KR101330699B1 - System for suctioning dusts - Google Patents

Abstract

A dust suctioning system is disclosed. The dust suctioning system includes: a dust suctioning unit which includes a housing with a plurality of inlets on the top thereof and an opening and closing member which is formed in the inlet and opens or closes the inlet by pressure which is applied from the top of the housing; and a collector which is arranged near the dust suctioning unit and suctions foreign materials from the inlet to the outside of the dust suctioning unit. The collector includes a sensor which senses a moving body which approaches the dust suctioning unit and operates when the moving body is sensed by the sensor.

Description

Dust suction system {SYSTEM FOR SUCTIONING DUSTS}

The present application relates to a dust intake system.

Japanese Patent Application Laid-Open No. 2001-224548 (inventive name: dustproof Device) includes a movable member having a hemispherical upper surface protruding out of the suction box to block the circular suction port, inside the suction box in which the circular suction port is formed, and when the upper surface on the hemispherical surface is pressed, A damping device is disclosed that allows foreign matter to be sucked into a gap formed between an upper surface of a and an upper surface of a.

However, such a conventional vibration isolator is difficult to maintain the normal opening and closing of the circular suction inlet to the external force action in various directions, there was a problem that the suction of foreign matter can not be made properly.

By the way, such a conventional device for sucking dust has been provided so as not to be exposed to the outside as much as possible the dust collector for processing the dust and the like introduced into the inside of the device, in order to prevent the appearance of deterioration. Thus, the dust collector was provided at a position far from the dust suction device and connected to it via a long hose.

However, in this case, since the suction force of the dust collector is transmitted to the device for sucking dust through the long hose, the suction force of the dust collector is weakened, the dust collection efficiency is lowered, and a space for installing the long hose has to be secured.

An object of the present invention is to provide a dust suction system that can effectively maintain dust and the like, thereby maintaining a cleaner indoor environment.

As a technical means for achieving the above technical problem, the dust suction system according to the first aspect of the present application, the housing is provided with a plurality of inlet holes on the upper side, and provided inside the inlet hole, which is applied from the upper side of the housing A dust suction part including an opening and closing member which opens or closes the inlet hole by pressure; And a dust collector disposed adjacent to the dust suction unit and configured to suck foreign substances introduced into the inlet hole to the outside of the dust suction unit, wherein the dust collector includes a sensor for detecting a moving body approaching the dust suction unit. It can operate when the moving object is detected by the sensor.

According to the aforementioned problem solving means of the present application, by arranging the dust collector adjacent to the dust suction unit, the sensor provided in the dust collector detects the moving object approaching the dust suction unit so that the dust collector operates only when the moving object approaches the energy Waste can be reduced, and the dust collector can suck foreign matter in the dust suction unit with a strong suction force. Therefore, by increasing the dust collection rate of the dust collector, it is possible to remove even the fine dust flowing from the outside, it is possible to efficiently collect the foreign matter by operating the dust collector only when the moving object passes.

1 is a schematic perspective view of a dust intake system according to an embodiment of the present disclosure.
Figure 2 is a schematic cross-sectional view of the dust intake system according to an embodiment of the present application.
3 is a state diagram used in the dust intake system according to an embodiment of the present application.
Figure 4 is a perspective view of a drive unit included in the dust suction system according to an embodiment of the present application.
5 is a schematic plan view of a dust intake system according to an embodiment of the present disclosure.
6 is a configuration diagram for explaining that the dust collector may be selected to be connected to any one of the dust bag region and the moisture filtering region.
7 and 8 are test reports analyzing the components of the first natural mineral contained in the NFC alpha, Figure 8 is a test report analyzing the components of the second natural minerals included in the NFC alpha.
9 is a test report analyzing the characteristics (flammability, flammability, specific gravity, water solubility, melting point, etc.) of the NFC alpha.
10 and 11 are test reports analyzing the far-infrared emission amount of NFC alpha.
12 is a test report on the antimicrobial function of NFC alpha.
13 is a test report for the amount of germanium components contained in the NFC alpha.
14 is a test report for the deodorizing function of the NFC alpha.
15 is a test report on the amount of negative ions released by NFC.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. It should be understood, however, that the present invention may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, the same reference numbers are used throughout the specification to refer to the same or like parts.

Throughout this specification, when a member is " on " another member, it includes not only when the member is in contact with the other member, but also when there is another member between the two members.

Throughout this specification, when an element is referred to as "including " an element, it is understood that the element may include other elements as well, without departing from the other elements unless specifically stated otherwise. The terms "about "," substantially ", etc. used to the extent that they are used throughout the specification are intended to be taken to mean the approximation of the manufacturing and material tolerances inherent in the stated sense, Accurate or absolute numbers are used to help prevent unauthorized exploitation by unauthorized intruders of the referenced disclosure. The word " step (or step) "or" step "used to the extent that it is used throughout the specification does not mean" step for.

For reference, the terms related to directions and positions (upper and lower sides, etc.) in the description of the embodiments of the present invention are set based on the arrangement state of each structure shown in the drawings. For example, when viewed from Fig. 2, the upper side may be the upper side, and the lower side may be the lower side. However, in various practical applications of the embodiments of the present disclosure, it may mean a direction that is generally upward, such as the direction in which the upper side is viewed obliquely.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, the present invention will be described in detail with reference to the accompanying drawings.

First, the dust suction system 1 (hereinafter referred to as 'the present dust suction system') according to an embodiment of the present application will be described.

The dust suction system 1 includes a dust suction unit 10.

When the dust suction unit 10 is provided at the entrance to enter the room from the outside to prevent foreign matter from entering the room, and if provided in the outside to prevent the foreign matter falling to the place where the dust suction unit 10 is not installed As such, it prevents the presence of foreign objects in unwanted places.

The dust suction system 1 includes a dust collector 20.

The dust collector 20 sucks foreign substances introduced into the inlet hole 111 to the outside of the dust suction unit 10.

That is, the dust collector 20 serves to collect and collect the foreign matter introduced into the dust suction unit 10 to the outside through the inlet hole 111 to be described later.

By way of example, the dust collector 20 of the dust suction system 1 may effectively collect dust, foreign matters and various harmful substances attached thereto, as well as bulky foreign substances by using an air suction method. .

Hereinafter, first, the dust collector 20 will be described in more detail.

The dust collector 20 is disposed adjacent to the dust suction unit 10. In addition, the dust collector 20 includes a sensor 21 for detecting a moving object, and operates when the moving object is detected by the sensor 21.

Here, the dust collector 20 disposed adjacent to the dust suction unit 10 may mean that the dust collector 20 is disposed adjacent to the dust suction unit 10, as shown in FIG. It may also mean that the 20 is disposed in contact with the dust suction portion 10.

For example, when the sensor 21 provided in the dust collector 20 can detect a moving object approaching the dust suction unit 10 or when a person located on the dust suction unit 10 reaches out a hand. The dust collector 20 may mean that the dust collector 20 is provided close to the dust suction unit 10 to the extent that the dust collector 20 can be reached.

Here, the moving object may be, for example, a person such as a visitor, an accessor, a truck, or the like.

The dust collector 20 does not always operate, but operates only when a moving object is detected to enter the entrance and exit, thereby realizing a more efficient dust suction system 1.

Conventionally, in order to prevent deterioration of aesthetics, the dust collector is provided at a position far from the dust suction apparatus so that the dust collector is not exposed to the outside as much as possible. For this reason, the dust collector was connected with the device which sucks in dust through a long hose, and sucked in dust.

However, in this case, the suction power of the dust collector is weak in the process of sucking dust through the long hose, there is a problem that the efficiency of sucking dust, that is, the dust collection efficiency is lowered. In addition, there is a problem in that a space for installing a long hose connecting the dust collector and the device for sucking dust is required.

Thus, the dust suction system 1 is disposed in the dust collector 20 adjacent to the dust suction portion 10, to prevent the suction force of the dust collector 20 is lowered to increase the dust collection efficiency, the space for installing a long hose There is no need to secure.

On the other hand, when the sensor 21 is provided in the dust collector 20 disposed adjacent to the dust suction unit 10, the sensor 21 is also positioned adjacent to the dust suction unit 10, so that the sensor 21 It is possible to set to detect the moving object approaching the dust suction unit (10). Therefore, the dust suction system 1 includes a sensor 21 for detecting a moving body in the dust collector 20 by utilizing the point that the dust collector 20 is disposed adjacent to the dust suction unit 10, and the dust collector ( 20 is activated only when the moving object is detected by the sensor 21. Through this, the dust collector 20 does not continue to operate, but only when there is a moving body, it is possible to prevent waste of energy.

On the other hand, in the related art, since the dust collector is provided far from the device for sucking dust, the sensor itself for detecting the moving body cannot be provided in the moving body. Therefore, in the related art, in some cases, a sensor may be provided at a position capable of detecting a moving object approaching a device for sucking dust such as a peripheral wall. However, it is difficult to provide a sensor when the conditions do not follow, such as no wall facing the moving object. In addition, in order to attach the sensor, it is necessary to further install a supporting member such as a bracket on the wall, etc. In this case, the installation process is cumbersome, and there is a problem that the aesthetics is degraded due to the installation of the supporting member.

However, since the dust collector 20 is disposed adjacent to the dust suction unit 10, the dust suction system 1 may include a sensor 21 in the dust collector 20 itself and include them as a modular unit. can do. Therefore, as in the related art, problems such as deterioration of aesthetics caused by separately arranging the dust collector and the sensor can be solved.

In summary, the dust suction system 1 may increase the suction power of the dust collector 20 through a configuration in which the dust collector 20 is disposed adjacent to the dust suction unit 10, and further utilizes the sensor ( By setting the dust collector 20 to operate only when the moving object is detected in 21, it is possible to prevent waste of energy. Thus, it is possible to implement an efficient dust suction system 1 as a whole.

As another example, the sensor 21 may be provided in the housing 100, but is not limited thereto.

The sensor 21 may be provided on one surface of the dust collector 20 to detect the moving object approaching the dust suction part 10 when the distance of the moving object with respect to the dust suction part 10 is within a certain distance.

For example, the sensor 21 may be provided on the upper surface of the dust collector 20 as shown in FIG. 1, or may be provided on the side surface of the dust collector 20.

In addition, the sensor 21 may detect, for example, the moving object approaching the dust suction part 10 from the front when the distance of the moving object with respect to the dust suction part 10 is within a certain distance. It may be provided on the front surface.

More specifically, referring to FIG. 1, the sensor 21 is provided on one surface of the dust collector 20 facing the 2 o'clock direction so as to detect a moving object approaching the dust suction unit 10 in an approximately 2 o'clock direction. Can be. In addition, referring to FIG. 1, the sensor 21 may be provided on one surface of the dust collector 20 facing the 4 o'clock direction so as to detect a moving object approaching the dust suction unit 10 at an approximately 4 o'clock direction. have.

At this time, the moving body approaching the dust suction unit 10 in the approximately 2 o'clock direction does not mean the moving body approaching the dust suction unit 10 at exactly 2 o'clock, and from 12 o'clock to 4 o'clock. Likewise, it may mean a moving body approaching the dust suction unit 10 in a wider direction.

Thus, by operating the dust collector 20 before the moving body steps on the dust suction unit 10, the moving body does not need to stop on the dust suction unit 10, but only by stepping on the dust suction unit 10, the dust collector ( 20) may inhale foreign matter attached to the moving body.

In exemplary embodiments, the sensor 21 may detect that the moving object approaches within about 2 m from the dust suction unit 10.

The dust collector 20 may be stopped after being operated for a predetermined time when the moving object is detected by the sensor 21.

In this way, the dust collector 20 is not driven continuously but is driven only for a necessary time, thereby preventing waste of energy and driving efficiently. In addition, there is no need to manually stop the dust collector 20, it is convenient.

The dust collector 20 may be stopped after operating for 1 to 10 seconds. For example, when the moving object traverses the dust suction unit 10 for about 1.5 seconds to about 2 seconds (about 2 beams to about 3 beams), the dust collector 20 is about 3 seconds to about 8 seconds. It can be stopped after it is activated. However, the present invention is not limited thereto, and the time at which the dust collector 20 is driven may be adjusted as necessary.

As another example, the dust collector 20 may further include a sensor for detecting a moving object staying on the dust suction part 10, in addition to the sensor 21 for detecting a moving object approaching the dust suction part 10. . As such, when the dust collector 20 includes a double sensor, when there is a moving body that stays on the dust suction unit 10 to remove a large amount of foreign matter, the dust collector 20 may be continuously operated without stopping. That is, the dust collector 20 detects a moving object approaching the dust suction unit 10 to drive the dust collector 20, and detects a moving object staying on the dust suction unit 10 to operate the dust collector 20. It may also include a sensor to hold.

At this time, the sensor for detecting the moving object staying on the dust suction unit 10 may be provided on the side facing the dust suction unit 10 of the dust collector 20.

The dust collector 20 may include a disinfecting unit 23 for spraying disinfectant material for disinfecting the moving body.

By utilizing the point that the dust collector 20 is disposed adjacent to the dust suction unit 10, the dust collector 20 is provided with a disinfection unit 23, the moving body removes the foreign matter while passing through the dust suction unit 10 and Can be disinfected at the same time. Through this, it is possible to more reliably block foreign matter flowing into the inside.

For example, a visitor or a person can hand disinfect by putting a hand in the disinfection unit 23 on the dust suction unit 10.

However, the present invention is not limited thereto. For example, the disinfecting unit 23 may be interlocked with the sensor 21 to automatically spray disinfectant toward the moving object when the moving object is detected by the sensor 21. In the same way, it is possible to disinfect a part or device that needs to be disinfected.

Referring to FIG. 1, the disinfecting unit 23 may include a hand sterilizer provided at an upper side of the dust collector 20 on the side of the dust suction unit 10.

Through this, since people can reach the disinfecting unit 23 by simply reaching out on the dust suction unit 10, the hand can be easily disinfected.

The dust collector 20 may include a voice support unit for transmitting a prestored voice.

When the sensor 21 detects the moving object, the voice support unit may transmit information about the disinfecting unit 23 as voice. In addition, as an example, when the sensor 21 detects the moving object, the voice support unit may transmit information about the dust suction unit 10 as a voice.

By using the point where the dust collector 20 is disposed adjacent to the dust suction unit 10, by providing the voice support unit in the dust collector 20, it is possible to help guide the walking of the moving object passing through the dust suction unit 10, and disinfect. It can be informed that the disinfection is possible through the part 23.

Here, the pre-stored voice may be, for example, notice that the dust suction unit 10 in front of the moving object to be careful, or that the disinfection may be possible through the disinfecting unit 23. Through this, the door guide and the hearing of the visually impaired can help the elderly walking safely, and can inform the information about the disinfecting unit (23).

Alternatively, the prestored voice may be a greeting or welcome message.

The voice support unit may include a speaker provided on one surface of the dust collector 20 on the side of the dust suction unit 10. Through this, the voice can be smoothly delivered to the moving object.

In addition, the voice support unit may automatically send a voice when there is a moving object approaching the dust suction unit 10, it is possible to implement a more convenient and efficient dust suction system (1).

The dust collector 20 may be provided with a hose 27 connectable to a foreign matter removal auxiliary unit (not shown) that is driven to remove foreign matters by using the power of the dust collector 20.

Since the dust collector 20 is located close to the dust suction unit 10, the dust suction unit 10 may be assisted by the dust suction unit 10 through a foreign matter removal auxiliary unit connected to be driven by the power of the dust collector 20. It is possible to remove the extraneous foreign matter which cannot be sucked through. For example, the foreign material removal auxiliary unit may be a unit capable of steam vacuuming.

The dust collector 20 may include a collecting unit for collecting a foreign substance. In exemplary embodiments, the collecting part may be a dust bag. In order to maintain the cleanliness and to facilitate the collection of foreign matter, the collecting section can be replaced periodically.

In addition, the dust collector 20 may include a sterilization unit for removing bacteria contained in the foreign matter. In exemplary embodiments, the sterilization unit may be a sterilization lamp.

Here, the germicidal lamp can remove the mold by the ultraviolet light emitting.

For example, the sterilization unit may be provided between the collecting unit and the filter unit to remove various bacteria included in the collected foreign matter.

In addition, the dust collector 20 may include a filter unit for filtering out the foreign matter remaining in the air passing through the collecting unit. In exemplary embodiments, the filter unit may be a hepa filter. Through this, the filter unit may filter foreign matters that are not collected in the collecting unit, such as fine dust.

In addition, the filter unit may be an antibacterial filter. Through this, it is possible to prevent the filter unit from being contaminated with bacteria, thereby maintaining the cleanness of the filter unit.

The dust collector 20 may first collect foreign substances through the collecting unit, secondly block harmful substances through the sterilizing unit, and thirdly filter the foreign substances through the filter unit to discharge air to the outside. have.

Therefore, the dust collector 20 of the present dust suction system 1 can have a high dust collection rate, and can effectively collect various harmful substances attached to the fine dust together with the fine dust, so that their entry into the room can be reliably blocked. Therefore, a more comfortable indoor environment can be maintained.

Referring to FIG. 1, the dust collector 20 may include an operation panel 25.

The operation panel 25 may be provided with a touch button. Therefore, the user may select to disinfect the disinfecting material from the disinfecting unit 23, or may manually control the on (off), off (off) of the dust collector (20).

In addition, the operation panel 25 may be provided with a display unit. An operation state of the dust collector 20 may be displayed on the display unit, or a guidement indicating that hand disinfection is possible through the disinfecting unit 23 may be displayed.

The dust collector 20 may be automatically operated when the sensor 21 detects a moving object, may be operated through the operation panel 25, or may be operated wirelessly through a remote controller or the like. Through this, the dust collector 20 can be controlled at a long distance.

In addition, the dust collector 20 may be connected to a central management system (not shown).

Through this, the dust collector 20 can be managed by the central management system if necessary. For example, the central management system may manage the dust collector 20 as a whole through a wireless method such as a wired method, Wi-Fi, and Bluetooth.

For example, the central management system may check in real time whether the dust collector 20 is operating normally, and notify the external manager when the dust collector 20 is abnormally operated. More specifically, the central management system, as well as the case that the suction of the foreign matter due to the motor failure of the dust collector 20, etc., as well as the operation panel 25, the voice support unit, disinfection unit 23, the sensor 21 and the like. You can also check the failure in real time.

In addition, the central management system can determine the number of operations of the dust collector 20, the number of moving objects detected by the sensor 21, and the like. Through this, it is possible to check the number of floating population during the day, the number of floating population by time, etc., it is possible to calculate how often to replace the collecting unit, filter unit, sterilization unit and the like. In addition, the central management system may determine the number of disinfectant injections of the disinfecting unit 23, and calculate how periodically to disinfect the disinfectant.

In addition, the central management system may adjust the strength of the suction force of the dust collector 20 as necessary. For example, when a lot of foreign matter is buried in the sole of the shoe (S), such as a snowy day, the suction force of the dust collector 20 can be flexibly adjusted, such as by operating the suction force of the dust collector 20 strongly.

In addition, the central management system, if necessary, the dust collector 20 is set to be operated only through a manual operation method using the control panel 25, a remote control, or the like, or automatically operated, such as when the sensor 21 detects a moving object. It is also possible to set the operation method of the dust collector 20, such as to set the operation only through the method.

The dust collector 20 may include a dust collecting unit provided in an area for collecting dust (dust bag area) and a water filter unit provided in an area for filtering water (water filtering area). In addition, the dust collector 20 is a selection switch for selecting the dust suction unit 10 to be connected to any one of the dust collecting unit and the water filter unit, and the dust suction unit 10 is the dust collecting unit or the water filter unit by the selection switch. It may include a direction switching unit is switched to be connected with.

In exemplary embodiments, the dust bag region may be a region provided with the above-described collecting unit, the sterilizing unit, and the filter unit.

Referring to FIG. 6, the dust collector 20 may include a diverter valve (an electronic valve or a mechanical valve) such that the dust suction unit 10 is connected to one of a dust bag region and a moisture filtering region including a filter such as a HEPA filter. It may include a selection switch for adjusting the. Through this, the dust suction unit 10 may be switched to be connected to the dust bag region or the moisture filtering region of the dust collector 20 according to the needs.

For example, referring to FIG. 6, in a general environment, the dust suction unit 10 may be switched to be connected to the dust bag region of the dust collector 20 through a direction switching valve, and may be externally introduced with water when raining. For a space where water is always present in the space or the bottom, the dust suction unit 10 may be switched to be connected to the water filtering region of the dust collector 20 through a direction switching valve.

For example, when the dust collector 20 is switched to the water filtering region, the dust collector 20 may be connected to a separate pipe hose to allow moisture to be discharged.

At this time, the dust bag region is a post-treatment is simple, but the water filtering region requires that the post-treatment is often confirmed compared to the dust bag region, as shown in Figure 6, separating the dust bag region and the water filtering region Each area can be managed separately.

Hereinafter, the dust suction unit 10 will be described in more detail.

The dust suction part 10 includes a housing 100.

The inner region of the housing 100 may be divided into a plurality of regions.

Each of the inner regions of the housing 100 is preferably divided into independent regions. At this time, foreign matter may be sucked in each divided area individually. In this case, a stronger suction force can be transmitted to each region than in the case where the inside of the housing 100 is not divided, so that the flow performance of foreign matter for discharge can be improved.

An inner region of the housing 100 may be divided into partitions 150, for example, as shown in FIG. 5. The partition wall 150 may be formed in the vertical direction of the housing 100 to partition an inner region of the housing 100 in the horizontal direction.

In addition, the housing 100 may be provided with a foreign matter discharge port 170 connected to each area so that foreign matters coming from each of the inner regions of the housing 100 divided into a plurality are collected.

As illustrated in FIG. 5, the foreign matter outlet 170 may be provided at one side of the housing 100. In addition, the foreign material outlet 170 may be connected to one side of the dust collector (20).

The foreign matter outlet 170 may collect foreign matter from each of the inner regions of the housing 100 through the suction force of the dust collector 20, and send the foreign matter to the dust collector 20.

The housing 100 has a plurality of inflow holes 111 formed thereon.

Referring to FIG. 3, the inflow hole 111 serves as a passage through which foreign matter such as soil buried in the sole of the shoe S is sucked into the housing 100.

The plurality of inflow holes 111 may be formed to be spaced apart at predetermined intervals on the upper portion of the housing 100. For example, when the dust suction unit 10 is provided at the entrance of a building with a large flow population such as a hospital, a large shopping mall, a department store, the inflow hole 111 may be formed at a narrower interval. In this case, the predetermined interval may be the same interval or may be different intervals.

Inlet hole 111 may be formed in a variety of shapes, such as circular, oval, polygonal.

The size of the inflow hole 111 may be selected as needed. For example, when the dust suction unit 10 is provided in a hospital, a large shopping mall, a department store, or the like, since the flow population is large, the inflow hole 111 may be formed relatively large so that a larger amount of foreign matter is sucked. At this time, when the inlet hole 111 has a circular shape, the size of the inlet hole 111 may mean the diameter of the inlet hole (111).

The plurality of inflow holes 111 may be formed to have a predetermined size, or may each be formed to have a different size as needed.

The inflow hole 111 is opened when the support member 350 is moved downward by the pressure applied to the head 330 from the upper side of the housing 100.

Here, the pressure applied to the head 330 may be a pressure applied in an oblique direction toward the head 330 from the upper side of the housing 100, or may be a pressure applied in the vertical direction.

Referring to FIG. 3, when the shoe S presses the head 330, the entire driving unit 300 is elastically moved downward by the elastic unit 500. Accordingly, the support member 350 which blocks the lower side of the inflow hole 111 is elastically moved downward to be spaced apart from the lower side of the inflow hole 111 so that the inflow hole 111 is opened and the inflow hole 111 is opened. Foreign matter may be sucked into the housing 100 through the).

2 and 3, the upper circumference of the inflow hole 111 may be formed in a taper shape.

Some of the foreign matter on the shoe S may fall on the upper plate 110. In this way, if the foreign matter placed on the upper plate 110 is left as it is, there is a risk that foreign matter may be introduced or dropped into an unwanted place.

Thus, by forming the upper periphery of the inlet hole 111 in a tapered shape, such foreign matter can flow into the inner circumferential surface of the inlet hole 111 to be sucked into the interior of the housing 100. Therefore, it is possible to minimize the foreign matter present in the unwanted place.

The height of the housing 100 may be formed low. Through this, it is possible to secure the walking stability of the moving object. In exemplary embodiments, the height of the housing 100 may be about 16 mm or less.

The housing 100 may include a top plate 110 on which a plurality of inflow holes 111 are formed.

The upper surface of the upper plate 110 may be provided with a display unit 120 for displaying information about the dust suction unit 10.

In this case, the display unit 120 may be provided at the edge of the upper surface of the upper plate 110, as shown in FIG. As such, the display unit 120 may be provided at a position to more smoothly transmit the information on the dust suction unit 10.

Referring to FIG. 1, the display 120 may display a walking direction. In exemplary embodiments, the display unit 120 may be provided as an LED, an LCD, or the like.

In addition, the display unit 120 may display information when the dust collector 20 operates. That is, when the moving object approaches the dust intake unit 10, by displaying the information, it is possible to transfer the information to the moving object.

Although not shown, the display 120 may include a mood light. Through this, aesthetics can be improved.

In addition, the housing 100 may include a lower plate 130 for arranging the opening and closing member 400 at a position corresponding to each of the plurality of inflow holes 111.

The opening and closing member 400 may include a driving unit 300 and an elastic unit 500 as described below.

The lower plate 130 may include a plurality of protruding units 131 protruding upward at a position corresponding to the inflow hole 111.

Referring to FIGS. 2 and 3, the upper plate 110 and the lower plate 130 may be spaced apart from each other so that the driving unit 300 and the elastic unit 500 may be provided therebetween.

In order to extend the life of the dust suction unit 10, the upper plate 110 and the lower plate 130 may be made of a material having high rigidity, corrosion resistance and oxidation resistance.

In addition, the upper plate 110 through which the moving object traverses may be made of a material including at least one of an antibacterial function component, a sterilization function component, a deodorizing function component, and an anion generating function component.

For example, the upper plate 110 may be formed of NF-α. NFC Alpha is a new material made by combining functional ceramic materials and two or more natural minerals. NFC alpha is a natural mineral containing essential components for the human body, which is sufficient as a material for a single radiator, and is rich in far-infrared emission.

The NFC alpha may include various minerals, and for example, may include the first natural mineral and the second natural mineral as described below.

7 to 15 are test reports or test reports for explaining component analysis, properties, and the like of NFC alpha. Here, FIG. 7 is a test report analyzing the components of the first natural mineral that may be included in the NFC, and FIG. 8 is a test report analyzing the components of the second natural mineral that may be included in the NFC, and FIG. 9. 15 to 15 are test reports for the NFC alpha including the first natural mineral of FIG. 7 and the second natural mineral of FIG. 8.

First, as an example of natural minerals that may be included in the NFC, the components of the first natural mineral and the second natural mineral are as follows.

The first natural mineral is a macrorite (pegmatite), the first natural mineral, as shown in Figure 7a, cerium (Ce) 106 mg / Kg, selenium (Se) 1.74 mg / Kg, gadolinium (Gd) is 1.88 mg / Kg, Holmium (Ho) 0.25 mg / Kg, Lanthanum (La) 41.1 mg / Kg, Neodymium (Nd) 27 mg / Kg, Prasedium (Pr) 7.05 mg / Kg, Samarium (Sm ) 4.7 mg / Kg, thorium 16.5 mg / Kg, and germanium (Ge) 1.27 mg / Kg.

Here, germanium is an essential ingredient for human nutrition that neutralizes heavy metals and reduces oxygen deficiency by ion elution. It supplies oxygen to the body, pulverizes toxic contaminants, and produces inteferol, which is anti-cancer activity in the body. It plays an important role and not only destroys cancer cells but also cleanses the blood.

Holmium is an element that is injected into the body and used as a liver cancer treatment to treat liver cancer and a skin cancer treatment to treat skin cancer.

Selenium is an essential ingredient that helps the human body's health. It is not only effective for adult diseases such as cancer, heart disease, arthritis, and sexual enhancement, but also reduces the toxicity of heavy metals such as mercury, lead, and cadmium.

Cerium is a type of mineral that is essential for human effects.

In addition, in the first natural mineral, as shown in FIG. 7B, 67.1% SiO ₂ , 13.9% Al ₂ O ₃ , 2.81% Na ₂ O, 2.9% Fe ₂ O ₃ , 3.08% CaO, and MgO 1.75%, K ₂ O 3.12%, TiO ₂ 2.75%, ZrO ₂ 0.01%, MnO ₂ 0.05%, P ₂ O ₅ 0.14%, SrO 0.06%, BaO 0.1%, ZnO 0.01 % Is included.

As shown in FIG. 8A, in the second natural mineral, SiO ₂ is 76.5%, Fe ₂ O ₃ is 0.68%, TiO ₂ is 0.02%, Al ₂ O ₃ is 13.4%, CaO 1.09%, MgO 0.12% , K ₂ O is 3.68% and Na ₂ O is 1.82%.

Sodium is an indispensable substance for maintaining life through various physiological effects such as neurotransmission and heart pulse of the human body, and performs an important physiological function of regulating cell fluid and blood pressure such as blood or body fluid.

Calcium is used for the treatment of osteoporosis, fractures, tooth decay, and physiological effects, high blood pressure, diarrhea, diabetes, allergic diseases, hepatic diseases, etc.

Potassium is a chemical defense against myocardial infarction, which aids in health, and when deficient, tilts body fluids to acidity and reduces enzyme activity.

Magnesium helps calcium metabolism, strengthens bones and teeth, plays an important role in minerals that are essential for the activity of enzymes involved in the synthesis of nucleic acids from carbohydrate metabolism, lipid metabolism, and protein metabolism.

Silicon is used a lot in living water purification.

7B and 8B, it can be seen that each of the first natural mineral and the second natural mineral does not contain heavy metal materials such as Pb, Cd, Cr, Ni, As, and Hg, which are harmful to the human body.

EN Alpha, which contains such natural minerals, contains alkaline ions such as sodium, calcium, potassium, and magnesium, which are common minerals that alkalize oxidized blood, and germanium (Ge) and selenium. Special ingredients such as (Se), cerium (Ce) and holmium (Ho) are excellent in cell activation, blood circulation, metabolism strengthening, and tissue regeneration in the body. In particular, the ingredients include a large amount of germanium to crush the toxic substances of the human body and holmium to emit radiation, nF alpha can be used in the treatment of liver cancer, interferol and skin cancer drugs that act anti-cancer.

In addition, NF Alpha contains natural minerals with antibacterial function, sterilization function and deodorization function, so it is rich in far infrared emission, effective in removing odors, effective in blocking direct sunlight and blocking electromagnetic waves, and resisting bacteria. It can also have a function to. In particular, the effects of the far-infrared rays emitted by NF alpha on the human body include temperature increase in the subcutaneous layer, expansion of microvessels, acceleration of blood circulation, metabolism, and increase of tissue regeneration ability. It has an excellent effect on disease, and when such far infrared rays are absorbed in vivo, metabolism is promoted, blood circulation is improved, enzyme production is revived, and aged cells are activated to promote waste and extra fat excretion. The production of lactic acid, free fatty acids, fatty acid esters, cholesterol, excess salt, and uric acid, which cause fatigue and aging, are suppressed.

In addition, NFC alpha is harmless and non-toxic and has no side effects on the human body.

When the top plate 110 is formed of such a material, the top plate 110 can be prevented from being contaminated from bacteria and can be used in a clean state for a long time. In addition, in some cases, when stepping through the dust inhalation portion 10 barefoot, the air flows between the toes by the suction of the dust collector 20, due to the sterilization function and deodorizing function of the top plate 110 itself, the top plate 110 ) Can also be expected to prevent foot odor or athlete's foot infection. In addition, negative ions from the functional material can help the blood circulation of the human body.

Referring to FIG. 9, the NF alpha has a high flash point and a flash point, and is safe, and has chemical stability without a water reaction risk, an acid risk, and a magnetic reaction risk at room temperature. In addition, NFC alpha has a high melting point, low specific gravity, and water-insoluble properties at room temperature.

10 is a test report of the far-infrared emission of the health necklace bracelet product containing NFC alpha, Figure 11 is a test report of the far-infrared emission amount of the functional coating containing NFC alpha. Through this, as described above, it can be confirmed that the NFC alpha is rich in far-infrared emission.

12 is a test report showing the results of the antimicrobial test of NFC alpha. As shown in FIG. 12, it can be seen that the viable cell count of the antimicrobial processed specimens processed with EN alpha is much smaller than the viable cell number of the raw sample. Through this, it can be confirmed that the antibacterial function of the NFC alpha is excellent.

FIG. 13 is a test report showing that a large amount of germanium (Ge) is contained in a component of EN Alpha. FIG. Through this, it can be seen that the NFC alpha has an excellent effect of grinding the toxic substances in the human body.

14 is a test report for testing the deodorizing effect of the NFC alpha, through which, it can be confirmed that the alpha alpha deodorizing function is good.

15 is a test report on the amount of negative ions released by the NFC alpha, it can be seen that the alpha alpha releases a large amount of anions.

For example, the top plate 110 may be injection molded using a functional resin material containing a component having such a function.

The protruding unit 131 may be integrally formed with the lower plate 130. For example, the lower plate 1315 and the protruding unit 131 may be integrally formed through injection. Through this, the protruding unit 131 may be formed more firmly, and there is no room for forming a gap between the lower end of the protruding unit 131 and the lower plate 130, thereby improving airtightness.

The protruding unit 131 may mount the elastic unit 500.

2 and 3, the protruding unit 131 may have an elastic unit 500 mounted therein, and although not shown in the drawing, the protruding unit 131 may have a shape in which a lower portion of the elastic unit 500 can be inserted, such as a protrusion shape. May have

Through this, the elastic unit 500 may be disposed in the vertical direction from the lower portion of the inlet hole 111. Therefore, the elastic unit 500 may support the driving unit 300 to be described later is inserted into the inlet hole 111 so as to elastically move.

2 and 3, a protruding unit groove 1313 into which a lower portion of the elastic unit 500 is inserted may be formed on an upper surface of the protruding unit 131. Through this, the lower portion of the elastic unit 500 may be mounted inside the protruding unit 131.

The sole of the shoe (S) may be soiled with dirt, as well as foreign matter such as moisture. When the sole of the shoe S comes in contact with the driving unit 300 in a state in which foreign matter such as moisture is attached, such foreign matter may be introduced into the housing 100 through the inflow hole 111.

In general, the elastic unit 500 is made of a metal material having a high rigidity to withstand the load applied to the drive unit 300. However, when foreign matter such as moisture is deposited on the elastic unit 500 made of such metal, the elastic unit 500 may be corroded. Therefore, there was a problem that the periodic replacement of the elastic unit 500 is required.

Thus, the dust suction unit 10 is inserted into the protrusion unit groove 1313 by inserting the elastic unit 500 to the inside of the protrusion unit 131, foreign matter such as moisture introduced into the interior of the housing 100 The elastic unit 500 may be introduced to prevent the elastic unit 500 from corroding. Therefore, the trouble of periodically replacing the elastic unit 500 can be eliminated, and the cost of replacement can be reduced.

The bottom surface of the protruding unit groove 1313 may have a fastening portion 1315 to which the lower end of the elastic unit 500 is fixed.

2 and 3, the lower end of the elastic unit 500 is inserted into the fastening part 1315, so that the elastic unit 500 is not detached and stably presses the driving unit 300 as described below. I can support it.

In this case, the fastening part 1315 may be formed integrally with, for example, the protruding unit 131 and the lower plate 130. Through this, the airtightness can be increased, and the fastening part 1315 can be formed more firmly.

The protruding unit 131 may be inserted into the body groove 313 so that the outer circumferential surface thereof corresponds to the inner circumferential surface of the body groove 313 so as to guide the elastic movement of the driving unit 300 in the vertical direction.

Here, referring to FIG. 3, when the driving unit 300 moves upward or downward, the outer circumferential surface of the protruding unit 131 and the inner circumferential surface of the body groove 313 maintain a predetermined contact relationship. For example, it may mean that only a part of the contact is not shaken or the tolerance is not generated. At this time, the degree of contact or the degree of tolerance means the degree to which the elastic movement of the drive unit 300 can be guided.

As such, the inner circumferential surface of the body groove 313 is moved along the up and down direction of the outer circumferential surface of the protruding unit 131 facing the same, thereby guiding the driving unit 300 so as not to deviate from the path of elastic movement.

The outer circumferential surface of the protruding unit 131 and the inner circumferential surface of the body groove 313 may be partially overlapped in the vertical direction in a state in which the inlet hole 111 is closed by the support member 350.

Here, the partial overlap in the vertical direction may mean that a part of the outer circumferential surface of the protrusion unit 131 and a part of the inner circumferential surface of the body groove 313 face each other as shown in FIGS. 2 and 3.

When the dust suction unit 10 is provided outside, a large amount of rainwater flows through the inlet hole 111 at the same time when the inlet hole 111 is opened, so that water may be filled in the housing 100. have. As such, when a large amount of foreign matter, such as moisture coming in through the inlet hole 111, enters the protruding unit groove 1313, the elastic unit 500 is elastic only by being provided inside the protruding unit 131. It is not possible to prevent corrosion of the unit 500.

Thus, the elastic unit 500 may be provided so as not to be exposed to the inside of the housing 100 in the body groove 313 and the protruding unit groove 1313. Thus, the elastic unit 500 can be blocked to the maximum extent possible.

At this time, the outer circumferential surface portion of the protruding unit 131 and the inner circumferential surface of the body groove 313 in a state in which the inflow hole 111 is closed in order to prevent foreign substances such as moisture from entering the protruding unit groove 1313 to the maximum. Some may be in close contact.

The dust suction unit 10 includes an opening and closing unit 400.

The opening and closing unit 400 may include a driving unit 300.

The drive unit 300 includes a body 310.

2 and 3, the body 310 is disposed with at least a portion inserted into each of the inflow holes 111 in the housing 100 by upward pressurization of the elastic unit 500.

The body 310 is elastically moved downward when an external force is applied to the head 330.

In addition, the driving unit 300 includes a head 330 connected to the upper side of the body 310.

By upward pressurization of the elastic unit 500, the head 300 is disposed in a state in which at least a portion protrudes onto the inlet hole (111).

2 and 3, the head 330 is directly in contact with the sole of the shoe S from the upper side of the housing 100. When an external force is applied to the head 330, it is elastically moved downward.

As shown in FIG. 4, the head 330 may have a circular cross section except for the protruding member 331, but is not limited thereto. In some cases, the cross section of the head 330 may have a polygonal shape such as a quadrangle.

When the head 330 is applied with pressure, the head 330 may be elastically moved into the inflow hole 111.

In this case, the thickness b of the inflow hole 111 may be greater than the thickness a of the head 330.

Here, the thickness b of the inflow hole 111 means the length in the vertical direction in which the inflow hole 111 is formed. In some cases, this may be understood as the thickness of the upper plate 110 of the portion of the upper plate 110 of the housing 100 in which the inlet hole 111 is formed.

In addition, the thickness (a) of the head 330 may be a thickness including a protruding member 331 formed on the top of the head 330 as shown in FIG.

2 and 3, when the thickness b of the inflow hole 111 is greater than the thickness a of the head 330, when the pressure is applied to the head 330 to move downward, the head 330 is moved. Does not exit to the lower side of the inlet hole 111, it can be moved only within the inlet hole (111). Therefore, it is possible to prevent the head 330, which is pressurized from the upper side of the housing 100, escapes to the lower side of the inflow hole 111 and gets caught in the housing 100.

At least one of the upper ends of the opening / closing member 400 may be formed of a material including at least one of an antibacterial function component, a sterilization function component, and an anion generating component.

Here, one of the upper ends of the opening and closing member 400 may be the head 330 shown in FIG.

In exemplary embodiments, the head 330 may be injection molded using a functional resin material. For example, the head 330 may be formed of NFC alpha. Through this, the head 330, as described in the upper plate 110, can help the blood circulation of the human body, can be prevented from being contaminated from bacteria, to prevent foot odor or transfer of athlete's foot You can also expect the effect.

In addition, there is an acupressure effect by the visitor or visitors stepping on the head 330.

A protruding member 331 protruding upward may be formed at an upper end of the head 330.

The protruding member 331 may serve to drop foreign matter remaining in the sole while being in contact with the sole of the shoe (S).

Referring to FIG. 4, the protruding member 331 may protrude radially to remove foreign matter.

2 and 3, the bottom surface of the groove formed between the radially protruding protruding members 331 may be formed in an inclined shape. Through this, foreign matters that are removed from the sole of the shoe S by the protruding member 331 and dropped on the bottom surface of the groove formed between the protruding members 331 flow into the inflow hole 111, so that the foreign matter is more smoothly. Can be inhaled.

The protruding member 331 is not limited to having a radial shape. For example, the protruding member 331 may be a brush.

In addition, the drive unit 300 includes a support member 350. The support member 350 is formed around the body 310.

By upward pressurization of the elastic unit 500, the support member 350 is disposed in a state of closing the inlet hole 111. That is, the support member 350 may open or close the lower side of the inflow hole 111 while being elastically moved.

More specifically, referring to FIG. 3, when the head 330 is pressed, the support member 350 is elastically moved downward along with the body 310 to open the inflow hole 111, and the head 330 is When not pressed, the body 310 is pushed upward by the elastic unit 500 to elastically move upwards to close the inflow hole 111.

In the conventional vibration damping device, the suction port is opened and closed by an upper surface on the hemispherical surface of the movable member, whereas the dust suction unit 10 is separate from a part of the driving unit 300 protruding onto the inflow hole 111, Opening and closing the inlet hole 111 through the support member 350 formed around the (300).

The dust suction part 10 is the support member 350 is normally closed the inlet hole 111, when the pressure is applied to the head 330 from the upper side of the housing 100 is moved downwards inlet hole 111 Open). That is, the driving unit 300 has a gap between the inlet hole 111 so that the upper portion and the inside of the housing 100 communicate with each other through the inlet hole 111 when the support member 350 is moved downward. Or may have a passageway in communication therewith. Such a gap or passage may be, for example, a gap 1111 described later.

The upper surface of the support member 350 may be made of an elastic material such as rubber. For example, a rubber packing may be provided on the upper surface of the support member 350, or rubber may be coated. Through this, the support member 350 may be in close contact with the lower surface of the upper plate 110, and the support member 350 is damaged even when the support member 350 repeatedly contacts the lower surface of the upper plate 110. You can stop it.

The head 330, the body 310, and the support member 350 may be integrally formed. Through this, the driving unit 300 can be easily manufactured. At this time, the head 330, the body 310, and the support member 350 is not limited to being integrally formed, the head 330 and the body 310 or the body 310 and the support member 350 ) May be integrally formed.

In addition, the head 330 may be made of a material including a component having an antibacterial function, a component having an anion generating function, a component having a photocatalyst deodorizing function, and the like. Through this, the driving unit 300 can be maintained in a clean state. At this time, the body 310 and the support member 350 may also be made of a material containing such a component.

In addition, at least one interior of the body 310 and the support member 350 may be made of a material including a component having a photocatalytic sterilization deodorization function. Since foreign matter is sucked into the housing 100 and thus many pollutants exist, the interior of the body 310 and the support member 350 may be made of a material having a faster sterilization function, so that a clean state may be maintained. .

When the driving unit 300 moves downward, a predetermined gap 1111 is formed between the inner circumference of the inflow hole 111 so that the upper side and the inside of the housing 100 communicate with each other through the inflow hole 111. Can have

In the conventional vibration damping device, the suction port is opened and closed by the upper surface on the hemispherical surface of the movable member, so that the upper surface on the hemispherical surface closes the suction port so that when the upper surface on the hemispherical surface is pressed obliquely, the movable member moves obliquely downward. The position (center of the hemispherical surface corresponding to the center of the circular suction port) may not be returned to the circular suction port but may be offset from the circular suction port. In addition, when the action of the oblique external force is repeated several times, the upper surface on the hemispherical surface may be separated from the movement path and caught in the suction box. In addition, when pressing the movable member at an angle, the upper surface on the hemispherical surface could not be smoothly moved downward caught on the circular suction port. Therefore, the conventional vibration damping device has a problem in that opening and closing of the circular suction port is difficult to be normally maintained under external force action in various directions, and foreign substances cannot be sucked properly.

On the other hand, the dust suction unit 10, as shown in Figures 2 and 3, because the gap 1111 is formed between the drive unit 300 and the inner circumference of the inlet hole 111, the drive unit 300 ) Is obliquely lowered to leave the correct position, or can be prevented from being caught in the housing (100). In addition, the dust suction unit 10 may smoothly move downward without being caught around the inlet hole 111 even when the driving unit 300 is pressed in an oblique direction. Therefore, the dust suction unit 10 can normally maintain the opening and closing of the inlet hole 111 with respect to the external force action in various directions, it is possible to smoothly suck the foreign matter.

The gap 1111 may be formed in the vertical direction.

For example, the gap 1111 may be formed in the vertical direction as shown in FIGS. 2 and 3, and may be formed to be slightly inclined although not shown in the drawing.

The lower surface of the driving unit 300 may be formed with a body groove 313 into which the upper portion of the elastic unit 500 is inserted.

2 and 3, an upper portion of the elastic unit 500 may be mounted inside the driving unit 300. Therefore, foreign substances coming into the housing 100 through the inflow hole 111 may be prevented from entering the elastic unit 500.

At this time, as shown in Figures 2 and 3, the bottom surface of the body groove 313 (the upper reference surface of Figure 2) may be further formed with a groove into which the upper end of the elastic unit 500 can be fitted. Therefore, the inner circumferential surface of the groove is in close contact with the outer circumferential surface of the elastic unit 500, so that the elastic unit 500 can stably support the driving unit 300.

The opening and closing unit 400 may include an elastic unit 500.

The elastic unit 500 supports the driving unit 300 by pressing the driving unit 300 upward so that the inlet hole 111 is closed by the support member 350.

The elastic unit 500 is preferably provided in a compressed state to some extent to push the drive unit 300 in the upward direction.

As shown in FIG. 3, when pressure is applied to the driving unit 300 from the upper side of the housing 100, the elastic unit 500 is elastically compressed to allow the driving unit 300 to move downward.

The elastic unit 500 may be, for example, a spring, but is not limited thereto.

In addition, the elastic unit 500 has a rigidity enough to withstand the load applied to the drive unit 300, it is preferably made of a material having excellent corrosion resistance and oxidation resistance.

The dust suction unit 10 may include a heat generating unit (not shown) for dissipating heat to the upper side of the housing 100.

Through this, the dust suction system 1 can be used outdoors in winter.

In this case, the heating unit may be provided inside the housing 100.

For example, the heating unit may be provided in the form of a hot wire inside the housing 100. For example, the heat generating unit may be provided on the lower surface of the upper plate 110 to melt heat accumulated on the upper surface of the upper plate 110 by conducting heat to the upper surface of the upper plate 110.

At this time, the snow accumulated on the upper plate 110 melts and flows into the inlet hole 111 and accumulated on the lower plate 130 may be evaporated by the convection of heat generated by the heat generating unit.

In addition, as described above, when the water introduced through the inlet hole 111 contacts the elastic unit 500, the elastic unit 500 may corrode. However, the present application may fundamentally block the introduction of foreign matter such as moisture into the protrusion unit groove 1313 on which the elastic unit 500 is mounted through the protrusion unit 131 described above. In addition, by evaporating and removing moisture remaining on the lower plate 130 through the heat generating unit, the elastic unit 500 may also be prevented from being gradually corroded under high humidity.

However, the present invention is not limited thereto, and the heating unit may be provided to supply warm air to the inside of the housing 100 so that the top plate 110 is warmed.

Referring to FIG. 1, the dust suction unit 10 may include one or more dust suction units 112 in a modular form.

According to the scale of the place where the dust suction system 1 is installed, the size of the dust suction portion 10 needs to be adjusted.

For example, in a relatively narrow entrance such as an apartment entrance, the size of the dust suction unit 10 may be reduced to be installed only in a narrow space. However, since the floating population is large, such as a department store or a large mart, the exterior may be large in a wide entrance. In order to inhale foreign matter introduced from the maximum, it is preferable to increase the size of the dust suction unit 10 and install it over a wide space.

For this reason, when the dust suction unit 10 is formed in a predetermined size according to a certain place, when it is moved to a place having a different size, the inflow of foreign matter cannot be effectively blocked.

Thus, the dust suction unit 10 of the dust suction system 1 is formed through the modularization of the plurality of dust suction units 112, as shown in Figure 1, the dust suction unit 10 according to the size of the place You can flexibly adjust the size of). Therefore, the dust suction system 1 can easily and efficiently adjust the size by simply adjusting the number of dust suction units 112 to be connected, without having to newly form the dust suction unit 10 according to the size of the place. Can be.

As described above, the housing 100 may be provided with a foreign matter discharge port 170 connected to each area so that foreign matters coming from each of the internal areas of the housing 100 partitioned into a plurality are collected. Although not clearly shown in the drawings, the housing 100 may be divided into a plurality of portions through the plurality of dust suction units 112. In addition, each of the dust suction unit 112 may be in communication with the foreign matter discharge port 170. That is, the foreign matter discharge port 170 may collect the foreign matter from each dust suction unit 112 through the suction force of the dust collector 20 and send it to the dust collector 20.

That is, simply replacing the housing 100 including the foreign matter discharge port 170 with a larger size, by increasing the size of the dust suction unit 10 by additionally placing the dust suction unit 112 inside the housing 100. Can be.

Conventionally, in order to prevent deterioration of aesthetics, the dust collector is provided at a position far from the dust suction apparatus so that the dust collector is not exposed to the outside as much as possible. For this reason, the dust collector was connected with the device which sucks in dust through a long hose, and sucked in dust.

However, in this case, the suction power is weak in the process of suctioning the dust through the long hose, there is a problem that the efficiency of sucking the dust, that is, the dust collection efficiency falls. In addition, there is a problem in that a space for installing a long hose connecting the dust collector and the device for sucking dust is required.

Thus, the dust suction system 1 is disposed in the dust collector 20 adjacent to the dust suction portion 10, to prevent the suction force of the dust collector 20 is lowered to increase the dust collection efficiency, the space for installing a long hose No need to secure

Furthermore, the dust suction system 1 includes a sensor 21 for detecting a moving body in the dust collector 20 by utilizing the point that the dust collector 20 is disposed adjacent to the dust suction unit 10, and the dust collector ( 20 is activated only when the moving object is detected by the sensor 21. Through this, the dust collector 20 does not continue to operate, but only when there is a moving body, it is possible to prevent waste of energy.

In addition, by utilizing the fact that the dust collector 20 is disposed adjacent to the dust suction unit 10, various types of sensors that can be provided to the moving body using the dust suction unit 10 as well as the sensor 21 for detecting the moving body. The modular dust collector 20 may be implemented by including both a disinfecting unit 23 capable of disinfecting at least a part of the moving object and a voice support unit transmitting various information toward the moving object. That is, by providing a dust collector 20 that performs a variety of such functions in a compact form, each of the devices for performing the dust collection function, a sensor device for detecting a person, a unit for providing various services, etc. Compared with the conventional one, the aesthetics can be improved.

In addition, in the conventional vibration damping device, the upper surface on the hemispherical surface of the movable member blocks the circular inlet port, and the restraint is maintained such that the upper surface on the hemispherical surface is in the correct position (the position of the center of the upper surface on the hemispherical surface corresponding to the center of the circular suction port). There was no separate point. Therefore, in the conventional vibration damping device, when the upper surface on the hemispherical surface is pressed obliquely, the movable member may be shifted obliquely and may be offset from the circular suction port without returning to the normal position. When such oblique external force was repeatedly applied several times, the upper surface on the hemispherical surface could escape the movement path and be caught in the suction box. In addition, when the movable member is pressed obliquely, the upper surface on the hemispherical surface was caught around the circular suction port and could not be moved smoothly downward.

On the other hand, the dust suction unit 10 is the driving unit 300 through the inlet hole 111 through the support member 350 provided on the lower side of the head 330 rather than the upper surface of the head 330 corresponding to the upper surface. Opening and closing, a gap 1111 may be formed between the driving unit 300 and the inner circumference of the inlet hole 111. Thus, since the driving unit 300 is elastically moved while being biased only within the range in which the gap 1111 is formed, the driving unit 300 may be returned to the correct position and thus the position may be maintained. Therefore, the driving unit 300 may be caught inside the housing 100, and may be smoothly moved downward even when pressed in an oblique direction. That is, the dust suction unit 10 may be elastically moved in the vertical direction to the drive unit 300 smoothly also against external force acting in various directions, it can be maintained so that the opening and closing of the inlet hole 111 is made normally. And the inhalation of foreign matter can be made properly.

In addition, the dust suction unit 10 may mount the elastic unit 500 inside the protruding unit 131 or completely prevent the elastic unit 500 from being exposed to the inner side of the housing 100. Even if the same foreign matter accumulates inside the housing 100, it is possible to prevent corrosion of the elastic unit 500.

It will be understood by those of ordinary skill in the art that the foregoing description of the embodiments is for illustrative purposes and that those skilled in the art can easily modify the invention without departing from the spirit or essential characteristics thereof. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive. For example, each component described as a single entity may be distributed and implemented, and components described as being distributed may also be implemented in a combined form.

The scope of the present invention is defined by the appended claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

1: dust suction system 100: housing
300: drive unit 500: elastic unit
110: top plate 111: inlet hole
130: lower plate 131: protrusion unit
150: bulkhead 170: foreign matter discharge portion
1111: gap 1313: protrusion unit groove
1315: fastening portion 350: support member
313: body groove 310: body
330: head 331: protruding member
112: upper plate member 120: display unit
10: dust suction unit 20: dust collector
21: sensor 23: disinfection unit
25: control panel 27: hose
400: opening and closing member

Claims (22)

In the dust suction system,
A dust suction unit including a housing having a plurality of inflow holes formed therein, and an opening and closing member provided inside the inflow hole and opening or closing the inflow hole by a pressure applied from an upper side of the housing; And
Is disposed adjacent to the dust suction portion, and includes a dust collector for sucking the foreign matter introduced into the inlet hole to the outside of the dust suction portion,
Wherein the dust collector comprises:
A sensor for detecting the collecting unit for collecting the foreign matter, a sterilizing unit for removing the bacteria contained in the foreign matter, a filter unit for filtering out the foreign matter remaining in the air passing through the collecting unit, and a moving object approaching the dust suction unit And a dust suction system that operates when the moving object is detected by the sensor. The method of claim 1,
And the sensor is provided on one surface of the dust collector to detect the moving object approaching the dust suction part when the distance of the moving object to the dust suction part is within a certain distance. The method of claim 1,
The dust collector, when the moving object is detected by the sensor, the dust suction system is to be stopped after being operated for a predetermined time. The method of claim 1,
The dust collector is a dust suction system that comprises a disinfecting unit for spraying disinfectant for disinfecting the moving body. 5. The method of claim 4,
The disinfection unit is a dust suction system comprising a hand sterilizer provided on the dust collector side of the dust suction side. 5. The method of claim 4,
The dust collector includes a voice support unit for transmitting a pre-stored voice,
The voice support unit, when the sensor detects the moving object, the dust suction system to send out information about the disinfection unit by voice. The method of claim 1,
The dust collector includes a voice support unit for transmitting a pre-stored voice,
The voice support unit, when the sensor detects the moving object, the dust suction system to send information about the dust suction unit by voice. The method of claim 1,
The dust collector, the dust suction system is provided with a hose connectable to the foreign matter removal auxiliary unit is driven to remove the foreign matter by the power of the dust collector. delete The method of claim 1,
The dust suction unit, the dust suction system is provided with one or more dust suction unit in a modular form. The method of claim 1,
The housing includes:
An upper plate having the plurality of inflow holes formed therein; And
And a lower plate for disposing an opening and closing member at a position corresponding to each of the plurality of inflow holes. The method of claim 11,
The upper surface of the upper plate, the dust suction system is provided with a display unit for displaying information about the dust suction unit. 13. The method of claim 12,
The display unit, the dust suction system to display the information on the dust suction unit when the dust collector is operating. The method of claim 1,
At least one of the upper plate of the housing and the upper end of the opening and closing member is a dust suction system comprising a material comprising at least one of an antibacterial function component, a sterilization function component, a deodorizing function component, an anion generating function component. 15. The method of claim 14,
At least one of the upper plate of the housing and the upper end of the opening and closing member is a dust suction system comprising a material containing a functional ceramic material and a natural mineral that emits far infrared rays. The method of claim 1,
The dust suction unit,
And a heating unit for dissipating heat to the upper side of the housing. 17. The method of claim 16,
The heating unit is a dust suction system that is provided inside the housing. The method of claim 1,
The open /
A drive unit including a body, a head connected to an upper side of the body, and a support member formed around the body; And
It includes an elastic unit for pressing the drive unit upward and elastically supported,
The driving unit is disposed in a state in which the support member closes the inflow hole by upward pressure of the elastic unit,
The inflow hole is a dust suction system that is opened when the support member is moved downward by the pressure is applied to the head from the upper side of the housing by the moving body. The method of claim 18,
The driving unit includes:
By the upward pressure of the elastic unit, the body is disposed in a state in which at least a portion is inserted into each of the inlet holes in the housing, the head is arranged in a state in which at least a portion protrudes onto the inlet hole. Dust suction system. The method of claim 19,
The driving unit includes:
And a predetermined gap between the inner circumference of the inflow hole so that the upper side and the inside of the housing can communicate with the inflow hole during the downward movement. 21. The method of claim 20,
The gap is a dust suction system is formed in the vertical direction. The method of claim 1,
Wherein the dust collector comprises:
A dust collecting unit provided in an area for collecting dust;
A moisture filter unit provided in an area for filtering moisture;
A selection switch for selecting the dust suction unit to be connected to any one of the dust collecting unit and the moisture filter unit; And
And a direction changing part for switching the dust suction part to be connected to the dust collecting part or the moisture filter part by the selection switch.

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