KR20220051659A - Enviromental information collection system - Google Patents

Abstract

The present invention relates to an environmental information collection system which is able to, in collecting outdoor environmental information, place access parts of sensors on a lower side of a sensor board, prevent the influence of natural phenomena such as rain, wind, and snow, and improve sensing reliability and durability. To this end, according to the present invention, the environmental information collection system comprises: an atmosphere flow unit made of a hollow enclosure through which outdoor atmosphere passes; and a flow sensing unit placed in the atmosphere flow unit, and collecting and managing the environmental information in the atmosphere flow unit. The atmosphere flow unit includes: a base unit facing the ground surface; an inclined side unit extended from an edge of the base unit outward by forming an upward inclination for forming a flow space accommodating the outdoor atmosphere, and having a flow hole unit through which the outdoor atmosphere passes; and a ceiling unit placed on an upper side of the base unit by being apart from the base unit, and closing the flow space. The flow sensing unit includes: a flow sensor board placed to face the base unit in the flow space on the other side from the ground surface, and managing the collected environmental information of the flow space; and an environmental sensing unit placed on a lower side of the flow sensor board, and collecting the environmental information of the flow space.

Description

Environmental information collection system {ENVIROMENTAL INFORMATION COLLECTION SYSTEM}

The present invention relates to an environmental information collection system, and more specifically, in collecting outdoor environmental information, as the connection parts of the sensors are disposed under the sensor board, they are not affected by natural phenomena such as rain, wind, snow, etc. It relates to an environmental information collection system to improve sensing reliability and durability without

In general, air pollution means that the amount, concentration, and duration of pollutants, such as radioactive substances or fine dust containing heavy metals artificially released into the atmosphere, cause discomfort to an unspecified number of people in the area or cause public health problems in the area. It causes harm and harms the activities of humans, animals, and plants. In particular, with the development of technology and the development of industries, interest in quality of life is increasing, and interest in air pollution in residential and working environments is rapidly increasing.

In response to this, in the prior art (Patent Publication No. 10-2013-0000065), it is mounted on a vacuum road sprinkler to acquire data such as the movement path and amount of water spraying, driver information, and environmental information of the sprinkler and transmit it to the control center, and RFID An air pollution control and monitoring system using GPS that can check whether a certain driver is working, working hours, etc. through card recognition is disclosed.

However, according to the prior art, the configuration of the device is complicated, the measurement accuracy of environmental data is low, and only the basic concept of environmental data measurement using GPS and sensor communication is disclosed as a product in the initial stage.

Republic of Korea Patent Publication No. 10-2013-0000065 (Title of the invention: Air pollution control and monitoring system using GPS, published on 01.02.2013)

It is an object of the present invention to solve the problems of the prior art. In collecting outdoor environmental information, as the connection parts of the sensors are disposed under the sensor board, they are not affected by natural phenomena such as rain, wind, snow, etc. To provide an environmental information collection system to improve sensing reliability and durability.

According to a preferred embodiment for achieving the above object of the present invention, the environmental information collection system according to the present invention includes an atmospheric flow unit consisting of a hollow enclosure through which the outdoor atmosphere passes; and a flow sensing unit provided inside the atmospheric flow unit and configured to collect and manage environmental information inside the atmospheric flow unit, wherein the atmospheric flow unit includes: a base unit facing the ground; an inclined side portion extending upwardly inclined from the edge of the base portion to the outside to form a flow space in which the outdoor air is accommodated, and through which a flow hole through which the outdoor air passes is formed; and a ceiling portion spaced apart from the upper side of the base portion to close the flow space, wherein the flow sensing unit is provided to face the base portion in the flow space with respect to the ground and spaced apart to face the flow space of the collected flow space. a floating sensor board that manages environmental information; and an environment sensing unit provided under the flow sensor board to collect environmental information of the flow space.

Here, the air flowing into the flow space through the flow hole forms a turbulence in the flow space.

Here, the inclined side portion includes a shielding portion protruding outward from the upper end of the flow hole or protruding inward from the upper end of the flow hole.

Here, in the base part, a discharge hole for discharging at least one of the air and moisture introduced into the flow space; is formed through.

Here, the environment sensing unit may include a fine dust sensing module connected to a lower portion of the flow sensor board in the flow space and configured to collect information on fine dust among environmental information of the flow space. In this case, the fine dust sensing module may include: a fine dust box provided as a hollow housing under the flow sensor board in the flow space, and having at least an opening among an opening and a circulation hole; an opening control unit for opening and closing the opening; and a fine dust sensor unit embedded in the fine dust box in a state connected to the lower part of the flow sensor board to collect information on the fine dust inside the fine dust enclosure, wherein the opening control unit comprises: It operates according to at least one of the wind speed of the atmosphere and the humidity of the outdoor atmosphere.

Here, the environment sensing unit is spaced apart from the fine dust sensing module and connected to the lower part of the flow sensor board, and a flow environment sensor unit that collects information other than the information on fine dust among the environmental information of the flow space; include more

Here, the environment sensing unit extracts a state meaningless to the operation of the fine dust sensing module based on outdoor environment information or environment information of the flow space to stop the operation of the fine dust sensor unit, or It further includes an opening/closing control unit for closing.

The system for collecting environmental information according to the present invention includes: a main body unit provided as a hollow housing on an upper portion of the atmospheric flow unit; and an external sensing unit provided in the main body unit and configured to collect and manage outdoor environmental information, wherein the external sensing unit is built into the main body unit and external sensor board for managing the collected outdoor environmental information ; and an external environmental sensor unit connected to the external sensor board to collect outdoor environmental information.

The environmental information collection system according to the present invention further includes a collection control unit configured to control the power applied to at least the flow sensing unit through at least one of external power, power generated by power generation, and battery power.

Here, the collection control unit includes a power supply unit for converting external power; and

and a power board including a power control unit for controlling the power delivered by the power supply unit and applying it to at least the flow sensing unit.

Here, the collection control unit further includes a system charging unit that is charged with the power delivered by the power supply unit, and the power control unit controls the power delivered by the power supply unit to control the power delivered by the power supply unit to the system charging unit also approved

Here, the power board may include: a power monitoring unit configured to monitor whether the power delivered by the power supply unit is abnormal; and when an abnormality occurs in the power transmitted by the power supply unit according to the monitoring of the power monitoring unit, the power transmitted by the power supply unit is cut off, while the power input to the power board is supplied to the system charging unit It further includes; a power switching unit for switching switching to the power charged in

Here, the collection control unit, solar panels generated by the sun; a solar supply unit in which the power produced by the solar panel is charged; and a solar controller for converting the power transmitted from the solar supply unit.

Here, the power board may include: a power monitoring unit configured to monitor whether the power delivered by the power supply unit is abnormal; and when an abnormality occurs in the power delivered by the power supply unit according to the monitoring of the power monitoring unit, the power delivered by the power supply unit is cut off while supplying the power input to the power board to the solar controller It further includes a; power switching unit for switching switching to power delivered by the.

Here, the collection control unit, solar panels generated by the sun; a solar supply unit in which the power produced by the solar panel is charged; and a solar controller for converting the power transmitted from the solar supply unit.

Here, the power board may include: a power monitoring unit configured to monitor whether the power delivered by the power supply unit is abnormal; and when an abnormality occurs in the power delivered by the power supply unit according to the monitoring of the power monitoring unit, the power delivered by the power supply unit is cut off, while the power input to the power board is connected to the solar controller It further includes; a power switching unit for switching to the power delivered by any one of the system charging unit.

Here, the collection control unit, solar panels generated by the sun; a solar supply unit in which the power produced by the solar panel is charged; a solar controller for converting the power transmitted from the solar supply unit; and a power board including a power control unit for controlling the power delivered by the solar controller and applying it to at least the flow sensing unit.

Here, the collection control unit includes a system charging unit that is charged with the power transmitted by the power supply unit, and the power control unit controls the power transmitted by the power supply unit to also the system charging unit. approve

Here, the power board may include: a power monitoring unit configured to monitor whether the power delivered by the power supply unit is abnormal; and when an abnormality occurs in the power delivered by the solar controller according to the monitoring of the power monitoring unit, the power delivered by the solar controller is cut off, while the power input to the power board is charged to the system charging unit It further includes;

Here, the power board, based on the outdoor environmental information, extracting a state that has no meaning for power generation in the solar panel, and a sensor monitoring unit for stopping the operation of the solar panel; further includes.

According to the environmental information collection system according to the present invention, when collecting outdoor environmental information, the sensing reliability and reliability of the sensor are not affected by natural phenomena such as rain, wind, snow, etc. Durability can be improved. In addition, by adding the inverted trapezoidal structure of the atmospheric flow unit, it is possible to prevent rainwater or external moisture from flowing into the flow space, and to lower the wind speed of the atmosphere flowing into the flow space.

In addition, the present invention can improve the accuracy of information on fine dust through turbulence in the flow space and make the distribution of the atmosphere in the flow space uniform.

In addition, the present invention lowers the wind speed of the air flowing into the flow space through the arrangement of the flow hole and the structure of the shield, while allowing the air to easily form turbulence in the flow space.

In addition, the present invention adjusts the wind speed in the flow space as an offset effect even if a large amount of air is introduced into the flow space through the structure of the discharge hole, facilitates the discharge of the air flowing into the flow space, and Allow the water to drain quickly.

In addition, the present invention can minimize the contact of moisture or moisture introduced into the flow space with the fine dust sensor unit and protect the fine dust sensor unit through the structure of the fine dust sensing module. In addition, when the circulation hole is added, it is possible to smooth the flow of the air flowing into the sensing space.

In addition, the present invention can collect the environmental information of the flow space in the flow space through the flow environment sensor unit.

In addition, the present invention can clarify the operation of the fine dust sensor unit and the opening and closing operation of the opening through the opening/closing control unit.

In addition, the present invention can protect the components of the collection control unit and the external sensing unit and the communication unit from the outdoor atmosphere through the configuration of the main body unit, and stabilize the coupling with the fixture.

In addition, the present invention can stabilize the power applied to the sensing units through the configuration of the collection control unit.

In addition, the present invention can easily operate the environmental information collection system by using an external power source alone through the configuration of the power supply unit and the power board.

In addition, the present invention can be charged using an external power source through the configuration of the system charging unit, and can use the charging power according to the situation.

In addition, the present invention can stably control the power usage state of the external power source and the battery in the combination of the external power source and the battery, and can clarify the operation of the environmental information collection system in response to an abnormality of the external power source.

In addition, since the present invention uses solar energy, the environmental information collection system is stably operated by using solar energy together with external power.

In addition, the present invention can stably control the state of use of external power and solar energy in the combination of external power and solar energy, and can clarify the operation of the environmental information collection system for abnormalities of external power.

In addition, according to the present invention, it is possible to charge the battery using any one of an external power source and solar energy, and the charging power can be used by reflecting the priority according to the situation.

In addition, the present invention can stably control the use state of external power, solar energy, and battery in the combination of external power, battery, and solar energy, and clearly control the operation of the environmental information collection system for abnormalities of external power can do.

In addition, the present invention can easily operate the environmental information collection system by using solar energy alone through the configuration of a solar panel, a solar supply unit, a solar controller, and a power board.

In addition, the present invention can stably control the power usage state of the solar energy and the battery in the combination of the solar energy and the battery, and can clarify the operation of the environmental information collection system for the abnormality of the solar energy.

In addition, the present invention can clarify the generation and transmission operation of solar energy through the sensor monitoring unit.

In addition, according to the present invention, the environmental information collected by the sensor units through the communication unit can be delivered, stored and managed to the collection server according to time series in real time.

In addition, the present invention can collect and monitor the environmental information provided by the environmental information collection system through the collection server, and facilitate the management, supervision, and maintenance of the environmental information collection.

1 is a view showing an installation state of an environmental information collection system according to an embodiment of the present invention.
2 is a schematic diagram illustrating an arrangement state of a standby flow unit and a flow sensing unit in the environmental information collection system according to an embodiment of the present invention.
3 is a bottom cross-sectional view illustrating an arrangement state of a fine dust sensing module in the environmental information collection system according to an embodiment of the present invention.
4 is a schematic diagram illustrating a flow state of the atmosphere passing through the atmospheric flow unit in the environmental information collection system according to an embodiment of the present invention.
5 is a block diagram illustrating a coupling relationship of an environmental information collection system according to an embodiment of the present invention.

Hereinafter, an embodiment of the environmental information collection system according to the present invention will be described with reference to the accompanying drawings. At this time, the present invention is not limited or limited by the examples. In addition, in describing the present invention, detailed descriptions of known functions or configurations may be omitted in order to clarify the gist of the present invention.

The environmental information collected by the sensor unit to be described later in an embodiment of the present invention includes fine dust, temperature, humidity, carbon monoxide (CO), carbon dioxide (CO2), nitrogen dioxide (NO2), sulfur dioxide (SO2), volatile organic compounds (VOCs), UV index, vibration, luminance, illuminance, etc. may be included.

The environmental information collection system according to an embodiment of the present invention is fixed to the fixture 1 to collect environmental information of the outdoor atmosphere. Here, the fixture 1 may include a pillar portion such as a street lamp, a telephone pole, a pillar, or a wall portion of a structure or a floor sensing space 241 portion of the structure.

The environmental information collection system according to an embodiment of the present invention may include a standby flow unit 10 and a flow sensing unit 20 .

The atmospheric flow unit 10 is made of a hollow enclosure through which the outdoor atmosphere passes. A flow space 101 in which the outdoor air is accommodated is formed in the atmospheric flow unit 10 . The atmospheric flow unit 10 may be coupled to the fixture 1 by a body unit 50 to be described later.

The atmospheric flow unit 10 includes a base part 11 facing the ground, and an inclined side part extending upwardly from the edge of the base part 11 to form a flow space 101 in which the outdoor atmosphere is accommodated. (12) and spaced apart disposed on the upper side of the base portion 11 may include a ceiling portion (13) for closing the flow space (101).

A discharge hole 111 for discharging at least one of air and moisture introduced into the flow space 101 may be formed through the base 11 . At the entrance of the discharge hole 111 in the flow space 101, a discharge inclined portion 112 that slopes downward from the edge of the discharge hole 111 toward the center of the discharge hole 111 is formed to facilitate discharge, It is possible to suppress the backflow of outdoor air into the flow space 101 .

A flow hole 121 through which the outdoor air passes may be formed through the inclined side portion 12 . These flow hole portions 121 may be arranged to be vertically and horizontally spaced apart in a grid pattern. In addition, the flow hole 121 is arranged to be spaced apart in a zigzag with respect to the height. For example, the flow hole 121 may have a diameter of about 5 mm and may be disposed at an interval of 5 mm.

The inclined side part 12 may include a shielding part 122 that protrudes outward from the upper end of the flow hole 121 or protrudes inward from the upper end of the flow hole 121 . The shielding part 122 may be formed by protruding the inclined side part 12 in the process of forming the flow hole part 121 . Then, the air flowing into the flow space 101 through the flow hole 121 may form a turbulence in the flow space 101 to stabilize the air flowing into the flow space 101 .

The ceiling part 13 may be a bottom part of the main body unit 50 to be described later, or may be integrally formed with the bottom part of the main body unit 50 to be described later.

The flow sensing unit 20 is provided inside the atmospheric flow unit 10 . The flow sensing unit 20 collects and manages the internal environmental information of the atmospheric flow unit 10 .

The flow sensing unit 20 is provided to face the base unit 11 in the flow space 101 with respect to the ground and is provided with a flow sensor board 21 for managing the collected environmental information of the atmosphere of the flow space 101 and , may include an environment sensing unit provided under the flow sensor board 21 to collect environmental information of the flow space 101 .

The environment sensing unit is connected to the lower portion of the flow sensor board 21 in the flow space 101 and may include a fine dust sensing module 22 for collecting information on fine dust among environmental information of the flow space 101 . there is.

The fine dust sensing module 22 includes a fine dust enclosure 24 provided as a hollow housing under the flow sensor board 21 in the flow space 101 and an opening 242 provided in the fine dust enclosure 24 . It is built into the fine dust enclosure 24 in the state of being connected to the opening control unit 25 for opening and closing the flow sensor board 21 and collects information on the fine dust inside the fine dust enclosure 24. It may include a fine dust sensor unit 26 .

The fine dust enclosure 24 is provided with a sensing space 241 in which the atmosphere of the flow space 101 is accommodated. At least an opening 242 of the opening 242 and the circulation hole 243 is opened in the fine dust enclosure 24 . The opening 242 allows the air of the flow space 101 to flow in, and in the circulation hole 243, the air of the flow space 101 flows into the sensing space 241 or the air in the sensing space 241 flows into the flow space ( 101) can be discharged.

The opening control unit 25 may include an opening/closing member 251 for opening and closing the opening 242 and an opening/closing driver 252 for operating the opening/closing member 251 to open and close the opening 242 . The opening/closing member 251 may move in the fine dust enclosure 24 by a sliding door method, an opening door method, or a curtain method.

The opening control unit 25 may be operated according to at least one of the wind speed of the atmosphere and the humidity of the atmosphere.

The environment sensing unit is spaced apart from the fine dust sensing module 22 and connected to the lower part of the flow sensor board 21 , and the flow environment sensor unit collects information other than the information on fine dust among the environmental information of the flow space 101 . (23) may be further included.

The environment sensing unit extracts a state that has no meaning in the operation of the fine dust sensing module 22 based on the outdoor environment information or the environment information of the flow space 101 to stop the operation of the fine dust sensor unit 26 or open the opening. It may further include an opening/closing control unit 27 for closing the 242.

The state in which the operation of the fine dust sensing module 22 is meaningless is when the wind speed of the outdoor air exceeds the preset limit wind speed, the humidity of the outdoor atmosphere exceeds the preset humidity limit, or the air in the flow space 101 This is a case in which the wind speed of the flow exceeds the preset flow speed, or the humidity of the atmosphere in the flow space 101 exceeds the preset flow humidity.

For example, the opening/closing control unit 27 operates the opening control unit 25 so that the opening 242 is opened when the wind speed of the outdoor atmosphere is less than or equal to a preset limit wind speed or when the humidity of the outdoor atmosphere is less than or equal to the preset humidity limit. and the fine dust sensor unit 26 is operated. In addition, when the wind speed of the outdoor air exceeds a preset limit wind speed, or when the humidity of the outdoor air exceeds a preset flow humidity, the opening control unit 25 is operated to close the opening 242, and fine dust The sensor unit 26 is stopped.

As another example, the opening/closing control unit 27 is configured to open the opening 242 when the wind speed of the atmosphere in the flow space 101 is less than or equal to a preset flow speed or when the humidity of the atmosphere in the flow space 101 is less than or equal to a preset humidity limit. The opening control unit 25 is operated, and the fine dust sensor unit 26 is operated. In addition, when the atmospheric wind speed of the flow space 101 exceeds a preset flow wind speed, or when the atmospheric humidity of the flow space 101 exceeds a preset flow humidity, the opening 242 is closed by an opening control unit ( 25) is operated, and the fine dust sensor unit 26 is stopped.

The environmental information collection system according to an embodiment of the present invention may further include a main body unit 50 and an external sensing unit 60 .

The body unit 50 is provided as a hollow housing in the upper part of the atmospheric flow unit 10 . Here, the bottom of the main body unit 50 may be formed of the ceiling portion 13 of the atmospheric flow unit 10 or may be formed integrally with the ceiling portion 13 of the atmospheric flow unit 10 .

The main body unit 50 has an exterior but has an indoor space therein, and may include a coupling body 51 having an open side, and a door 52 opening and closing the opening of the coupling body 51 .

The coupling body 51 may be provided with a mounting part (not shown) for coupling with the fixture 1 .

The door 52 may be provided with a lock (not shown) for lock setting and release.

The external sensing unit 60 is connected to the external sensor board 61 that is built into the main body unit 50 and manages the collected outdoor environmental information, and the external sensor board 61 to collect outdoor environmental information. It may include a sensor unit 62 . Here, reference numeral 63 denotes a wind speed sensor unit for measuring wind strength, and reference numeral 64 denotes a wind direction sensor unit for measuring a wind direction.

The environmental information collection system according to an embodiment of the present invention controls the power applied to at least the flow sensing unit 20 among the flow sensing unit and the external sensing unit through at least one of external power, power generated by power generation, and battery power. It may further include a collection control unit (30). The collection control unit 30 may control the power applied to the built-in system charging unit. The collection control unit 30 is divided into six types according to the type of power source.

In the following description, the operation of the power control unit 324 and the operation of the power switching unit 322 are mixed, but not limited thereto, and the operation of the power control unit 324 and the operation of the power switching unit 322 is the power board ( 32), or may be integrated into any one operation of the operation of the power control unit 324 and the operation of the power switching unit 322 .

1. When using an external power source alone,

The collection control unit 30 includes a power supply unit 31 for converting external power, and at least a flow of the flow sensing unit 20 and the external sensing unit 60 by controlling the power delivered by the power supply unit 31 . It may include a power board 32 including a power control unit 324 applied to the sensing unit 20 .

Then, the power control unit 324 monitors the power supply state of the power supply unit 31 . When an abnormality occurs in the power supply state of the power supply unit 31 , the power control unit 324 may transmit abnormal information to the collection server 70 to maintain the power of the environmental information collection system.

2. When using an external power source and battery,

The collection control unit 30 includes a power supply unit 31 that converts external power, a system charging unit 33 in which the power delivered by the power supply unit 31 is charged, and a power supply unit 31 by A power board 32 including a power control unit 324 that controls the transmitted power and applies it to at least the flow sensing unit 20 among the flow sensing unit 20, the external sensing unit 60, and the system charging unit 33. may include

The power control unit 324 may control the power delivered by the power supply unit 31 to apply it to the system charging unit 33 as well.

The power control unit 324 monitors the charging amount of the system charging unit 33 . When the charging of the system charging unit 33 is completed by the power delivered by the power board 32 , the power control unit 324 cuts off the power applied to the system charging unit 33 . And when the charging amount of the system charging unit 33 is smaller than the preset minimum charging amount according to the use of the system charging unit 33, the power control unit 324 controls the power input to the power board 32 to control the system charging unit (33) can be charged.

Here, the power board 32 is a power supply unit 31 according to the monitoring of the power monitoring unit 321 and the power monitoring unit 321 for monitoring whether the power delivered by the power supply unit 31 is abnormal. When an abnormality occurs in the power delivered by the power supply unit 31 , the power supply is cut off while the power input to the power board 32 is switched to the power charged in the system charging unit 33 . A switching unit 322 may be further included.

And the power control unit 324 generates raw data for the abnormal information of the power delivered by the power supply unit 31 and the switching information to the power charged in the system charging unit 33 and transmits it to the collection server 70 . Therefore, it is possible to monitor the input power through the analysis of raw data.

In addition, the power control unit 324 is transmitted by the power supply unit 31 when the abnormality of the power delivered by the power supply unit 31 is maintained according to the monitoring of the power monitoring unit 321 after the switching operation. It is possible to quickly maintain the environmental information collection system by quickly transmitting the abnormal information of the power source to the collection server 70 .

For example, the power switching unit 322 is the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321 when the power charged in the system charging unit 33 is applied to the power board. When returning to normal, the power delivered by the system charging unit 33 is cut off, and the power input to the power board 32 is switched back to the power delivered by the power supply unit 31 .

As another example, the power switching unit 322 is transmitted by the system charging unit 33 when the power charged in the system charging unit 33 is applied to the power board 32, when a preset switching time elapses. While the power is cut off, the power input to the power board 32 is switched back to the power delivered by the power supply unit 31 .

First, when the preset switching time elapses, even after the return switching operation, when an abnormality occurs in the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321, the power switching unit 322 is Stops the entire operation of the environmental information collection system, and transmits error information about power failure to the collection server 70 to protect the environmental information collection system and to quickly process the maintenance of the environmental information collection system .

Second, when the preset switching time elapses, even after the return switching operation, when an abnormality occurs in the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321, the power switching unit 322 is While blocking the power delivered by the power supply unit 31 , the power input to the power board 32 may be switched to power delivered by the system charging unit 33 . And when the power delivered by the power supply unit 31 returns to normal, the power switching unit 322 cuts off the power delivered by the system charging unit 33, while being input to the power board 32 The power may be switched back to the power delivered by the power supply unit 31 . Here, when the abnormality of the power delivered by the power supply unit 31 is maintained even up to a preset dangerous charge amount of the charge amount of the system charging unit 33 in response to the charge amount of the system charging unit 33, the power switching unit 322 ) stops the entire operation of the environmental information collection system, and transmits error information about power failure to the collection server 70 to protect the environmental information collection system and to quickly process the maintenance of the environmental information collection system. let it be

3. When using external power and power generated by power generation,

The collection control unit 30 includes a power supply unit 31 that converts external power, a solar panel 34 generated by the sun, and a solar supply unit 35 that is charged with power produced by the solar panel 34 . ), a solar controller 36 that converts power transmitted from the solar supply unit 35, and a flow sensing unit 20 and an external sensing unit 60 by controlling the power transmitted by the power supply unit 31 Among them, it may include a power board 32 including a power control unit 324 applied to at least the flow sensing unit 20 .

The power control unit 324 monitors the charge amount of the solar supply unit (35). When the charging of the solar supply unit 35 by the solar panel 34 is completed, the power control unit 324 stops the operation of the solar panel 34 . And when the amount of charge of the solar supply unit 35 becomes smaller than the preset minimum charge amount according to the use of the solar supply unit 35, the power control unit 324 cuts off the power transmitted from the solar controller 36 and supplies external power. let it be used

Here, the power board 32 is a power supply unit 31 according to the monitoring of the power monitoring unit 321 and the power monitoring unit 321 for monitoring whether the power delivered by the power supply unit 31 is abnormal. Power that cuts off the power delivered by the power supply unit 31 when an abnormality occurs in the power delivered by the power supply unit 31 and switches the power input to the power board 32 into the power delivered by the solar controller 36 A switching unit 322 may be further included.

And the power control unit 324 generates raw data for the abnormal information of the power delivered by the power supply unit 31 and the switching information to the power delivered by the solar controller 36 and transmits it to the collection server 70 . Therefore, it is possible to monitor the input power through the analysis of raw data.

In addition, the power control unit 324 is transmitted by the power supply unit 31 when the abnormality of the power delivered by the power supply unit 31 is maintained according to the monitoring of the power monitoring unit 321 after the switching operation. It is possible to quickly maintain the environmental information collection system by quickly transmitting the abnormal information of the power source to the collection server 70 .

For example, the power switching unit 322 is transmitted by the power supply unit 31 according to the monitoring of the power monitoring unit 321 when the power delivered by the solar controller 36 is applied to the power board 32 . When the power to be returned to normal, the power switching unit 322 cuts off the power delivered by the solar controller 36 , while the power input to the power board 32 is delivered by the power supply unit 31 . Switch back to the supplied power supply.

As another example, when the power delivered by the solar controller 36 is applied to the power board 32, the power switching unit 322 is a preset switching time, the power switching unit 322 is the solar controller ( 36), while shutting off the power, the power input to the power board 32 is switched back to the power delivered by the power supply unit 31 .

First, when the preset switching time elapses, even after the return switching operation, when an abnormality occurs in the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321, the power switching unit 322 is Stops the entire operation of the environmental information collection system, and transmits error information about power failure to the collection server 70 to protect the environmental information collection system and to quickly process the maintenance of the environmental information collection system .

Second, when the preset switching time elapses, even after the return switching operation, when an abnormality occurs in the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321, the power switching unit 322 is While blocking the power delivered by the power supply unit 31 , the power input to the power board 32 may be switched to power delivered by the solar controller 36 . And when the power delivered by the power supply unit 31 returns to normal, the power switching unit 322 cuts off the power delivered by the solar controller 36 , while the power input to the power board 32 . may be switched back to the power delivered by the power supply unit 31 . Here, when the abnormality of the power delivered by the power supply unit 31 is maintained even to a preset dangerous charge amount of the solar supply unit 35 in response to the charge amount of the solar supply unit 35, the power switching unit 322 ) stops the entire operation of the environmental information collection system, and transmits error information about power failure to the collection server 70 to protect the environmental information collection system and to quickly process the maintenance of the environmental information collection system. let it be

In addition, the power board 32 further includes a sensor monitoring unit 323 for stopping the operation of the solar panel 34 by extracting a state that has no meaning for power generation in the solar panel 34 based on outdoor environmental information. may include

The state in which the operation in the solar panel 34 has no meaning means that the power generation efficiency of the solar panel 34 is lowered or the solar panel 34 does not generate electricity, and the amount of sunlight incident on the solar panel 34 is It may be a few or no hours, cloudy hours, or rainy times. Such a time period may be determined by illuminance, humidity, etc. among outdoor environmental information.

For example, the sensor monitoring unit 323 causes the solar panel 34 to operate when the operation in the solar panel 34 is meaningful. In addition, the sensor monitoring unit 323 causes the solar panel 34 to stop when the operation in the solar panel 34 is in a meaningless state.

4. When using an external power source and power source and battery,

The collection control unit 30 includes a power supply unit 31 that converts external power, a solar panel 34 generated by the sun, and a solar supply unit 35 that is charged with power produced by the solar panel 34 . ), a solar controller 36 for converting the power transmitted from the solar supply unit 35, a system charging unit 33 for charging the power transmitted by the power supply unit 31, and a power supply unit 31 ) to control the power delivered by the flow sensing unit 20, the external sensing unit 60, and the system charging unit 33 of the power control unit 324 to apply to at least the flow sensing unit 20 A power board including (32) may be included.

The power control unit 324 may control at least one of the power delivered by the power supply unit 31 and the power delivered by the solar controller 36 to be applied to the system charging unit 33 as well.

The power control unit 324 monitors the charging amount of the system charging unit 33 . When the charging of the system charging unit 33 is completed by the power delivered by the power board 32 , the power control unit 324 cuts off the power applied to the system charging unit 33 . And when the charging amount of the system charging unit 33 is smaller than the preset minimum charging amount according to the use of the system charging unit 33, the power control unit 324 controls the power input to the power board 32 to control the system charging unit (33) can be charged.

The power control unit 324 monitors the charge amount of the solar supply unit (35). When the charging of the solar supply unit 35 by the solar panel 34 is completed, the power control unit 324 stops the operation of the solar panel 34 . And when the amount of charge of the solar supply unit 35 becomes smaller than the preset minimum charge amount according to the use of the solar supply unit 35, the power control unit 324 operates the solar panel 34 to operate the system charging unit 33. can be recharged.

Here, the power board 32 is a power supply unit 31 according to the monitoring of the power monitoring unit 321 and the power monitoring unit 321 for monitoring whether the power delivered by the power supply unit 31 is abnormal. When an abnormality occurs in the power delivered by the power supply unit 31 , the power delivered by the power supply unit 31 is cut off and the power input to the power board 32 is applied to the solar controller 36 and the system charging unit 33 . It may further include a power switching unit 322 for switching to the power delivered by the.

The power control unit 324 may determine the priority of the primary conversion target through comparison of the charging amount of the solar supply unit 35 and the system charging unit 33, preset conversion information, and the like.

Power control unit 324 is the power supply unit 31, abnormal information of the power delivered by, the solar controller 36 or the system charging unit 33 raw data for switching information to the power delivered by any one As it is generated and transmitted to the collection server 70, the input power can be monitored through the analysis of raw data.

In addition, the power control unit 324 is transmitted by the power supply unit 31 when the abnormality of the power delivered by the power supply unit 31 is maintained according to the monitoring of the power monitoring unit 321 after the switching operation. It is possible to quickly maintain the environmental information collection system by quickly transmitting the abnormal information of the power source to the collection server 70 .

For example, the power switching unit 322 is a power supply monitoring unit 321 when the power delivered by any one of the solar controller 36 and the system charging unit 33 is applied to the power board 32 according to the priority. ), when the power delivered by the power supply unit 31 returns to normal according to the monitoring, the power switching unit 322 is the power delivered by any one of the solar controller 36 and the system charging unit 33 . On the other hand, the power input to the power board 32 is switched back to the power transmitted by the power supply unit 31 .

As another example, the power switching unit 322 is a preset switching time when the power delivered by any one of the solar controller 36 and the system charging unit 33 is applied to the power board according to the priority. , the power switching unit 322 cuts off the power of the priority, while switching the switch in a manner that applies the power of the next order to the power board 32, and after the changeover is switched to the final order, the power of the last order is cut off while , the power input to the power board 32 is switched back to the power transmitted by the power supply unit 31 .

First, when an abnormality occurs in the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321 even after the return switching operation, the power switching unit 322 stops the entire operation of the environmental information collection system On the other hand, it transmits error information about power failure to the collection server 70 to protect the environmental information collection system and to quickly process the maintenance of the environmental information collection system.

Second, even after the return switching operation, when an abnormality occurs in the power delivered by the power supply unit 31 according to the monitoring of the power monitoring unit 321 , the power switching unit 322 is transmitted by the power supply unit 31 . On the other hand, the power input to the power board 32 may be switched again according to the priority. And when the power delivered by the power supply unit 31 returns to normal, the power switching unit 322 cuts off the power currently delivered according to the priority, while turning the power input to the power board 32 into power. It is possible to switch back to the power delivered by the supply unit (31). Here, in the final ranking, in response to the amount of charge of the solar supply unit 35 or the amount of charge of the system charging unit 33, the amount of charge of the unit corresponds to the preset dangerous charge amount of power delivered by the power supply unit 31. If this is maintained, the power switching unit 322 stops the entire operation of the environmental information collection system, and transmits error information about power failure to the collection server 70 to protect the environmental information collection system and collect environmental information It allows the maintenance of the system to be handled quickly.

In addition, the power board 32 further includes a sensor monitoring unit 323 for stopping the operation of the solar panel 34 by extracting a state that has no meaning for power generation in the solar panel 34 based on outdoor environmental information. may include

The state in which the operation in the solar panel 34 has no meaning means that the power generation efficiency of the solar panel 34 is lowered or the solar panel 34 does not generate electricity, and the amount of sunlight incident on the solar panel 34 is It may be a few or no hours, cloudy hours, or rainy times. Such a time period may be determined by illuminance, humidity, etc. among outdoor environmental information.

For example, the sensor monitoring unit 323 causes the solar panel 34 to operate when the operation in the solar panel 34 is meaningful. In addition, the sensor monitoring unit 323 causes the solar panel 34 to stop when the operation in the solar panel 34 is in a meaningless state.

5. In the case of using power generated by power alone,

The collection control unit 30 includes a solar panel 34 generated by the sun, a solar supply unit 35 in which power produced by the solar panel 34 is charged, and power transmitted from the solar supply unit 35 . A solar controller 36 that converts the power supply control unit ( 324 may include a power board 32 included.

Then, the power control unit 324 monitors the power supply state of the solar controller (36). When an abnormality occurs in the power supply state of the solar controller 36 , the power control unit 324 may transmit abnormal information to the collection server 70 to maintain the power of the environmental information collection system.

The power control unit 324 monitors the charge amount of the solar supply unit (35). When the charging of the solar supply unit 35 by the solar panel 34 is completed, the power control unit 324 stops the operation of the solar panel 34 . And when the amount of charge of the solar supply unit 35 becomes smaller than a preset dangerous charge amount according to the use of the solar supply unit 35, the power control unit 324 is a solar controller such that the solar supply unit 35 is a preset operation charge amount. The power delivered in (36) can be temporarily cut off.

In addition, the power board 32 further includes a sensor monitoring unit 323 for stopping the operation of the solar panel 34 by extracting a state that has no meaning for power generation in the solar panel 34 based on outdoor environmental information. may include

The state in which the operation in the solar panel 34 has no meaning means that the power generation efficiency of the solar panel 34 is lowered or the solar panel 34 does not generate electricity, and the amount of sunlight incident on the solar panel 34 is It may be a few or no hours, cloudy hours, or rainy times. Such a time period may be determined by illuminance, humidity, etc. among outdoor environmental information.

For example, the sensor monitoring unit 323 causes the solar panel 34 to operate when the operation in the solar panel 34 is meaningful. In addition, the sensor monitoring unit 323 causes the solar panel 34 to stop when the operation in the solar panel 34 is in a meaningless state.

6. When using power and batteries from power generation,

The collection control unit 30 includes a solar panel 34 generated by the sun, a solar supply unit 35 in which power produced by the solar panel 34 is charged, and power transmitted from the solar supply unit 35 . A solar controller 36 that converts the power supply unit 31, a system charging unit 33 that is charged with power delivered by the power supply unit 31, and a flow sensing unit ( 20) and the external sensing unit 60 and the system charging unit 33 may include a power board 32 including a power control unit 324 applied to at least the flow sensing unit 20.

The power control unit 324 may control at least one of the power delivered by the power supply unit 31 and the power delivered by the solar controller 36 to be applied to the system charging unit 33 as well.

The power control unit 324 monitors the charging amount of the system charging unit 33 . When the charging of the system charging unit 33 is completed by the power transmitted by the power board 32 , the power control unit 324 cuts off the power applied to the system charging unit 33 . And when the charging amount of the system charging unit 33 becomes smaller than the preset minimum charging amount according to the use of the system charging unit 33, the power control unit 324 controls the power input to the power board 32 to control the system charging unit (33) can be charged.

The power control unit 324 monitors the charge amount of the solar supply unit (35). When the charging of the solar supply unit 35 by the solar panel 34 is completed, the power control unit 324 stops the operation of the solar panel 34 . And when the amount of charge of the solar supply unit 35 becomes smaller than the preset minimum charge amount according to the use of the solar supply unit 35, the power control unit 324 cuts off the power transmitted from the solar controller 36, and the system charging unit Use the power of (33).

Here, the power board 32 is a power monitoring unit 321 that monitors whether the power delivered by the power supply unit 31 is abnormal, and the solar controller 36 according to the monitoring of the power monitoring unit 321. Power switching unit that cuts off the power delivered by the solar controller 36 when an abnormality occurs in the transmitted power and switches the power input to the power board 32 into the power charged in the system charging unit 33 (322) may be further included.

And the power control unit 324 generates raw data for the abnormal information of the power delivered by the solar controller 36, the switching information to the power charged in the system charging unit 33, and transmits it to the collection server 70 Therefore, the input power can be monitored through the analysis of the raw data.

In addition, the power control unit 324 is the power transmitted by the solar controller 36 when the abnormality of the power transmitted by the solar controller 36 is maintained according to the monitoring of the power monitoring unit 321 after the switching operation. of the abnormal information can be quickly transmitted to the collection server 70 to quickly maintain the environmental information collection system.

As an example, the power switching unit 322 is transmitted by the solar controller 36 according to the monitoring of the power monitoring unit 321 when the power charged in the system charging unit 33 is applied to the power board 32 . When the power returns to normal, the power delivered by the system charging unit 33 is cut off, while the power input to the power board 32 is switched back to the power delivered by the solar controller 36 .

As another example, the power switching unit 322 is transmitted by the system charging unit 33 when the power charged in the system charging unit 33 is applied to the power board 32, when a preset switching time elapses. While the power is cut off, the power input to the power board 32 is switched back to the power delivered by the solar controller 36 .

First, even after the return switching operation, if an abnormality occurs in the power delivered by the solar controller 36 according to the monitoring of the power monitoring unit 321, the power switching unit 322 stops the entire operation of the environmental information collection system. On the other hand, by transmitting error information about power failure to the collection server 70, the environmental information collection system is protected, and the maintenance of the environmental information collection system can be quickly processed.

Second, even after the return switching operation, if an abnormality occurs in the power delivered by the solar controller 36 according to the monitoring of the power monitoring unit 321 , the power switching unit 322 is the power delivered by the solar controller 36 . On the other hand, it is possible to switch the power input to the power board 32 into power delivered by the system charging unit 33 . And when the power delivered by the solar controller 36 returns to normal, the power delivered by the system charging unit 33 is cut off, while the power input to the power board 32 is applied to the solar controller 36 . It can be switched back to power delivered by Here, when the abnormality of the power delivered by the solar controller 36 is maintained even to a preset dangerous charge amount of the charge amount of the system charging unit 33 in response to the charge amount of the system charging unit 33, the power switching unit 322 stops the entire operation of the environmental information collection system, and transmits error information about power failure to the collection server 70 to protect the environmental information collection system and to quickly process the maintenance of the environmental information collection system do.

7. When using the battery alone,

As the environmental information collection system according to an embodiment of the present invention is coupled to a fixture, a battery replacement or charging operation should be performed in parallel.

The collection control unit 30 controls the power delivered by the system charging unit 33 charged with power and the system charging unit 33 to sense at least one of the flow sensing unit 20 and the external sensing unit 60 . It may include a power board 32 including a power control unit 324 applied to the unit 20 .

Then, the power control unit 324 monitors the charging amount of the system charging unit (33). The power control unit 324 transmits risk information to the collection server 70 when the charging amount of the system charging unit 33 becomes smaller than the preset dangerous charging amount so that the system charging unit 33 is replaced or charged. .

The environmental information collection system according to an embodiment of the present invention may further include a communication unit 40 for transmitting the environmental information collected by the above-described sensing unit to the collection server 70 . The communication unit 40 may adopt at least one of wired and wireless communication methods.

The environmental information collection system according to an embodiment of the present invention may further include a collection server 70 for collecting and managing the environmental information transmitted from the communication unit 40 .

According to the above-described environmental information collection system, in collecting outdoor environmental information, the sensing reliability and durability are improved without being affected by natural phenomena such as rain, wind, snow, etc. can be improved In addition, by adding the inverted trapezoidal structure of the atmospheric flow unit 10, rainwater or external moisture can be prevented from flowing into the flow space 101, and the wind speed of the atmosphere flowing into the flow space 101 can be lowered. there is.

In addition, the accuracy of information on fine dust can be improved through the turbulence in the flow space 101 , and the distribution of the atmosphere in the flow space 101 can be made uniform.

In addition, through the structure of the flow hole portion 121 and the structure of the shielding portion), the wind speed of the air flowing into the flow space 101 is lowered, while the air can easily form turbulence in the flow space 101 .

In addition, even if a large amount of air is introduced into the flow space 101 through the structure of the discharge hole 111 , the wind speed is adjusted in the flow space 101 as an offsetting effect, and the discharge of the air flowing into the flow space 101 is prevented. and to allow the water flowing into the flow space 101 to be discharged quickly.

In addition, through the structure of the fine dust sensing module 22 , it is possible to minimize contact of moisture or moisture introduced into the flow space 101 with the fine dust sensor unit 26 and protect the fine dust sensor unit 26 . there is. In addition, when the circulation hole 243 is added, it is possible to smoothly flow the air flowing into the sensing space 241 .

Also, the environment information of the flow space 101 may be collected from the flow space 101 through the flow environment sensor unit 23 .

In addition, the operation of the fine dust sensor unit 26 and the opening/closing operation of the opening 242 can be made clear through the opening/closing control unit 27 .

In addition, through the configuration of the body unit 50, the components of the collection control unit 30 and the external sensing unit 60 and the communication unit 40 are protected from the outdoor atmosphere, and the coupling with the fixture 1 is stabilized. can do it

In addition, the power applied to the sensing units can be stabilized through the configuration of the collection control unit 30 .

In addition, through the configuration of the power supply unit 31 and the power board 32, it is possible to operate the environmental information collection system simply by using an external power source alone.

In addition, through the configuration of the system charging unit 33 can be charged using an external power source, it is possible to use the charging power according to the situation.

In addition, in the combination of the external power source and the battery, it is possible to stably control the power usage state of the external power source and the battery, and to clarify the operation of the environmental information collection system in response to an abnormality of the external power source.

In addition, since solar energy is used, the environmental information collection system is stably operated by using solar energy together with external power.

In addition, in the combination of external power and solar energy, it is possible to stably control the use state of external power and solar energy, and it is possible to clarify the operation of the environmental information collection system for abnormalities of external power.

In addition, it is possible to use any one of an external power source and solar energy to charge the battery, and it is possible to use the charging power by reflecting the priority according to the situation.

In addition, in the combination of external power, battery, and solar energy, it is possible to stably control the state of use of external power, solar energy, and battery, and to clarify the operation of the environmental information collection system for abnormalities of external power. .

In addition, through the configuration of the solar panel 34 , the solar supply unit 35 , the solar controller 36 and the power board 32 , the environmental information collection system can be operated simply by using solar energy alone.

In addition, in the combination of solar energy and battery, it is possible to stably control the state of using the power of the solar energy and the battery, and it is possible to clarify the operation of the environmental information collection system for the abnormality of the solar energy.

In addition, it is possible to clearly generate and transmit solar energy through the sensor monitoring unit 323 .

In addition, the environment information collected by the sensor units through the communication unit 40 may be delivered, stored and managed to the collection server 70 according to time series in real time.

In addition, it is possible to collect and monitor the environmental information provided by the environmental information collection system through the collection server 70, and to facilitate the management, supervision, and maintenance of the environmental information collection.

As described above, the preferred embodiments of the present invention have been described with reference to the drawings, but those skilled in the art may vary the present invention in various ways without departing from the spirit and scope of the present invention as set forth in the claims below. may be modified or changed.

1: fixture 10: atmospheric flow unit 11: base part
111: discharge hole portion 112: discharge inclined portion 12: inclined side
121: floating hole portion 122: shielding portion 13: ceiling portion
101: flow space 20: flow sensing unit 21: flow sensor board
22: fine dust sensing module 24: fine dust enclosure 241: sensing space
242: opening 243: circulation hole 25: opening control part
251: opening/closing member 252: opening/closing driving unit 26: fine dust sensor unit
23: flow environment sensor unit 27: opening/closing control unit 30: collection control unit
31: power supply unit 32: power board 321: power monitoring unit
322: power switching unit 323: sensor monitoring unit 324: power control unit
33: system charging unit 34: solar panel 35: solar supply unit
36: solar controller 40: communication unit 50: body unit
51: coupled body 52: door 60: external sensing unit
61: external sensor board 62: external environment sensor unit 63: wind speed sensor unit
64: wind direction sensor unit 70: collection server

Claims (8)

an atmospheric flow unit consisting of a hollow enclosure through which the outdoor atmosphere passes; and
A flow sensing unit provided inside the atmospheric flow unit and configured to collect and manage environmental information inside the atmospheric flow unit; includes;
The atmospheric flow unit,
a base portion facing the ground;
an inclined side portion extending upwardly inclined from the edge of the base portion to the outside to form a flow space in which the outdoor air is accommodated, and through which a flow hole through which the outdoor air passes is formed; and
and a ceiling portion spaced apart from the upper side of the base to close the flow space.
The flow sensing unit,
a flow sensor board that is provided to face the base in the flow space with respect to the ground and manages the collected environmental information of the flow space; and
and an environment sensing unit provided under the flow sensor board to collect environmental information of the flow space.
According to claim 1,
The atmospheric air flowing into the flow space through the flow hole forms a turbulence in the flow space.
3. The method of claim 2,
Environmental information collection system, characterized in that it includes; the inclined side, the shielding portion protruding outward from the upper end of the flow hole portion or protruding inward from the upper end of the flow hole portion.
According to claim 1,
In the base part,
An environmental information collection system, characterized in that through; a discharge hole for discharging at least one of the air and moisture introduced into the flow space.
According to claim 1,
The environmental sensing unit,
A fine dust sensing module connected to a lower portion of the flow sensor board in the flow space and configured to collect information on fine dust among environmental information of the flow space;
The fine dust sensing module,
a fine dust enclosure provided as a hollow housing at a lower portion of the flow sensor board in the flow space and having at least an opening among an opening and a circulation hole;
an opening control unit for opening and closing the opening; and
and a fine dust sensor unit embedded in the fine dust box in a state connected to the lower part of the flow sensor board to collect information on fine dust inside the fine dust enclosure;
The opening adjustment unit,
An environmental information collection system, characterized in that it operates according to at least one of the wind speed of the outdoor atmosphere and the humidity of the outdoor atmosphere.
6. The method of claim 5,
The environmental sensing unit,
A flow environment sensor unit spaced apart from the fine dust sensing module and connected to the lower portion of the flow sensor board to collect information other than the information on fine dust among the environmental information of the flow space; characterized by further comprising: Environmental information collection system.
6. The method of claim 5,
The environmental sensing unit,
An opening/closing control unit for stopping the operation of the fine dust sensor unit or closing the opening by extracting a state meaningless to the operation of the fine dust sensing module based on outdoor environmental information or environmental information of the flow space; Environmental information collection system, characterized in that it further comprises.
According to claim 1,
a body unit provided as a hollow housing on an upper portion of the atmospheric flow unit; and
It is provided in the main body unit, the external sensing unit for collecting and managing outdoor environmental information; further comprising,
The external sensing unit,
an external sensor board built into the main body unit and managing the collected outdoor environmental information; and
and an external environmental sensor unit connected to the external sensor board to collect outdoor environmental information.

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