KR101823839B1 - Central dust collect vacuum cleaning system - Google Patents

Abstract

The present invention relates to a central dust-collecting vacuum cleaning system, and provides a central dust-collecting vacuum cleaning system including: a vacuum suctioning portion for generating a dust suctioning pressure; a particle separating portion for separating and temporarily storing particles of a specific size or larger among the suctioned dust particles; a first dust collecting portion disposed between the particle separating portion and the vacuum suctioning portion, and collecting particles passing through the particle separating portion; and a second dust collecting portion disposed between the particle separating portion and the vacuum suctioning portion, and collecting particles temporarily stored in the particle separating portion.

Description

[0001] CENTRAL DUST COLLECT VACUUM CLEANING SYSTEM [0002]

The present invention relates to a central dust collecting vacuum cleaning system, and more particularly, to a central dust collecting vacuum cleaning system which can separate a fine particle and a large particle separately to thereby extend a replacement cycle of the dust filter.

Generally, the central dust collecting vacuum cleaner installs the vacuum cleaner body in the underground building and the management floor, installs suction pipe for each floor, installs the vacuum cleaner main body in a place where less noise is transmitted, such as a veranda, And a connector for connection and connection of the suction port is partially connected to the wall surface or bottom surface of the suction pipe to be connected and used.

1 is a schematic diagram illustrating a conventional central dust collection vacuum cleaning system. The conventional central dust collecting vacuum cleaning system includes a central dust collector 10, suction pipes 20 and 21, a suction hose 30, a suction gun 40 and a controller 60.

Such a central collecting type vacuum cleaning method is widely used in common multi-family houses, office buildings, hotels, offices, and the like because it can solve the noise problem of the vacuum cleaner, facilitate the treatment of the collected garbage, and simplify the cleaning tool.

However, in the central dust collecting vacuum cleaning system, the length of the suction pipes 20 and 21 increases due to the distance from the central dust collecting organs 10 for generating suction force and dust collecting space to the space for actual cleaning, The flow resistance of the fluid is generated and the suction force is lowered.

It is necessary to increase the output of the vacuum pump in order to compensate for the decrease in the suction force, thereby causing a disadvantage that the power consumption is increased. Further, according to the conventional dust collecting system, since the dust collected by the central dust collector is collectively collected, it is difficult to collect the dust when the important article is sucked due to carelessness of the user.

Patent Document 1: Korean Patent No. 10-0917258 'Central dust collecting vacuum cleaning system equipped with horizontal dust collector'

SUMMARY OF THE INVENTION It is an object of the present invention to provide a central dust collecting vacuum cleaning system in which a first dust collecting section for collecting fine particles and a second dust collecting section for collecting large particles are provided in parallel to extend the replacement period of the dust collecting filter.

According to another aspect of the present invention, there is provided a vacuum cleaner for a central collection type vacuum cleaner, comprising: a vacuum suction unit generating a dust suction pressure; A particle separating unit for separating and temporarily storing particles of a specific size or larger among the sucked dust particles; A first dust collecting part disposed between the particle separating part and the vacuum suction part and collecting particles passing through the particle separating part; And a second dust collecting part disposed between the particle separating part and the vacuum suction part and collecting particles temporarily stored in the particle separating part.

Here, the particle separator may include: a housing having a receiving space therein; A suction port disposed on one side of the housing and connected to the suction pipe; A first outlet disposed on one side of the housing and connected to the first dust collector; And a second outlet disposed on one side of the housing and connected to the second dust collection unit.

The particle separating unit may further include a flow preventing plate disposed between the inlet and the first outlet to prevent the flow of the air that has passed through the inlet to go straight to the first outlet, The first outlet may be disposed at an upper portion of the housing, and the second outlet may be disposed at a lower portion of the housing.

The vacuum cleaner may further include a vacuum cleaner disposed between the first dust collector and the vacuum suction unit and configured to switch a connection state of the vacuum suction unit and the first dust collection unit to a connection state between the vacuum suction unit and the second dust collection unit, 1 switching valve unit.

And a second dust collecting unit that is disposed between the particle separating unit and the first dust collecting unit and controls the connection of the particle separating unit and the first dust collecting unit to the connection state between the second dust collecting unit and the first dust collecting unit, 2 switching valve unit.

According to the central dust collecting vacuum cleaning system according to the embodiment of the present invention,

First, the large particles are separated and accommodated through the particle separating unit, and the separated large particles are collected in the second dust collector after the cleaning by the user is completed, so that the replacement period of the first dust collector filter can be extended as compared with the conventional method.

Second, since the first dust collector for collecting the fine particles and the second dust collector for collecting the large particles are arranged in parallel, the load applied to the vacuum suction portion is reduced, so that the power consumption can be reduced.

1 is a schematic diagram illustrating a conventional central dust collection vacuum cleaning system.
2 is a block diagram illustrating a central dust collection vacuum cleaning system in accordance with one embodiment of the present invention.
3 is a block diagram illustrating a central dust collection vacuum cleaning system in accordance with another embodiment of the present invention.
4 is a cross-sectional view illustrating the particle separator shown in Figs. 2 and 3. Fig.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Note that, in the drawings, the same components are denoted by the same reference symbols as possible. Further, the detailed description of known functions and configurations that may obscure the gist of the present invention will be omitted. For the same reason, some of the components in the drawings are exaggerated, omitted, or schematically illustrated.

FIG. 2 is a block diagram illustrating a central dust collecting vacuum cleaning system according to an embodiment of the present invention, and FIG. 4 is a cross-sectional view illustrating the particle separator shown in FIG.

2 and 4, the central dust collecting vacuum cleaning system 1000 according to the present invention includes a first dust collecting unit 100, a second dust collecting unit 200, a particle separating unit 300, a vacuum suction unit 400, 1 switching valve 500, a control unit (not shown), suction pipes 20 and 20 ', a suction hose 30 and a suction gun 40.

The suction piping 20 is shown as a piping connected to each floor of the building where the central dust collecting vacuum cleaning system 1000 is installed. However, this is only conceptually shown for convenience of explanation, And a suction pipe 21 branched into the cleaning space as shown in Fig.

The suction hose 30 is connected to the suction gun 40 as a hose extending from the end of the suction pipe 20, that is, a connector (not shown) provided in the cleaning space and extends the suction pipe 20, The dust collecting vacuum cleaning system 1000 can be used as a general vacuum cleaner.

According to the embodiment, when the suction hose 30 is connected to the connector, the vacuum suction unit 400 of the central dust collecting vacuum cleaning system 1000 is operated to apply the vacuum pressure to the suction gun 40.

In the present invention, since the suction pipe 20, the suction hose 30 and the suction gun 40 may be used in a conventional conventional manner, the suction pipe 20, the suction hose 30, A detailed description thereof will be omitted.

The vacuum suction unit 400 is a device for generating a vacuum pressure necessary for dust suction, and includes a vacuum pump. The vacuum pump may be a multi-stage turbo blower type. Since the conventional vacuum suction unit 400 may also be used, a detailed description of the vacuum suction unit 400 will be omitted.

The particle separating unit 300 temporarily separates particles of a predetermined size or more from the inhaled dust particles. When the vacuum suction unit 400 is operated, vacuum pressure is applied to the connected pipe, dust in the cleaning space is sucked through the suction gun 40, moves along the suction hose 30 and the suction pipe 20, And then flows into the separator 300.

In general, dust particles include fine particles floating in the air at a constant flow rate or larger particles that can not float in the air below a certain flow rate.

Prior to a detailed description of the particle separator 300, the structure of the conventional dust collector 10 will be described.

In the conventional system, the fine particles and large particles sucked into the suction gun 40 are collected by the central dust collector 10 in a floating state in the air by a strong vacuum suction force (that is, a high air flow rate).

The central dust collector 10 has a bag separator for trapping fine particles. Since the large particles and the fine particles are collected at the bag filter dust collector at the same time, the filter replacement period of the bag filter dust collector is short, In order to overcome this problem, a Cyclone Separator is installed at the front of the bag filter dust collector to separately separate large particles.

However, even if the centrifugal precipitator is further provided in the central dust collector 10, since the large particles must be moved to the central dust collector 10, a strong vacuum suction force is required throughout the cleaning, There are disadvantages.

To solve this problem, the present invention includes a particle separator 300 for separating large particles first.

The particle separating unit 300 temporarily separates particles of a predetermined size or more from the inhaled dust particles. 3, the particle separating unit 300 includes a housing 310, an inlet 320, a first outlet 330, a second outlet 3400, and a flow-preventing plate 350.

The enclosure 310 is a main body constituting the particle separating unit 300. The enclosure 310 is a container having a receiving space inside and includes a suction port 320, a first discharge port 330 and a second discharge port 230 And has a closed face.

1, the particle separator 300 is provided at the front end of the first dust collector 100 and the second dust collector 200. However, only one of the particle separators 300 is shown briefly in order to explain the concept of the present invention , The particle separating unit 300 may be provided in plurality according to the embodiment.

For example, the particle separating unit 300 may be disposed for each layer of the building where the central dust collecting vacuum cleaning system 1000 is installed. As another example, when the building in which the central dust collecting vacuum cleaning system 1000 is installed is a common house, the particle separating unit 300 may be arranged for each call.

The suction port 320 is disposed on one side of the housing 310 and connected to the suction pipe 20. That is, when cleaning is started, dust enters through the suction port 320.

The first outlet 330 is disposed on one side of the housing 310 and connected to the first dust collector 100. That is, when cleaning is started, a part of the dust introduced through the suction port 320 is discharged through the first discharge port 330. Here, it is understood that the 'discharge' is sucked to the first dust collector 100 because the suction pressure is generated by the vacuum suction part 400 as described above.

The second outlet 340 is disposed on one side of the housing 310 and connected to the second dust collector 200. At this time, when cleaning is started, air is not discharged toward the second outlet 340. The operation of the second outlet 340 will be described in the description of the first switching valve 500.

On the other hand, the inlet port 320 and the first outlet port 330 are disposed in the upper portion of the housing 310, and the second outlet 340 is disposed in the lower portion of the housing.

The flow prevention plate 350 is disposed between the suction port 320 and the first discharge port 330 to prevent the flow of air passing through the suction port 320 directly to the first discharge port 330.

4 is a schematic illustration of the particle separating unit 300, the shape of the flow preventing plate 350 is not limited to the shape shown in FIG. .

The flow prevention plate 350 is formed to have a fluid flow structure that generates hydrodynamic load (i.e., air friction resistance) less in consideration of the shape of the housing 310 and the position of the inlet port 320 and the first outlet port 330 It is preferable to have a form that can lower the flow rate of air.

In addition, the flow-preventing plate 350 is not provided inside the housing 310 as a separate member but is formed in a shape in which the inner surface of the housing 310 is bent to realize the function of the flow-preventing plate 350 It is possible.

When the flow rate of the air is slowed by the flow-preventing plate 350, the large particles B fall down to the bottom of the housing 310, and the floating fine particles S can flow through the first outlet 330 And is collected in the first dust collector 100. That is, the large particles B are separated from the particle separating unit 300.

The first dust collecting part 100 is disposed between the particle separating part 300 and the vacuum suction part 400 and collects the particles passing through the particle separating part 300, that is, the fine particles S. The first dust collector 100 may be a bag separator. Since the first dust collecting part 100 can be configured as a bag separator of a conventional system, a detailed description will be omitted.

The first switching valve unit 500 is disposed between the first dust collecting unit 100 and the vacuum suction unit 400 so that the connection state between the vacuum suction unit 400 and the first dust collecting unit 100 is controlled by the control unit, And switches the connection state between the suction unit 400 and the second dust collection unit 200. [

According to one embodiment, the first switching valve portion 500 may be configured to include a triangular valve and a driving device for driving the triangular valve.

The control unit controls the first switching valve unit 500 so that the first switching valve unit 500 is connected to the vacuum suction unit 400 and the first dust collection unit 100 in a clean state in which the user uses the suction gun 40 to suck the dust in the cleaning space. .

In the clean state, the large particles (B) among the dusts to be sucked are separated and temporarily accommodated in the particle separating unit 300 as illustrated in FIG. 4, and the fine particles S among the dusts to be sucked are separated from the particle separating unit 300, And is collected in the first dust collecting unit 100.

Since only the fine particles S pass through the particle separator 300, it is possible to collect the fine particles S even if a flow velocity lower than the flow velocity for moving the large particles B is applied. That is, the diameter of the suction pipe 20 'provided between the particle separating unit 300 and the first dust collecting unit may be larger than the diameter of the suction pipe 20.

According to the present invention, the diameter of the suction pipe 20 'provided between the particle separating unit 300 and the first dust collecting unit is formed to be larger than the diameter of the suction pipe 20, The same suction force can be applied to the suction pipe 20 even if a lower output is applied.

When the cleaning state using the suction gun 40 is terminated, the control unit controls the connection state of the vacuum suction unit 400 and the first dust collection unit 100 to the connection state of the vacuum suction unit 400 and the second dust collection unit 200 . At this time, the switching of the connection state may be performed immediately after the cleaning is completed, or may be performed after a certain number of large particles B are accommodated in the particle separator 300, or may be performed manually by the user.

4, the second separator 300 is connected to the second collecting part 200, and the second separator 300 is connected to the first selector valve 500, The large particles B separated and accommodated in the bottom portion of the housing 310 are sucked into the second dust collecting part 200.

The second dust collector 200 may be a Cyclone Separator or a Bag Separator.

Since the fine particles S may be contained between the large particles B temporarily accommodated in the particle separating unit 300, the second dust collecting unit 200 may include a Cyclone Separator and a Bag Separator Or may be formed in a connected form.

The control unit operates the vacuum suction unit 400 in a high output state only while the discharge of the large particles B temporarily stored in the particle separating unit 300 is completed. Therefore, the amount of power consumption can be reduced as compared with the conventional method in which the vacuum suction unit 400 is operated in a high output state throughout the cleaning state using the suction gun 40.

3 is a block diagram illustrating a central dust collection vacuum cleaning system in accordance with another embodiment of the present invention.

The central dust collecting vacuum cleaning system 1000 'according to another embodiment of the present invention includes a first dust collecting unit 100, a second dust collecting unit 200, a particle separating unit 300, a vacuum suction unit 400, A control unit (not shown), suction pipes 20 and 20 ', a suction hose 30 and a suction gun 40.

The first dust collecting unit 100, the second dust collecting unit 200, the particle separating unit 300, the vacuum suction unit 400, the control unit (not shown), the suction pipes 20 and 20 ', the suction hose 30, Since the suction gun 40 is the same as the embodiment of FIG. 2, a duplicate description will be omitted.

The second switching valve unit 600 is disposed between the particle separating unit 300 and the first dust collecting unit 100 under the control of the controller so that the connection between the particle separating unit 300 and the first dust collecting unit 100 State to the connection state between the second dust collection unit 200 and the first dust collection unit 100. [

The second switching valve unit 600 may be configured to include a triangular valve and a driving device for driving the triangular valve.

When the second switching valve unit 600 is in a connected state between the particle separating unit 300 and the first dust collecting unit 100 in a clean state where the user sucks dust in the cleaning space by using the suction gun 40, do.

In the clean state, the large particles (B) among the dusts to be sucked are separated and temporarily accommodated in the particle separating unit 300 as illustrated in FIG. 4, and the fine particles S among the dusts to be sucked are separated from the particle separating unit 300, And is collected in the first dust collecting unit 100.

Since only the fine particles S pass through the particle separator 300, it is possible to collect the fine particles S even if a flow velocity lower than the flow velocity for moving the large particles B is applied. That is, the diameter of the suction pipe 20 'provided between the particle separating unit 300 and the first dust collecting unit may be larger than the diameter of the suction pipe 20.

According to the present invention, the diameter of the suction pipe 20 'provided between the particle separating unit 300 and the first dust collecting unit can be larger than the diameter of the suction pipe 20, ', It is possible to apply the same suction force to the suction pipe 20 even if the vacuum suction unit 400 applies a lower output than the conventional method.

When the cleaning state using the suction gun 40 is terminated, the control unit controls the connection state of the particle separator 300 and the first dust collector 100 to the connection state between the second dust collector 200 and the first dust collector 200 .

At this time, the switching of the connection state may be performed immediately after the cleaning is completed, or may be performed after a certain number of large particles B are accommodated in the particle separator 300, or may be performed manually by the user.

The second dust collector 200 may be a Cyclone Separator or a Bag Separator.

Since the fine particles S may be contained between the large particles B temporarily accommodated in the particle separating unit 300, the second dust collecting unit 200 may include a Cyclone Separator and a Bag Separator 3, the second dust collecting unit 200 is connected in series with the first dust collecting unit 100, so that the second dust collecting unit 200 is configured as a centrifugal separator, (100) is preferably constituted by a bag filter dust collector.

The control unit operates the vacuum suction unit 400 in a high output state only while the discharge of the large particles B temporarily stored in the particle separating unit 300 is completed. Therefore, the amount of power consumption can be reduced as compared with the conventional method in which the vacuum suction unit 400 is operated in a high output state throughout the cleaning state using the suction gun 40.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined in the appended claims. It will be possible.

1000: Central dust collecting vacuum cleaning system
100: first dust collector
200: the second dust collecting part
300: particle separator
400: vacuum suction part
500: a first switching valve portion
600: a second switching valve portion

Claims (5)

A vacuum suction unit for generating a dust suction pressure;
A particle separating unit for separating and temporarily storing particles of a specific size or larger among the sucked dust particles;
A first dust collecting part disposed between the particle separating part and the vacuum suction part and collecting particles passing through the particle separating part; And
And a second dust collecting part disposed between the particle separating part and the vacuum suction part and collecting particles temporarily stored in the particle separating part,
Wherein the particle separator comprises:
An enclosure having a receiving space therein;
A suction port disposed on one side of the housing and connected to the suction pipe;
A first outlet disposed on one side of the housing and connected to the first dust collector; And
And a second outlet disposed on one side of the housing and connected to the second dust collection unit. delete The method according to claim 1,
Wherein the particle separator comprises:
Further comprising a flow preventing plate disposed between the suction port and the first discharge port to prevent a flow of the air that has passed through the suction port from directing to the first discharge port,
Wherein the suction port and the first discharge port
An upper portion of the housing,
And wherein the second outlet is disposed in a lower portion of the enclosure. The method according to claim 1,
And a second switch for switching a connection state between the vacuum suction unit and the first dust collection unit to a connection state between the vacuum suction unit and the second dust collection unit under control by being disposed between the first dust collection unit and the vacuum suction unit, Further comprising: a valve unit disposed in the vacuum cleaner. The method according to claim 1,
And a second switching unit that is disposed between the particle separating unit and the first dust collecting unit and controls the connection between the particle separating unit and the first dust collecting unit to the connection state between the second dust collecting unit and the first dust collecting unit, Further comprising: a valve unit disposed in the vacuum cleaner.

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