of an assembly of a cyclone dust collecting device shown in FIG. 3;
Fig. 5 is a cross-section illustrating the principle of dust collection of the cyclone dust collecting device shown in Fig. 4;
FIG. 6 is an exploded perspective view of a cyclone dust collecting device in accordance with a second preferred embodiment of the present invention;
Fig. 7 is a cross-section illustrating the principle of dust collection of the cyclone dust collecting device shown in Fig. 6;
FIG. 8 is an exploded perspective view of a cyclone dust collecting device according to a third preferred embodiment of the present invention;
Fig.9 is a cross section explaining the principle of dust collection of the cyclone dust collecting device shown in Fig.8;
FIG. 10 is an exploded perspective view of a cyclone dust collecting device in accordance with a fourth preferred embodiment of the present invention;
FIG. 11 is a cross-section illustrating the principle of dust collection of the cyclone dust collecting device shown in FIG. 10; and
FIG. 12 is a cross-sectional view of a cyclone dust collecting apparatus according to a fifth preferred embodiment of the present invention.

Detailed Description of a Preferred Embodiment
A vacuum cleaner with a cyclone dust collecting device according to a preferred embodiment of the present invention is shown in FIG. 3-5.

 Note that the same numbers will be used to refer to similar or equivalent elements having the same functions. A detailed description will therefore, if possible, be omitted and attention will be focused on the distinguishing features of the present invention.

 The following notation is used in the drawings: 1 - main body of the vacuum cleaner, 2 - connecting hose, 3 - extension pipe, 4 - suction air intake, 5 - cover, 6 - dust collection chamber, 7 - paper filter, 8 - handle and 10 - cyclone dust collection device .

 As shown in FIG. 2, the cyclone dust collecting device 10 is connected to an extension pipe 3 that connects the main body 1 of the vacuum cleaner to the intake air intake 4.

 The cyclone dust collection device 10 includes a cyclone trap body 20 with first and second connecting tubes 11 and 12, which are connected to an extension pipe 3, a dust collector 30, removably mounted on the cyclone trap body 20, and a fixing device 40 that secures the dust collector 30 and allows you to separate the dust collector 30 from the housing 20 of the cyclone trap.

 The first and second connecting tubes 11 and 12 of the cyclone trap body 20 are inclined to one side from the center of the cyclone trap body 20. With this design, when the cyclone dust collecting device is connected to the extension pipe 3 of the vacuum cleaner, the center of the cyclone dust collecting device, more precisely, the central axis of the dust collector 30, does not coincide with the axis C1 of the extension pipe 3, but is located on a different axis, as shown in FIG. 5. Thus, in order to remove dirt collected in the dust collector 30, it is not necessary to separate the extension pipe of the vacuum cleaner. As shown in FIG. 2, dirt can be easily removed by separating only the dust collector 30 from the cyclone trap body 20.

 The cyclone trap body 20 is divided into a lower part of the housing 21, which is integrated with the first connecting tube 11, and an upper part of the housing 22, which is combined with the second connecting tube 12, and both upper and lower parts of the housing 22 and 21 are integrated with each other with a few screws 29.

 An air inlet 11a that communicates with the first connecting pipe 11 is located in the lower part of the housing 21, and an air outlet 12a that communicates with the second connecting pipe 12 is located in the upper part of the housing 22. The air inlet 11a and the air outlet 12a are formed by dividing the internal volumes the upper and lower parts of the housing 22 and 21 with curved ribs 22a and 21a, respectively. In addition, several pairs of locking tabs 22b and 21b, each of which has a screw hole, are formed in certain positions opposite each other on the upper and lower parts of the housing 22 and 21. The closed hole 11b and the embedded protrusion 12b for connecting the cyclone dust collecting device to the extension nozzles 3 'and 3' 'are formed on the first and second connecting tubes 11 and 12, respectively, and the embedded protrusion 3'b and the closable hole 3''b, which correspond to the closed hole 11b and the embedded protrusion 12b, are formed on dlinitelnyh nozzles 3 'and 3 ", respectively.

 The first connecting pipe 11 is connected to the extension pipe 3 'near the suction inlet of the vacuum cleaner, and the second connecting pipe 12 is connected to the extension pipe 3 "near the main body of the vacuum cleaner. The dirt-containing air drawn in through the suction intake of the vacuum cleaner enters through the air inlet 11a of the first connecting pipe 11 in an oblique direction relative to the cyclone trap body 20 so that the swirling air flow (shown by arrows in the form of solid lines in FIG. .5) is excited inside the cyclone trap body 20 and dust collector 30. Under the influence of this vortex air stream, dirt in the form of large particles contained in the air is separated from the air and then precipitated, while air is supplied to the main body 1 of the vacuum cleaner through the air outlet 12a of the cyclone trap body 20 with an upward air flow (shown by arrows in the form of dashed lines in FIG. 5) generated at the base and directed upward.

 For detachable fastening of the dust collector 30 to the cyclone trap body 20, a fixing device 40 is used. The dust collector is designed to form a vortex air flow together with the cyclone trap body 20 and collect dirt separated from the air by the centrifugal force of the vortex air flow.

 Typically, the dust collector 30 has a cylindrical shape, but its shape may be different. From the outside, it may have a cylindrical shape decreasing in the lower part, in which the diameter of the lower part is less than the diameter of the upper part.

 In addition, to conveniently check outside the presence of dirt collected inside the dust collector 30, it is preferable to make the dust collector 30 from a transparent material, however, there is no strict need to limit the materials for manufacturing the dust collector 30 to only transparent materials. It is also preferable that the dust collector 30 is made of a material with high strength so that it cannot be easily broken by external influences or when dropped.

 The supporting element 31 for fixing the dust collector 30 on the extension pipe 3 of the vacuum cleaner is formed on one side around the circumference of the smaller radius of the dust collector 30 and serves to connect them into a single whole. The support member 31 is inserted into the sliding groove of the retaining ring 32 located on the extension pipe 3. The supporting member 31 includes a locking protrusion 31b with a suspension fixture that is locked when inserted into the sliding groove 32a of the retaining ring 32, and a guide protrusion 31c that is formed before by the locking protrusion 31b and guides the locking protrusion 31b along the sliding groove 31a upon insertion. The guide protrusion 31c has a special shape and its width becomes narrower from the part near the locking protrusion 31b to the upper part. The locking ring 32 is fixed to the extension pipe 3 with a screw (not shown).

 The locking device 40 includes a pair of holes of the suspension 41, made opposite to each other on both sides of the lower part of the housing 21, a pair of latches 43, which are pivotally mounted on a pair of support elements 42 of the latches located on both sides of the upper part of the dust collector 30, and have hooks 43a, which catch on the holes of the suspension 41 and are located at their ends, and a pair of springs 44, which are placed between the inner part of the rear side of the latch 43 and the supporting element 42 of the latch on the dust collector 30 and spring the latch 43 into one ohm direction.

 The retainer support member 42 is typically U-shaped, and a pair of hinge holes 42a and a spring support protrusion 42b are formed at defined positions, respectively. The latch 43 is rotatably mounted around a projection 43b of the hinge by inserting a pair of projections 43b of the hinge into the holes 42a of the hinge of the locking member 42. A spring-supporting protrusion 43c for securing the spring 44 is formed on the inner surface of the latch 43. In this position, the spring 44 springs the latch 43 in the direction in which the hook 43a engages in the opening of the suspension 41.

 Thus, if the dust collector 30 is inserted into the lower part 21 of the cyclone trap body 20, then the hook 43a of the latch 43 engages the suspension hole 41, and then the dust collector 30 is combined with the cyclone trap body 20. To separate the dust collector 30 from the cyclone trap body 20, both latches 43 must be pressed and pulled. In this case, the hooks 43a of the latches 43 are released from the holes of the suspension 41 on the lower part of the housing 21, and the support element 31 on the lower part of the dust collector 30 is released from the fixing ring 32 on extension pipe 3, and thus it is possible to conveniently remove dirt collected inside the dust collector 30, separating only the dust collector 30.

 The dirt separating grate 50 serves to prevent dust from entering the stream along with the air through the air outlet 12a in the cyclone trap body 20 during operation of the cyclone dust collector. The dirt-separating grill 50 extends downward from the air outlet 12a and has a plurality of tiny transmission openings 50a such that air that rises in the dust collector 30 and passes through the tiny transmission holes 50a, while the dirt particles are larger than the smallest transmission holes, cannot pass through the transmission openings 50a and are re-deposited and collected in the dust collector 30.

 The dirt separating grid 50 has a guiding grid, an upper forming member 51, a conical shaped grating 52, the interior of which is hollow, and a cylindrical grating 53, whose bottom is closed. All these elements are combined into a single whole. The smallest transmission holes 50a are made in the remaining parts of the conical shape of the grid element 52, except for a certain area near the air inlet 11a, and around the entire circumference of the grid element of a cylindrical shape 53.

 The guiding element 51 is supported by curved ribs 22a and 21a formed on the upper and lower parts of the housing 22 and 21 and defining the position of the dirt separating grill 50 and defining the boundaries of the air outlet. The groove of the rib 51a, which includes the curved rib 22a of the upper part of the housing 22, is formed on the edge of the upper surface of the guiding element 51, and the end clamping device 51b, to which the curved rib 21a of the lower part of the body 21 fits tightly, is formed on the other surface of the guiding element .

 In addition, the anti-mud plate 60 of the conical shape, in which the width of the lower part is larger than the width of the upper part, is located at the lower end of the dirt separating grating 50 and is integrated with it.

 The anti-mud plate 60 is used to trap dirt that rises with the air until the dirt separates the dirt grid 50 and re-settles the dirt. In this case, dirt in the form of pieces of toilet paper cannot completely penetrate the upper part of the cyclone trap body 20, but is delayed and re-precipitated, and thus it is possible to significantly reduce the amount of dirt penetrating through the smallest passing holes 50a of the dirt separating grid 50, and possibly also prevent clogging with dirt in the form of, for example, toilet paper, the smallest passing holes 50a of the dirt separating grate 50.

 The following is a description of the action of a vacuum cleaner with a cyclone dust collection device, which was discussed above.

 When applying electric energy, the suction force is excited when the motor rotates in the main body 1 of the vacuum cleaner. Under the influence of this force, dirt in the form of dust enters the cyclone dust collection device through the intake air intake and the first connecting pipe 11 together with the intake air, as shown in FIG. In this case, the air entering the cyclone dust collecting device flows in an oblique direction relative to the cyclone trap body 20 through the air inlet 11a of the first connecting tube 11. Accordingly, the air generates a vortex air flow and is lowered into the lower part of the dust collector 30. In this process, dirt in the form of large particles or dirt, like toilet paper or vinyl, contained in the air, is separated from the air by centrifugal force and is deposited along the inner side wall of the dust container and swirls in the dust collector 30. And when the air begins a reverse upward movement from the base of the dust collector 30 and is directed to the main body 1 of the vacuum cleaner through the air outlet 12a and the second connecting tube 12 with an upward air flow, it rotates around circles of a smaller radius. In this case, the dirt, which is raised together with the air by the ascending air stream, cannot pass through the smallest passing holes 50a of the dirt separating grid 50 and is re-deposited and collected in the dust collector 30. And some of the relatively large particles of dirt fall on the anti-mud plate 60 and then re-deposited and are going. The dust collection and removal process carried out in the main body 1 is the same as in a typical vacuum cleaner.

 When filling the dust collector 30 with dirt that has been separated and collected by such a process, the collected dirt is removed by separating only the dust collector 30 from the cyclone collector body 20, but without separating the cyclone dust collecting device from the extension pipe.

 Fig.6 shows a perspective three-dimensional image with a spatial separation of the details of the cyclone dust collecting device in accordance with the second preferred embodiment of the present invention, and Fig.7 is a cross section explaining the principle of dust collection of the cyclone dust collecting device shown in Fig.6.

 As shown in the drawings, the basic construction of the cyclone dust collecting apparatus according to the second preferred embodiment of the present invention is the same as the first preferred embodiment of the present invention, except that an additional anti-mud rotary assembly is located at the bottom of the dirt separating grid 50 plate 60 'driven by upward rotation of the air.

 The anti-mud rotary plate 60 ', driven by the swirling air flow excited inside the dust collector 30, thus effectively deposits various particles of dirt that hit the anti-mud rotary plate 60'.

 As shown in the drawing, the anti-mud rotary plate 60 'has a conical shape, in which the width of the lower part is greater than the width of the upper part. The protrusion 60a formed in the center of the upper part of the anti-mud rotary plate 60 'is inserted into the axial hole formed in the center of the lower part of the dirt separating grating 50, and thus the anti-mud rotary plate 60' is rotated. The design of such an anti-mud rotary plate 60 'is well known in the art.

 Other structural elements and performance characteristics are the same as in the first preferred embodiment of the present invention, and therefore, their detailed description is not given.

 On Fig shows a perspective three-dimensional image with a spatial separation of the details of the cyclone dust collection device in accordance with the third preferred embodiment of the present invention; and in FIG. 9 is a cross section illustrating the principle of dust collection of the cyclone dust collecting device shown in FIG.

 The cyclone dust collecting device according to the third preferred embodiment of the present invention has an additional anti-mud element 70 for enhancing the action of the anti-mud plate 60.

 The additional anti-mud element 70 can be made in the form of a brush and placed along the edge of the lower end of the anti-mud plate 60. In this design, the additional anti-mud element 70 forms an expanding conical surface with the same angle as the angle of the lower expanding part of the anti-mud plate 60.

 As a result, a more efficient retention of dirt that rises with the air in the dust collector 30 is provided.

 Other structural elements and performance characteristics are the same as in the first preferred embodiment of the present invention, and therefore, their detailed description is not given.

 Figure 10 shows a perspective three-dimensional image with a spatial separation of the details of the cyclone dust collection device in accordance with the fourth preferred embodiment of the present invention, and Fig. 11 is a cross-section illustrating the principle of dust collection of the cyclone dust collecting device shown in FIG. 10. FIG. 12 is a cross-sectional view of a cyclone dust collecting apparatus according to a fifth preferred embodiment of the present invention.

 The basic construction of the cyclone dust collecting apparatus according to the fourth and fifth preferred embodiments of the present invention is the same as the first preferred embodiment of the present invention, except that the dust collector 30 is made of a first cylindrical assembly 30a with a predetermined diameter d1 that forms the upper part of the dust collector and a second cylindrical assembly 30b, which forms the lower part of the dust collector and has a larger diameter than the diameter of the first cylindrical assembly 30a.

 In such a design, the vortex airflow excited in the dust collector 30 rotates at a relatively high speed in the first cylindrical assembly 30a and rotates at a relatively low speed in the second cylindrical assembly 30b. This thus allows to minimize the amount of dirt that rises from the base of the second cylindrical node 30b with a swirling air flow.

 In this design, the second cylindrical assembly 30b may have a conical shape in which the diameter of the upper part is less than the diameter of the lower part, as shown in FIG. 11, or may have the shape of a straight cylinder whose diameter is larger than the diameter of the first cylindrical assembly 30a, as shown in FIG. 12.

 Other structural elements and performance characteristics are the same as in the first preferred embodiment of the present invention, and therefore, their detailed description is not given.

 As indicated above, since the dirt in the form of large particles and the dirt in the form of pieces of toilet paper contained in the air sucked through the intake air intake is mainly collected by the cyclone dust collecting device, the present invention can significantly reduce the amount of dirt collected by the paper filter in the main body vacuum cleaner. This allows you to increase the time interval between replacing the paper filter.

 In addition, when the dust collector of the cyclone dust collector is filled with dirt, to remove dirt, you can simply separate the dust collector without separating the cyclone dust collector from the extension pipe.

 Moreover, according to other preferred embodiments of the present invention, it is possible to effectively prevent the spread of dirt collected in the dust collector from flowing, and thereby reduce the amount of dirt collected in the paper filter. Therefore, the life of the paper filter can be increased.

 In addition, according to other preferred embodiments of the present invention, since dirt, like toilet paper, is collected in the dust collector and does not get on the dirt separating grate, it does not clog the smallest passing holes of the dirt separating grate, and thus it is possible to prevent overloading of the cyclone dust collecting device or electric motor and prevent deterioration in cleaning efficiency.

 Although preferred embodiments of the invention have been described, those skilled in the art will understand that the present invention should not be limited to the described preferred embodiments of the invention, but various changes and modifications may be made within the spirit and scope of the invention set forth in the appended claims.

Claims (10)

 1. A vacuum cleaner including a cyclone dust collection device located on a different axis relative to an extension pipe connecting the main body of the vacuum cleaner and the intake air intake, and intended to separate and collect dust and dirt in the form of relatively large particles that are sucked through the intake air intake with the air underneath centrifugal force, and the cyclone dust collection device includes a cyclone body having a first and second connecting tube, connected with the extension pipe of the vacuum cleaner, an air inlet formed on one side of the cyclone collector and communicating with the first connecting pipe, and an air outlet formed on the other side of the cyclone collector and communicating with the second connecting pipe, and used to create a vortex air flow from the intake air of the dust collector combined with the cyclone body and serving to collect dirt separated from the air by a swirling air flow in the cyclone body a trap separating the dirt grate, conically expanding downward from the air outlet, closed at the lower end and having many tiny passing holes to prevent dirt from entering the stream through the air outlet with air, an anti-mud agent located at the lower end of the dirt separating grate and trapping dirt, which is lifted together with the air by an ascending air flow, until the dirt separates the dirt from the grate, and then re-precipitates the dirt, fixing cf means for removable fastening of the dust collector on the specified cyclone body.  2. The vacuum cleaner according to claim 1, characterized in that the anti-mud agent is formed by combining the anti-mud plate and the lower end of said dirt separating grate, the anti-mud agent having a conical shape with a diameter of the lower part larger than the diameter of the upper part.  3. The vacuum cleaner according to claim 2, characterized in that the anti-mud agent contains an additional anti-mud element for increasing the effectiveness of the anti-mud plate and is made expanding with the same angle as the part of the anti-mud plate expanding downward.  4. The vacuum cleaner according to claim 1 or 2, characterized in that the anti-mud agent has an additional conical anti-mud rotating plate located at the lower end of the dirt-separating grate, which rotates by a swirling air stream.  5. The vacuum cleaner according to claim 4, characterized in that the additional anti-mud element to increase the effectiveness of the specified anti-mud rotating plate has an expanding shape with the same angle as the downward-expanding part of the anti-mud rotating plate.  6. The vacuum cleaner according to any one of paragraphs. 1-5, characterized in that the cyclone body includes a lower part of the body with a first connecting tube and an air inlet, an upper part of the body with a second connecting tube and an air outlet and several screws for combining the upper and lower parts of the body into one.  7. Vacuum cleaner according to any one of paragraphs. 1-6, characterized in that the dirt separating lattice is made as a whole and includes a guiding element with a rib groove into which a curved rib is inserted that defines the boundaries of the specified air outlet in the cyclone collector body, a conical lattice element, the inside of which is hollow , and a cylindrical lattice element, the lower end of which is closed, while many tiny transmitting holes are made in the part of the conical lattice element, except for a certain domain near the air inlet, and on the entire side surface of the cylindrical screen.  8. The vacuum cleaner according to any one of paragraphs. 1-7, characterized in that the support element for fixing the dust collector on the extension pipe is made as a single unit on one side around the circumference of the smaller radius of the dust container, and a locking ring having a sliding groove into which the support element is inserted is located on the extension pipe of the vacuum cleaner.  9. The vacuum cleaner according to claim 8, characterized in that the support element includes a locking protrusion having a suspension fixture that is fixed after insertion into the sliding groove of the locking ring, and a guide protrusion that is formed in front of the locking protrusion and guides the locking protrusion when inserted into groove slip.  10. The vacuum cleaner according to claim 6, characterized in that the fixing means includes a pair of suspension holes made on both sides of the lower part of the housing, a pair of latches having hooks at one of their ends, which are fixed to a pair of supporting elements of the latches, formed as one the whole on both sides of the upper part of the dust collector, the hooks catching on the suspension holes, and the spring located between the inner part of the rear side of the latch and the supporting element of the latch on the dust collector to spring fi Xator in one direction.

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