JP2006272314A - Multi-cyclone dust collecting apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a multi-cyclone dust collecting apparatus capable of collecting fine particles of dust included in air and capable of improving flow velosity on the side of a suction brush. <P>SOLUTION: The multi-cyclone dust collecting apparatus includes: a first and a second multi-cyclone units having a first cyclone unit which collects large particles of dust and a second cyclone unit for collecting fine particles of dust; an air suction path which includes a partition plate therein and through which dust-containing air is distributed and supplied to each of the first and second multi-cyclone units; and an air exhaust path which gathers air discharged from second cyclone parts of each of the first and second multi-cyclone units and discharges the gathered gas to the outside. <P>COPYRIGHT: (C)2007,JPO&INPIT

Description

  The present invention relates to a cyclone dust collector, and more particularly, to a left-right symmetric multi-cyclone dust collector having an increased suction flow rate and improved dust dust collection efficiency.

  Generally, a vacuum cleaner sucks air containing dust and separates it into dust and air by a dust collector. The conventional dust collector mainly uses a dust filter, but there is a disadvantage that it must be replaced if the dust filter is filled with dust. When replacing the dust filter, the user has to touch the contaminated filter directly with his hand, which is inconvenient and unsanitary.

  Considering this, recently, cyclone dust collectors that can be used permanently in the second half after removing filtered dust have been widely developed. The cyclone dust collector has a structure for collecting dust by centrifuging dust from air based on the principle of centrifugation.

  However, the cyclone dust collector does not use a dust bag or a dust filter, so that it has a merit that it can be used semipermanently, but has a problem that fine dust contained in the air cannot be collected completely. In order to solve the problem of the cyclone dust collecting apparatus, the present applicant has reduced the ability to collect fine dust, and the ability to collect fine dust is disclosed through patent applications 2003-62520, 2003-63221, 2003-63212, 2003-63213. An improved multi-cyclone dust collector was filed. According to such a configuration, the collection efficiency of fine dust can be improved as compared with the conventional cyclone dust collector. However, since a large number of cyclone airflows are required, the flow velocity on the suction brush side may be reduced.

  The present invention has been devised in order to solve the above-mentioned problems, and an object of the present invention is to collect a fine dust contained in the air and to improve the flow velocity on the suction brush side. The object is to provide a dust collector.

  Another object of the present invention is to provide a cyclone dust collecting device capable of improving the collection capability of large garbage.

  It is a further object of the present invention to provide a multi-cyclone dust collector having an improved structure so as to improve the dust collection capability.

  In order to achieve the above-described object, the multi-cyclone dust collecting apparatus according to the present invention includes at least two multi-cyclone units including a first cyclone unit that collects large dust and a second cyclone unit that collects fine dust. It is characterized in that two or more are provided symmetrically. At this time, the second cyclone unit is arranged in a C shape on the outer circumferential surface of the first cyclone unit.

  A multi-cyclone dust collector according to a preferred embodiment of the present invention includes a first and second multi-cyclone unit including a first cyclone unit that collects large garbage and a second cyclone unit that collects fine garbage. An air intake path for distributing and supplying dusty air to each of the first and second multicyclone units, and collecting air discharged by the second cyclone unit of each of the first and second multicyclone units. And an exhaust passage for exhausting to the outside.

  The air suction path preferably includes a branch plate in one air suction path to form first and second air suction ducts.

The first and second multi-cyclone units are provided symmetrically to each other;
It is preferable that the first and second multi-cyclone units have dust collecting cylinders separated from each other.

  According to the present invention, the air sucked into one inlet is branched inside and separated into dust and air at the same time by a plurality of multi-cyclone dust collectors, thereby including dust sucked in on the suction brush side. It is possible to prevent a decrease in the flow rate of the generated air.

  Furthermore, since a plurality of first cyclone units capable of collecting large garbage are provided, the ability to collect large garbage is improved.

  In addition, since at least two or more multi-cyclone units including a first cyclone unit that collects large dust and a second cyclone unit that collects fine dust are provided symmetrically, the collection efficiency of fine dust is improved.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

  As shown in FIG. 1, the multi-cyclone dust collector according to the present invention is provided with symmetrical multi-cyclone dust collectors having the same structure, the first multi-cyclone unit 100, the second multi-cyclone unit 200, the air suction flow. A passage 300 and an exhaust passage 400 are included.

  The first multicyclone unit 100 includes a first cyclone unit 110 and a second cyclone unit 120. The first cyclone unit 110 is eccentrically connected to the air suction channel 300. A plurality of second cyclone units 120 are arranged in a C shape around the first cyclone unit 110.

  That is, air containing dust flows into the first cyclone unit 110 through the first air suction duct 310 branched by the air suction passage 300 while forming a rotating air current, and the dust is centrifuged inside. The The centrifugally separated air of the dust is secondarily filtered through an exhaust grill 113 provided with a backflow prevention member, and then passes around the first cyclone unit 110 through a spiral flow path 115 connected to the exhaust grill 113. It flows into a plurality of second cyclone units 120 arranged radially asymmetrically. As shown in the figure, the second cyclone unit 120 preferably has six second cyclone units 120 arranged in a C shape. The air that has flowed into the second cyclone unit 120 is centrifuged again at the second cyclone body 121 and collects fine dust that cannot be collected by the first cyclone unit 110. The dust centrifuged by the first and second cyclone units 110 and 120 is collected in the first dust collecting cylinder 130. Fine dust is separated and purified air is exhausted to the cleaner body through the first exhaust pipe 140.

  The second multi-cyclone unit 200 has the same configuration that is provided symmetrically with respect to the first multi-cyclone unit 100 and the air suction passage 300 described above.

  On the other hand, the second dust collection cylinder 230 of the second multi-cyclone unit 200 is separated from the first dust collection cylinder 130, and 240, which is not described, is a second exhaust pipe.

  The air suction flow path 300 simultaneously feeds dust on the surface to be cleaned through the cleaning unit such as a suction brush to the first and second multi-cyclone units 100 and 200 together with air. Preferably, as shown in FIG. 2, a branch plate 301 is provided inside, and a first air intake duct 310 that supplies air containing dust to the first multicyclone unit 100, and a second multicyclone unit 200. A second air suction duct 320 for supplying air containing dust is formed. In this way, the air sucked at one inlet is branched inside and the dust and air are separated from each of the first and second multi-cyclone units 100 and 200, so that suction is performed on the suction brush side (not shown). The amount of air flowing in and the amount of large garbage collected are increased.

  The exhaust passage 400 is formed in a cover (C) coupled to the upper side of the first and second multi-cyclone units 100 and 200, and the first and second exhaust pipes 140 and 240 formed in the second cyclone unit 120. The air discharged from the air is collected and exhausted to a vacuum suction motor (not shown) provided in the cleaner body.

  Hereinafter, the operation of the multi-cyclone dust collector according to the present invention will be described.

  The dust-containing air sucked through the air suction channel 300 passes through the first and second air suction ducts 310 and 320 separated by the branch plate 301, and the first and second multicyclone units 100. , 200 and separated into dust and air by the first and second multi-cyclone units 100 and 200, respectively. That is, in the first multi-cyclone unit 100, large garbage is first separated by the first cyclone unit 110, and fine garbage that is not collected by the first cyclone unit 110 is centrifuged again by the plurality of second cyclone units 120. This process is performed in the same way in the second multi-cyclone unit 200 provided symmetrically with the first multi-cyclone unit 100.

  On the other hand, the air that has been collected by the first and second multicyclone units 100 and 200 is discharged through the first and second exhaust pipes 140 and 240, and the discharged air is collected again to form an exhaust passage. The air is exhausted to the side of a vacuum suction motor (not shown) provided in the cleaner body via 400.

  In this way, since the dust-containing air is filtered in parallel by the multi-cyclone units having the same configuration arranged symmetrically, the dust collection efficiency can be improved.

  As described above, the use of two multi-cyclone units having excellent fine dust collection efficiency in a symmetrical arrangement has been described. However, the present invention is not necessarily limited thereto. Although not shown, it is also possible to use three or more multi-cyclone units that share an air intake passage and an exhaust passage and are arranged in parallel.

  Although the preferred embodiments of the present invention have been illustrated and described with reference to the drawings, the protection scope of the present invention is not limited to the above-described embodiments, and the invention described in the claims and equivalents thereof are described. It extends to things.

It is sectional drawing of the multi cyclone dust collector which concerns on this invention. It is II-II sectional drawing of FIG.

Explanation of symbols

100 First multi-cyclone unit 110 First cyclone unit 120 Second cyclone unit 130 Garbage collection cylinder 200 Second multi-cyclone unit 300 Air intake channel 400 Exhaust channel

Claims (6)

  A multi-cyclone dust collector, wherein at least two or more multi-cyclone units including a first cyclone unit for collecting large garbage and a second cyclone unit for collecting fine dust are provided symmetrically.   The multi-cyclone dust collector according to claim 1, wherein the multi-cyclone unit has a C-shaped second cyclone unit disposed on an outer peripheral surface of the first cyclone unit. A first and second multi-cyclone unit including a first cyclone unit for collecting large garbage and a second cyclone unit for collecting fine garbage;
An air intake passage for distributing and supplying air containing dust to each of the first and second multi-cyclone units;
An exhaust passage for collecting air exhausted by the second cyclone unit of each of the first and second multicyclone units and exhausting the air to the outside;
A multi-cyclone dust collector.   The multi-cyclone dust collecting apparatus according to claim 3, wherein the air suction path is provided with a branch plate in one air suction path to form first and second air suction ducts.   The multi-cyclone dust collector according to claim 3, wherein the first and second multi-cyclone units are provided symmetrically to each other.   The multi-cyclone dust collector according to claim 3, wherein the first and second multi-cyclone units have a dust collecting cylinder separated from each other.

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