KR102315023B1 - Vacuum cleaning system with low frequency pulse - Google Patents

Abstract

Disclosed is a vacuum cleaning system with low-frequency pulses, which efficiently performs cleaning. To this end, the vacuum cleaning system with low-frequency pulses comprises: a main body (100); a pressure regulator (200) installed inside the main body (100) to adjust the pressure of air supplied from the outside to a set pressure; an air generator (300) connected to the pressure regulator (200) to supply the air to an object to be cleaned; a pulse generator (500) generating low-frequency pulses so that the air whose pressure has been adjusted through the pressure regulator (200) is supplied to the object to be cleaned in the form of the low-frequency pulse; and a sub main body (600) connected to the pulse generator (500) and including a pulse air injection hole (610) to which the air can be supplied in the form of a low-frequency pulse and a suction hole (620) formed on the upper surface sucking foreign substances scattered by the pulsed air supplied through the pulse air injection hole (610). A pulse nozzle (400) from which the pulse air is injected is formed in the center of the sub main body (600) while extending in the downward direction and a pair of side shielding members (410) are installed on both sides of the sub main body (600) to prevent the foreign substances from moving to the outside by the pulse air.

Description

VACUUM CLEANING SYSTEM WITH LOW FREQUENCY PULSE

The present invention relates to a vacuum cleaning system using low-frequency pulses.

In general, a vacuum cleaner is a device that sucks dust together with air by a suction force generated by a fan rotated by a motor, separates the dust contained in the sucked air from the air, and collects the dust to perform cleaning.

Such a vacuum cleaner includes an upright body including a fan motor for generating suction force, a head unit disposed on the front side of the upright body to suck dust together with air from the floor, and a handle for a user to hold and move the vacuum cleaner and an extension frame that connects the handle and the upright body so that the user can move the upright body in a standing state.

However, even if the vacuum suction power is high, there is a limit to inhaling foreign substances on carpets, rugs, etc. with a vacuum cleaner.

Accordingly, it is an object of the present invention to provide a vacuum cleaning system of a new type in which foreign substances are suspended and then sucked so as to remove foreign substances that are not efficiently sucked in a conventional vacuum cleaner system.

KR 10-2085135 (registered on February 28, 2020)

The present invention relates to a vacuum cleaning system using a low-frequency pulse of a new type that can remove foreign substances that cannot be removed by a conventional vacuum cleaner by improving the system of an existing vacuum cleaner and supplying air as a low-frequency pulse.

A vacuum cleaning system using low-frequency pulses is introduced.

To this end, the present invention provides a vacuum cleaning system using a low-frequency pulse, the main body 100; a pressure regulator 200 installed inside the body 100 to adjust the pressure of air supplied from the outside to a set pressure; an air generator 300 connected to the pressure regulator 200 to supply air to the cleaning target; a pulse generator 500 for generating a low-frequency pulse so that the air whose pressure has been adjusted through the pressure regulator 200 is supplied to the cleaning target in the form of a low-frequency pulse; A pulse air injection hole 610 connected to the pulse generator 500, to which air can be supplied in the form of a low-frequency pulse, and a foreign substance scattered by the pulse air supplied by the pulse air injection hole 610 can be sucked. A sub-body 600 having a suction hole 620 formed on the upper surface thereof is positioned at one lower side of the main body 100, and a pulse nozzle ( 400) is formed extending downward, and a pair of side shielding members 410 are installed on both sides of the sub body 600 to prevent foreign substances from moving to the outside by pulsed air. .

According to the present invention having the above configuration, 1) fine dust particles that cannot be removed with a conventional vacuum cleaner are suspended and then sucked in to effectively clean, and 2) the direction of the sprayed air and the direction of suction are Various effects are realized, such as being staggered, and the suction area is located wider than the sprayed area, so that the efficient removal of foreign substances is achieved.

1 is an overall schematic view of the present invention;
2 is a front view of the sub body;
3 is a perspective view of a sub body;

Hereinafter, a preferred embodiment of a vacuum cleaning system using a low-frequency pulse of the present invention will be described with reference to the accompanying drawings.

1 is an overall schematic diagram of the present invention.

As shown, the present invention provides a vacuum cleaning system using a low-frequency pulse, the main body 100; a pressure regulator 200 installed inside the body 100 to adjust the pressure of air supplied from the outside to a set pressure; an air generator 300 connected to the pressure regulator 200 to supply air to the cleaning target; a pulse generator 500 for generating a low-frequency pulse so that the air whose pressure has been adjusted through the pressure regulator 200 is supplied to the cleaning target in the form of a low-frequency pulse; It is connected to the pulse generator 500, and the pulse air injection hole 610 to which air can be supplied in the form of a low-frequency pulse and the pulse air injection hole 610 can suck foreign substances scattered by the pulsed air. A sub-body 600 having a suction hole 620 formed on the upper surface thereof is positioned at one lower side of the main body 100, and a pulse nozzle ( 400) is formed extending downward, and a pair of side shielding members 410 are installed on both sides of the sub body 600 to prevent foreign substances from moving to the outside by pulsed air. .

The main body 100 means a housing of a vacuum cleaner, and the shape of the main body 100 is not limited, and any structure in which the sub-body 600 to be described below can be coupled to one side of the vacuum cleaner housing is applied to the present invention. This is possible.

A pressure regulator 200 installed inside the body 100 to adjust the pressure of air supplied from the outside to a set pressure is disclosed.

Although not shown in the drawing, a flow path through which air can be supplied to the corresponding pressure regulator 200 may be formed.

The pressure regulator 200 may be configured as a regulator, and the control unit 210 to be described below adjusts the pressure of the incoming air to a set pressure.

The air generator 300 connected to the pressure regulator 200 is disclosed.

The air generator 300 is configured to supply air to the cleaning target, and whether air is supplied is controlled by the control unit 210 installed inside the main body 100 .

The air generator 300 is composed of a solenoid valve and its operation can be controlled by the control unit 210 located inside the body 100, but is not necessarily limited thereto. It is installed inside a general vacuum cleaner to supply air. If it is a structure, it can be applied to the present invention.

The air generator 300 can be applied to the present invention in a structure that opens a valve to supply air when cleaning is started under the control of the controller 210 and closes the valve when cleaning is finished.

The control unit 210 provided inside the main body 100 controls the operation of the pressure regulator 200 , the air generator 300 , the pressure regulator 200 , and the vacuum generator 700 .

A pressure regulator 200 connected to the air generator 300 to adjust the pressure of the air to a set pressure is disclosed.

On the other hand, the set pressure of the pressure regulator 200 may be a pressure of 0.1Mpa to 0.15Mpa, but is not necessarily limited thereto, and the corresponding pressure may be controlled according to a vacuum cleaning target or a vacuum cleaning environment, which is also a control unit 210 However, it may be controlled by a separate button provided on the outside of the vacuum cleaner.

The low-frequency pulsed air is injected to the cleaning target and the pressure regulator 200 is controlled to a relatively weak pressure.

A pulse generator 500 for generating a low-frequency pulse is installed inside the body 100 so that the air whose pressure is adjusted through the pressure regulator 200 is supplied to the cleaning object in the form of a low-frequency pulse.

The pulse generator 500 generates a low-frequency pulse so that the air supplied to the cleaning object can be injected in the form of a low-frequency pulse having discontinuity.

Low frequency is a relative concept and means low frequency, not high frequency.

These low-frequency pulses are sprayed together with air to become a kind of pulsed air. Due to this pulsed air, foreign substances, which are difficult to solve with a conventional vacuum cleaner, are separated from the cleaning object and floated, and at the same time, the suspended foreign substances are removed from the suction hole 620 to be described below. ) is inhaled and removed.

The low frequency band means a frequency of 10 kHz or less, and the structure of the pulse generator 500 applied to the present invention is not limited to a specific structure, but it is applicable to the present invention as long as a frequency of 10 kHz or less can be supplied to air. do.

On the other hand, it is connected to the pulse generator 500, the pulse air injection hole 610 to which air can be supplied in the form of a low-frequency pulse, and the pulse air injection hole 610 is sucked in foreign substances suspended by the pulsed air supplied by the hole. A sub-body 600 having a suction hole 620 that can do it is located on one lower side of the main body 100 .

As shown in FIGS. 2 and 3 , the sub body 600 has side shielding members 410 installed on both sides and a pulse nozzle 400 extending to a predetermined length is formed in the center thereof.

The side shielding member 410 performs a kind of shielding function to prevent foreign substances scattered by the pulse nozzle 400 from moving to the outside.

Furthermore, the side shielding member 410 has a suction mesh port 621 formed with a predetermined area, and the suction mesh port 621 is in communication with the suction hole 620 to be described below to suck foreign substances.

The suction mesh port 621 made of a plurality of meshes is not limited to a special structure, and can be applied to the present invention as long as it has a structure that can communicate with the suction hole 620 .

The sub-body 600 is located on one lower side of the main body 100 constituting the housing of the vacuum cleaner, and the pulse air injection hole 610 and the pulse generator 500, which will be described below, are connected to each other so that the air by the low-frequency pulse is pulsed air. Moving along the injection hole 610, the moved pulse air is injected along the pulse nozzle (400).

FIG. 2 is a front view of this sub-body 600, and FIG. 3 is a perspective view.

As shown, pulsed air is sprayed to the cleaning target along the pulse air spray hole 610, and foreign substances floating due to this spray are not moved to another place by the side shielding member 410, and the side shielding member 410 After being sucked along the suction mesh port 621 formed in the member 410, it is removed after being caught by the filter.

The pulse air injection hole 610 formed in the sub main body 600 is formed in a form penetrating along the lower surface from the upper surface of the sub main body 600, and the pulse air injection hole 610 formed in the upper surface is a pulse generator ( 500) and the air supplied in the form of a pulse is introduced.

Similarly, the suction hole 620 formed in the sub body 600 is formed to penetrate along the lower surface from the upper surface of the sub body 600 , and the suction hole 620 formed in the upper surface is formed in the main body 100 . It is connected to a separate vacuum generator 700 provided, and it is characterized in that foreign substances suspended by the vacuum generator 700 are sucked.

Meanwhile, the vacuum generator 700 is positioned inside the main body 100 .

The vacuum generator 700 generates a vacuum so that foreign substances can be sucked along the suction hole 620 .

Of course, the time of generating the vacuum of the vacuum generator 700 may correspond to the time when air is supplied to the air generator 300 .

For this purpose, as shown in FIG. 1 , an air supply path is branched between the air generator 300 and the pressure regulator 200 to be connected to the vacuum generator 700 .

Again, the operation of the vacuum generator 700 is controlled by the control unit 210 installed inside the main body 100 .

Although the structure of the vacuum generator 700 applied to the present invention is not specifically disclosed, it can be applied to the present invention as long as it generates a vacuum and has a structure in which foreign substances can be sucked by the vacuum.

On the other hand, a separate filter 800 is positioned between the vacuum generator 700 and the suction hole 620 formed on the upper surface of the sub-body 600, and foreign substances sucked by the filter 800 are collected. do.

The structure of the filter 800 is also not specifically limited, but it is applicable to the present invention as long as the filter 800 is installed inside a general vacuum cleaner.

In addition, a contact sensor 900 for recognizing contact with the ground is further installed on the lower surface of the pair of side covering members 410 , and the signal sensed by the contact sensor 900 is inside the body 100 . It is transmitted to the installed control unit 210, and the control unit 210 controls the operation of the air generator 300 so that air is supplied.

Through this, even if the user does not press a separate operation button, when a signal that the user touches the ground is sensed, the control unit 210 turns on the operation of the air generator 300 to perform cleaning.

In this case, of course, when air is supplied through the air generator 300 , the controller 210 may control the vacuum generator 700 to generate a vacuum.

The working relationship is briefly described as follows.

When sensed by the contact sensor 900 , the signal is transmitted to the control unit 210 .

The control unit 210 sets the pressure supplied to the pressure regulator 200 located inside the main body 100 , the air is supplied to the air generator 300 , and is again controlled to the pressure set by the pressure regulator 200 . .

Air supplied to the pulse generator 500 at a set pressure is sprayed to the cleaning target along the pulse air injection hole 610 together with the low frequency and pulses generated by the pulse generator 500 .

At this time, the control unit 210 operates the vacuum generator 700 at the same time so that foreign substances suspended by the corresponding pulse air injection hole 610 are sucked along the suction hole 620 .

When the non-contact signal is sensed by the contact sensor 900, the operation logic is stopped.

100: body 200: pressure regulator
300: air generator 400: pulse nozzle
500: pulse generator 600: sub body
700: vacuum generator 800: filter
900: contact sensor

Claims (5)

In the vacuum cleaning system using a low frequency pulse,
body 100;
a pressure regulator 200 installed inside the body 100 to adjust the pressure of air supplied from the outside to a set pressure;
an air generator 300 installed inside the main body 100 and connected to the pressure regulator 200 to supply air to the cleaning target;
a pulse generator 500 installed inside the main body 100 and generating a low-frequency pulse so that the air whose pressure is controlled through the pressure regulator 200 is supplied to the cleaning target in the form of a low-frequency pulse;
It is connected to the pulse generator 500, and the pulse air injection hole 610 to which air can be supplied in the form of a low-frequency pulse and the pulse air injection hole 610 can suck foreign substances scattered by the pulsed air. A sub-body 600 having a suction hole 620 formed on the upper surface thereof is located at one lower side of the main body 100,
A pulse nozzle 400 to which pulse air is injected is formed in the center of the sub body 600 while extending downward, and on both sides of the sub body 600, foreign substances are prevented from being moved to the outside by the pulse air It is characterized in that a pair of side shielding members 410 are installed for
A suction mesh port 621 through which foreign substances suspended by the pulse air can be sucked is formed in the pair of side covering members 410, and the suction hole 620 and the side covering member 410 communicate with each other in the interior. characterized by being
The pulse air injection hole 610 is connected to the pulse generator 500, and air supplied in the form of a pulse is injected through the pulse nozzle 400 communicated with the pulse air injection hole 610. , a vacuum cleaning system using low-frequency pulses. delete The method according to claim 1,
The suction hole 620 formed in the sub-body 600 is connected to a separate vacuum generator 700 provided in the main body 100 so that foreign substances suspended by the vacuum generator 700 are sucked. , a vacuum cleaning system using low-frequency pulses. 4. The method according to claim 3,
A separate filter 800 is positioned between the vacuum generator 700 and the suction hole 620 formed on the upper surface of the sub-body 600 to collect foreign substances sucked by the filter 800 . Characterized in, a vacuum cleaning system using a low-frequency pulse. 5. The method according to claim 4,
A contact sensor 900 for recognizing contact with the ground is installed on the lower surface of the side covering member 410, and the signal sensed by the contact sensor 900 is a control unit 210 installed inside the body 100. is sent to
The control unit 210 controls the operation of the air generator 300 according to the signal sensed by the contact sensor 900 so that air is supplied, a vacuum cleaning system using a low frequency pulse.

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