KR102098730B1 - Anti-fine particle type bus shelter - Google Patents

Abstract

The present disclosure secures atmospheric passengers from fine dust or fumes as the inside air of the bus stop booth is sucked and purified through a filter and an optical plasma and then sprayed with compressed air for air curtains to block the outside air of the bus stop booth. It relates to a bus stop for fine dust-blocking type that allows clean air to be protected and also purifies the surrounding air outside the bus stop through a chain sterilization reaction by optical plasma.
The micro-dust blocking bus stop booth according to an embodiment of the present disclosure has at least one side open and a booth main body to which commercial power is supplied, and is installed in the booth main body and operated by the commercial power source and inside the booth main body. An optical plasma air purification unit that sucks air inside to collect dust and foreign substances, sterilizes and sterilizes harmful bacteria and viruses through an optical plasma, and is installed on the upper part of the open surface of the booth body's ceiling. An air curtain communicating with the exhaust port side of the air purification unit to discharge air purified by the optical plasma air purification unit in a downward direction, and a controller installed in the booth body to control the operation of the optical plasma air purification unit Includes.

Description

Fine dust blocking type bus stop booth {ANTI-FINE PARTICLE TYPE BUS SHELTER}

The present disclosure relates to a bus stop booth installed near a bus stop where a bus stops for passengers to provide a space for passengers to wait for the bus.

Unless otherwise indicated in this specification, the contents described in this identification item are not prior art to the claims of this application, and the description in this identification item is not admitted to be prior art.

In general, buses stop and pick up passengers by stopping at a number of bus stops along the route. In the vicinity of the stop where the bus stops for passengers, an open temporary building is provided that provides space for passengers to catch the bus, which is called a bus stop booth.

A bus route map is attached to the bus stop booth, a display panel is provided to guide the waiting time of the bus, etc., and an outdoor billboard or a solar panel for self-generation can be additionally installed.

On the other hand, an open temporary building type bus stop booth is usually installed on the side of the road on which the vehicle travels, and there is a problem in that the waiting passenger's health is impaired as the passengers are exposed to the exhaust fumes discharged from the vehicle.

As a way to solve this problem, many bus stop booths that can purify the air have been proposed.

As an example of such a bus stop booth, in the Republic of Korea Patent Publication No. 10-2017-0003286 (released on September 1, 2017), the interior is sealed except for the doorway, and the air curtain is installed at the doorway to allow air flow inside and outside. A blocked bus stop is provided, and the bus stop is provided with a body having a cuboid filter chamber. The filter chamber is divided into a plurality of activated carbon sheets and a zeolite sheet, and contaminated air passes through these activated carbon sheets and zeolite sheets in multiple stages. It is discharged to the exhaust port at the top of the main body, and a water tank containing water is provided at the bottom of the main body. The water tank is provided with a rotating body partially submerged in water, and the rotating body is rotated by a motor. The air is introduced into the inside, and the outer circumferential surface is equipped with a stainless wool and carbon filter, so that the contaminated air gets wet with water and the carbon filter and Disclosed is a bus stop booth having an air purifier, characterized in that it is supplied to the filter chamber via stainless wool.

In the conventional bus stop booth as described above, the polluted air inside the bus stops through the inside of the rotating filter body partially submerged in the water tank and is first purified, and the second purified while passing through the filter layer of the vertically erected body. It is configured such that the exhaust gas and contaminants discharged are well dissolved in water, removed from the water tank, and various odors are secondaryly removed while passing through a vertically arranged filter.

In addition, in the conventional bus stop booth as described above, the air curtain is installed at the entrance side, and the internal air is sucked from the top and moved to the bottom while completely blocked from the outside. It is made of a structure that is purified and then discharged downward.

Therefore, the conventional bus stop booth as described above can purify the air inside the booth, but cannot clean up the air around the bus stop outside the booth. In addition, the conventional bus stop booth as described above has a limitation in collecting and removing various harmful substances contained in the smoke, although it may be easy to remove dust or foreign substances only with a water washing filter for air purification, a stainless wool and a carbon filter. In addition, the conventional bus stop booth as described above has a problem in that a motor for driving the air curtain and a motor for sucking air into the filter chamber are separately provided.

Patent Literature 1: Republic of Korea Patent Publication No. 10-2017-0003286 (released on Jan. 9, 2017)

Clean space to safely protect atmospheric passengers from fine dust or fumes as the inside air of the bus stop booth is sucked and purified through a filter and optical plasma and then sprayed with compressed air for air curtains to block the outside air of the bus stop booth At the same time as this is formed, it is to provide a bus stop booth for fine dust blocking so that the air around the bus stop can be purified through a chain sterilization reaction by optical plasma.

In addition, it is obviously not limited to the above-described technical problems, and another technical problem may be derived from the following description.

The micro-dust blocking bus stop booth according to an embodiment of the present disclosure, at least one side is opened and the booth main body is supplied with commercial power, and is installed in the booth main body and operated by the commercial power source and inside the booth main body. An optical plasma air purification unit that sucks air inside to collect dust and debris, sterilizes and sterilizes harmful bacteria and viruses through an optical plasma, and is installed on the top of the open surface of the ceiling of the booth body and the optical plasma An air curtain communicating with the exhaust port side of the air purification unit to discharge air purified by the optical plasma air purification unit in a downward direction, and a controller installed in the booth body to control the operation of the optical plasma air purification unit Includes.

According to a preferred feature of the present disclosure, the optical plasma air purification unit includes a case in which an intake port is formed on one side and an exhaust port is formed on the other side, a filter installed on the intake side in the case, and the inside of the case An optical plasma lamp installed downstream of the filter and sterilizing and sterilizing bacteria and viruses contained in the air flowing through the case through light plasma emission, and an intake fan installed downstream of the optical plasma lamp in the case .

According to a preferred feature of the present disclosure, an air pollution sensor is installed in the booth body to measure the air pollution level inside and around the booth body, respectively, and to transmit it to the controller or an external monitoring center.

According to an embodiment of the present disclosure, the optical plasma air purification unit for air purification and the air curtain for forming a barrier film are integrally formed on the booth body, and the internal air of the booth body is sucked through the optical plasma air purification unit to filter and After being purified through an optical plasma, as the purified air is sprayed in the form of compressed air from the top of the opening of the booth body to the bottom through the air curtain, the inside air of the booth body where atmospheric passengers stay is blocked from outside from the outside. At the same time, a clean space is formed to safely protect the air passengers from fine dust or fumes, and at the same time, the air purifying air sprayed through the air curtain performs a chain sterilization reaction by the optical plasma on the outside of the booth, and the air around the bus stop outside the booth. There is an advantage that can be purified to.

In addition, according to an embodiment of the present disclosure, the air pollution degree inside and around the booth body is measured and displayed in real time by an air pollution sensor installed in the booth body, thereby effectively monitoring air quality around the bus stop. There is this.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned will become apparent to those skilled in the art from the description of the claims.

1 is a schematic structural diagram of a micro-dust blocking bus stop booth according to an embodiment of the present disclosure.
FIG. 2 is a detailed structural diagram of an optical plasma air purification unit in a micro-dust blocking bus stop booth according to an embodiment of the present disclosure.
Figure 3 is a block diagram illustrating the operation of the fine dust-blocking bus stop booth according to an embodiment of the present disclosure.

Hereinafter, with reference to the accompanying drawings, a description will be given of the configuration, operation, and effect of the micro-dust blocking bus stop booth according to a preferred embodiment. For reference, in the drawings, each component is omitted or schematically illustrated for convenience and clarity, and the size of each component does not reflect the actual size. In addition, the same reference numerals refer to the same components throughout the specification, and reference numerals for the same components in individual drawings will be omitted.

1 is a schematic structural diagram of a micro-dust blocking bus stop booth according to an embodiment of the present disclosure.

As shown in FIG. 1, the bus stop 1 of the fine dust blocking type bus stop according to an embodiment of the present disclosure has at least one side open and a booth body 10 to which commercial power is supplied, and a booth body 10 Installed inside, operated by a commercial power source, sucks the inside air of the booth body (10) inside to collect dust and foreign substances, sterilizes harmful bacteria and viruses through an optical plasma, and then discharges the optical plasma air purification unit (20 ), And installed on the top of the open surface of the ceiling of the booth body 10 and communicates with the exhaust side of the optical plasma air purification unit 20 to the air purified by the optical plasma air purification unit 20 in the downward direction It includes an air curtain (30) for discharging, and a controller (40) installed in the booth body (10) to control the operation of the optical plasma air purification unit (20).

Here, the booth body 10 corresponds to a frame forming a waiting space for waiting passengers, and at least one surface is open to allow the passengers of the bus to enter and exit.

The booth main body 10 is supplied with commercial power for operating devices and facilities including lighting. Depending on the embodiment, a solar panel may be installed on the upper surface of the booth body 10.

In addition, a route map of the bus may be attached to the inner wall of the booth body 10, and a display panel for displaying the current state and arrival time of the bus may be installed on the upper side of the booth body 10.

The inside of the above-described booth body 10, in particular, the optical plasma air purification unit 20 is installed on the ceiling side of the booth body 10. The optical plasma air purification unit 20 sucks the inside air of the booth body 10 inside to collect dust and foreign substances, sterilizes harmful bacteria and viruses through the optical plasma, and then toward the air curtain 30 to be described later. By discharging the purified air, a detailed structure of the optical plasma air purification unit 20 is shown in FIG. 2.

As shown in FIG. 2, the optical plasma air purification unit 20 includes a case 21 in which an intake port 21a is formed on one side and an exhaust port 21b is formed on the other side, and an intake port 21a in the case 21 ) Is installed on the filter 23 installed on the side, and downstream of the filter 23 in the case 21 and sterilizes bacteria and viruses contained in the air flowing through the case 21 through optical plasma emission. It includes an optical plasma lamp 25 and an intake fan 27 installed downstream of the optical plasma lamp 25 in the case 21.

The case 21 forms an air movement passage through which the inside air of the booth body 10 flows with the suction force by the intake fan 27, and at the same time forms a reaction chamber in which primary sterilization by optical plasma is performed, A suction port 21a is formed at the bottom, an exhaust port 21b is formed at the front, and an installation space 21c in which a filter 23, an optical plasma lamp 25 and an intake fan 27 is built is formed inside.

The filter 23 installed on the inlet 21a side in the case 21 prior to sterilization and sterilization by optical plasma pre-dusts dust and debris contained in the inside air of the booth body 10 introduced into the case 21. By collecting, it may be formed of a variety of filters, such as replaceable non-woven filter, hepa filter, carbon filter, porous ceramic filter.

The optical plasma lamp 25 installed downstream of the filter 23 in the case 21 emits optical plasma to photodissociate oxygen molecules and water molecules in the air to form various active oxygen radicals and hydroxyl radicals. With the strong redox power of oxygen radicals and hydroxyl radicals, it serves to remove harmful substances (bacteria, viruses, chemicals, etc.) and odors in a chain.

The photoplasma lamp 25 is preferably formed of a UV lamp coated with a photocatalyst. It is preferable that the photocatalyst is titanium dioxide (TiO ₂ ). Titanium dioxide (TiO ₂ ) is a photocatalyst with semiconducting properties. When irradiated with ultraviolet light on its surface, oxygen and water molecules in the air passing through it are broken, plasma is formed, and free radical radicals generated therefrom. Radical hydroxide performs bactericidal purification. The principle of sterilization of light plasma through the light plasma lamp 25 is a sterilization method which is completely different from the general ultraviolet sterilization method that maintains sterilization power only in the reach of the ultraviolet wavelength.

In addition, free radicals and hydroxyl radicals are prokaryotic viruses. bacteria. Biological contaminants such as mold and fungi and other chemical contaminants can be completely destroyed, but it is harmless to eukaryotic people.

A separate socket frame 25a may be additionally installed for replaceable installation and power supply of the above-described optical plasma lamp 25.

The intake fan 27 installed downstream of the optical plasma lamp 25 in the case 21 generates a suction force for flowing the inside air of the booth body 10 into the case 21, particularly the air curtain 30 It is preferably formed of a jet fan that generates a strong suction force so that the compressed air can be discharged downward from).

The air curtain 30 is installed on the upper portion of the open surface of the ceiling of the booth body 10 described above. The air curtain 30 is in communication with the exhaust port 31b side of the optical plasma air purification unit 20 to discharge air purified by the optical plasma air purification unit 20 in a downward direction to form a kind of blocking film. Unlike the known air curtain, it does not include a separate motor and fan, and simply serves to convert the high pressure discharged from the exhaust port 31b of the optical plasma air purification unit 20 to the direction of purifying air downward.

Inside the air curtain 30, a guide plate 31 for converting the direction of the purified air to the lower direction may be additionally installed.

The controller 40 is installed in the booth body 10 described above. The controller 40 includes a printed circuit board that controls the operation of the optical plasma air purification unit 20, and can be implemented in the form of a conventional control box.

In addition, as shown in FIG. 3, the above-described booth body 10 measures the air pollution level inside and around the booth body 10, respectively, and transmits it to the aforementioned controller 40 or an external monitoring center (not shown). Air pollution sensor 50 may be installed. The air pollution sensor 50 may be formed of a conventional gas sensor that detects a specific gas concentration or a fine dust sensor that measures the fine dust concentration.

The sensor signal of the air pollution sensor 50 is provided to the controller 40 and can be configured to adjust the rotational speed of the intake fan 27 according to the degree of air pollution, and the air from the controller 40 to an external monitoring center (not shown) The signal regarding the degree of contamination may be transmitted or the sensor signal of the air pollution sensor 50 may be transmitted directly to an external monitoring center (not shown) without going through the controller 40.

In addition, a display panel 60 for displaying the measurement result of the air pollution sensor 50 may be installed in the booth body 10. The display panel 60 may be formed separately from the display panel displaying the current state and arrival time of the bus, or may be formed in combination.

Also, as shown in FIG. 3, a waiting passenger detection sensor 70 that detects the presence or absence of waiting passengers in the booth body 10 and provides a signal to the controller 40 may be installed in the booth body 10. The standby passenger detection sensor 70 allows the controller 40 to determine whether to operate the optical plasma air purification unit 20 according to the presence or absence of waiting passengers in the booth body 10, and is provided in a proximity sensor. It can be implemented as a sensor.

The fine dust-blocking bus stop booth 1 according to an embodiment of the present disclosure as described above has an optical plasma air purification unit 20 for air purification on the booth body 10 and an air curtain for forming a barrier film ( 30) is composed integrally, the inside air of the booth body 10 is sucked through the optical plasma air purification unit 20 and purified through the filter 23 and the optical plasma lamp 25, and then the air curtain 30 Through this, the purified air has a structure in which compressed air is injected in a downward direction from the top of the opening of the booth body 10.

Therefore, the inside air of the booth body 10 where the standby passenger stays is purified, and of course, it is blocked from the outside, and a clean space is formed in the booth body 10 to safely protect the air passenger 30 from fine dust or fumes. Through the purified air sprayed therethrough, a chain sterilization reaction by an optical plasma is performed outside the booth body 10, and air around the bus stop outside the booth can be purified.

In addition, the booth 1 of the fine dust blocking type bus stop according to an embodiment of the present disclosure as described above, inside and around the booth body 10 by the air pollution sensor 50 installed in the booth body 10 The air pollution degree of is measured in real time and displayed through the display panel 60, whereby the air quality around the bus stop can be efficiently monitored.

In addition, the fine dust-blocking bus stop booth 1 according to an embodiment of the present disclosure as described above, only when the waiting passenger is present in the booth body 10 by the detection of the waiting passenger detection sensor 70 As the optical plasma air purification unit 20 is configured to operate, power saving driving is possible.

The preferred embodiments of the present invention have been described above with reference to the accompanying drawings, but the embodiments described in the specification and the configurations shown in the drawings are only the most preferred embodiments of the present invention and represent all technical spirits of the present invention. It should be understood that there may be various equivalents and modifications that can replace them at the time of application. Therefore, the embodiments described above are to be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the following claims rather than the detailed description, and the meaning and scope of the claims It should be construed that any altered or modified form derived from the equivalent concept is included in the scope of the present invention.

1: Fine dust blocking bus stop booth
10: Booth body
11: opening
20: Optical plasma air purification unit
21: case
21a: Intake
21b: exhaust
21c: Installation space
23: filter
25: optical plasma lamp
25a: Socket frame
27: intake fan
30: air curtain
40: controller
50: air pollution sensor
60: display panel
70: waiting passenger detection sensor

Claims (5)

At least one side is opened and the booth main body is supplied with commercial power;
It is installed in the booth main body and is operated by the commercial power source, and sucks the inside air of the booth main body to collect dust and foreign substances, sterilizes harmful bacteria and viruses through an optical plasma, and then discharges it. ;
An air curtain installed on an upper side of the ceiling of the booth body and communicating with the exhaust side of the optical plasma air purification unit to discharge air purified by the optical plasma air purification unit downward; And
Includes a controller that is installed on the booth body and controls the operation of the optical plasma air purification unit;
The booth body is equipped with an air pollution sensor that measures the air pollution level inside and around the booth body and transmits it to the controller or an external monitoring center.
A display panel for displaying the measurement result of the air pollution sensor is installed in the booth body, and the display panel is formed separately from the display panel for displaying the current state and arrival time of the bus, or is formed in combination.
The booth body is equipped with a waiting passenger detection sensor that detects the presence of waiting passengers in the booth body and provides a signal to the controller. The method according to claim 1,
The optical plasma air purification unit includes a case in which an intake port is formed on one side and an exhaust port is formed on the other side, a filter installed on the inlet side in the case, and installed downstream of the filter in the case and emitting optical plasma A micro-dust blocking bus comprising an optical plasma lamp for sterilizing and sterilizing bacteria and viruses contained in the air flowing through the case through, and an intake fan installed downstream of the optical plasma lamp in the case. Stop booth. delete delete delete

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