CN116818023B

CN116818023B - Atmospheric environment monitoring emergency early warning device

Info

Publication number: CN116818023B
Application number: CN202311093499.0A
Authority: CN
Inventors: 周德荣; 郑龙飞; 杨珍; 陈启智
Original assignee: Nanjing Pulan Atmospheric Environment Research Institute Co ltd
Current assignee: Nanjing Pulan Atmospheric Environment Research Institute Co ltd
Priority date: 2023-08-29
Filing date: 2023-08-29
Publication date: 2023-11-07
Anticipated expiration: 2043-08-29
Also published as: CN116818023A

Abstract

The invention provides an atmospheric environment monitoring emergency early warning device, which relates to the technical field of atmospheric environment monitoring and comprises the following components: the system comprises a top side mounting plate, wherein a bottom side mounting plate is fixedly mounted on the bottom end face of the top side mounting plate through a rectangular supporting frame, a monitoring early warning shell is fixedly mounted on the bottom end face of the bottom side mounting plate, a timing module and a 5G module are further arranged inside the monitoring early warning shell, an atmospheric environment monitoring unit b belongs to an intermittent starting monitoring application design, the monitoring judgment of whether a data monitoring piece contained in the atmospheric environment monitoring unit a and the atmospheric environment monitoring unit b has faults or not is achieved, the problem that the existing monitoring equipment for atmospheric environment monitoring corresponds to the field needing to be monitored is solved, only one group of corresponding data monitoring pieces is usually arranged, but once the data monitoring piece corresponding to the monitoring field has faults, monitored data of the monitoring equipment always stay in an error state within a long time period, and the problem that workers judge the atmospheric environment monitoring is affected is solved.

Description

Atmospheric environment monitoring emergency early warning device

Technical Field

The invention relates to the technical field of atmospheric environment monitoring, in particular to an atmospheric environment monitoring emergency early warning device.

Background

Atmospheric environmental monitoring refers to monitoring and judging the type and concentration of pollutants in the atmospheric environment by observing and analyzing the change of the pollutants and the influence of the pollutants on the environment, and is not limited to the atmospheric environmental monitoring, but also includes synchronous monitoring of the temperature, humidity, wind speed, air pressure and the like of the air in the environment.

The existing monitoring equipment for atmospheric environment monitoring is usually placed outdoors, in the long-period application process, under the influence of the intrinsic factors of the self quality and the external factors such as rainwater, strong wind, rain and snow, the data monitoring pieces for atmospheric environment monitoring, such as an air temperature sensor, an ultraviolet sensor, a solar radiation sensor and the like, cannot realize the transmission of correct monitoring data once the data monitoring pieces fail, but the existing monitoring equipment for atmospheric environment monitoring corresponds to the field required to be monitored, usually only one group of corresponding data monitoring pieces, such as solar radiation, is provided with one group of corresponding solar radiation sensors to realize the monitoring, but once the data monitoring pieces corresponding to the monitoring field fail, the data transmitted back by the data monitoring pieces are in a normal state all the time, but if the current environment corresponds to the monitoring field beyond a monitoring threshold value, the data transmission cannot be realized, so that the monitored data of the monitoring equipment for atmospheric environment monitoring is always in an error state in a long period, and the monitoring judgment of the atmospheric environment is influenced by workers.

Disclosure of Invention

In view of this, the invention provides an atmospheric environment monitoring emergency early warning device, which realizes the data monitoring of the atmospheric environment through an atmospheric environment monitoring unit a and an atmospheric environment monitoring unit b, and the atmospheric environment monitoring unit b belongs to an intermittent starting monitoring application design, and the intermittent starting design is used for realizing the monitoring judgment of whether the data monitoring pieces contained in the atmospheric environment monitoring unit a and the atmospheric environment monitoring unit b have faults or not, so as to ensure that the data monitoring pieces in the atmospheric environment monitoring unit a are in a fault-free state, and ensure the accuracy of the monitored data in a long period of time.

The invention provides an atmospheric environment monitoring emergency early warning device, which specifically comprises: the top side mounting plate is fixedly arranged on the bottom end face of the top side mounting plate through a rectangular supporting frame, a mounting bottom plate is fixedly arranged at the center of the bottom end face of the bottom side mounting plate through a supporting rod, and mounting hole sites are formed in the four edge included angle positions of the top end face of the mounting bottom plate; the monitoring and early warning shell is fixedly arranged at the bottom end surface of the bottom side mounting plate, a microcontroller and a storage battery electrically connected with the microcontroller are arranged in the monitoring and early warning shell, a group of solar photovoltaic cell power generation panels are fixedly arranged at the front end surface of the rectangular support frame, and the solar photovoltaic cell power generation panels are electrically connected with the storage battery; the monitoring and early warning shell is internally provided with a timing module, a timing module and a 5G module, the initial set value of the timing module is twenty-four hours, and the timing module is electrically connected with the microcontroller; the initial set value of the timing module is thirty minutes, and the timing module is electrically connected with the microcontroller; and the 5G module is in wireless network transmission connection with the monitoring center.

Further, a rotating shaft a is rotatably arranged at the center part of the top end surface of the top side mounting plate through a group of bearings a, the top end of the rotating shaft a is positioned above the top end surface of the top side mounting plate, and an auxiliary transmission gear is fixedly arranged at the top end of the rotating shaft a; a side supporting plate is fixedly arranged on the front side and the rear left side and the right side of the top end of the top side mounting plate respectively.

Further, a main rotating block body is arranged above the left side of the top side mounting plate, the main rotating block body is of a decagon block structure, and the side end face of the main rotating block body is fixedly connected with two side support plates positioned on the left side through a connecting support plate a; the center part of the top end surface of the main rotating block body is rotatably provided with a rotating shaft b through a group of bearings b, and the top end surface of the rotating shaft b and the top end surface of the main rotating block body are positioned on the same horizontal plane; the bottom end of the rotating shaft b is positioned below the bottom end surface of the main rotating block body, the bottom end of the rotating shaft b is fixedly provided with a transmission gear a, and the transmission gear a is meshed with the auxiliary transmission gear; the top end surface of the main rotating block body is fixedly provided with a group of driving motors, the rotating shaft ends of the driving motors are fixedly connected with the rotating shaft b, the driving motors are electrically connected with the microcontroller, the driving motors are started to drive the rotating shaft b to rotate anticlockwise for one circle, and the time for one circle of rotation is less than the initial set value of the timing module by one minute.

Further, an L-shaped mounting plate a is fixedly mounted on the ten side end faces of the main rotating block, an air temperature sensor a, an ultraviolet sensor a, a solar radiation sensor a, a wind direction sensor a, a PM2.5 sensor a, an atmospheric pressure sensor a, an illuminance sensor a, an air humidity sensor a, a wind speed sensor a and a carbon dioxide sensor a are fixedly mounted on the long end top end faces of the ten L-shaped mounting plates a respectively, and the air temperature sensor a, the ultraviolet sensor a, the solar radiation sensor a, the wind direction sensor a, the PM2.5 sensor a, the atmospheric pressure sensor a, the illuminance sensor a, the wind speed sensor a and the carbon dioxide sensor a form an atmospheric environment monitoring unit a together, and the atmospheric environment monitoring unit a is electrically connected with the microcontroller.

Further, a secondary rotating block body is arranged above the right side of the top side mounting plate, the secondary rotating block body is of a decagon block structure, and the side end face of the secondary rotating block body is fixedly connected with two side support plates positioned on the right side through a connecting support plate b; the center part of the top end surface of the auxiliary rotating block body is rotatably provided with a rotating shaft c through a group of bearings c, and the top end of the rotating shaft c is positioned above the top end surface of the auxiliary rotating block body; the bottom end of the rotating shaft c is positioned below the bottom end surface of the auxiliary rotating block body, a transmission gear b is fixedly arranged at the bottom end of the rotating shaft c, and the transmission gear b is meshed with the auxiliary transmission gear.

Further, an L-shaped mounting plate b is fixedly mounted on the side end face of ten positions of the auxiliary rotating block, an air temperature sensor b, an ultraviolet sensor b, a solar radiation degree sensor b, a wind direction sensor b, a PM2.5 sensor b, an atmospheric pressure sensor b, an illuminance sensor b, an air humidity sensor b, a wind speed sensor b and a carbon dioxide sensor b are fixedly mounted on the top end face of the long end of the ten L-shaped mounting plates b, the air temperature sensor b, the ultraviolet sensor b, the solar radiation degree sensor b, the wind direction sensor b, the PM2.5 sensor b, the atmospheric pressure sensor b, the illuminance sensor b, the air humidity sensor b, the wind speed sensor b and the carbon dioxide sensor b form an atmospheric environment monitoring unit b together, and the atmospheric environment monitoring unit b is electrically connected with the microcontroller.

Further, a pressing matching plate is arranged above the auxiliary rotating block body, the pressing matching plate is of a circular plate structure, a fixed mounting hole is formed in the axial center of the pressing matching plate, the fixed mounting hole is fixedly mounted with the top end of the rotating shaft c, and the bottom end face of the pressing matching plate is higher than the top end face of the auxiliary rotating block body; the top end surface of the auxiliary rotating block body is provided with an annular pressing groove, a group of temporary starting power switches are fixedly arranged at the front side of the bottom surface of the inner end of the annular pressing groove, the temporary starting power switches are electrically connected with the microcontroller, the temporary starting power switches adopt tact switches, the key ends of the temporary starting power switches face to the right upper side, and the top end surface of the key ends of the temporary starting power switches and the top end surface of the auxiliary rotating block body are in the same horizontal plane; the bottom end surface of the abutting-press fit plate is fixedly adhered with a rubber abutting-press strip relative to the annular abutting-press groove, the head end and the tail end of the rubber abutting-press strip are not contacted, and the head end and the tail end of the rubber abutting-press strip are not connected, and correspond to the position where the temporary starting power switch is located; the longitudinal section of the rubber pressing strip is of an arc-shaped structure, and the bottom end of the arc surface of the rubber pressing strip is positioned in the annular pressing groove; when the rubber pressing strip is contacted with the temporary starting power switch, the temporary starting power switch is in a pressed starting state at the moment, and when the temporary starting power switch is positioned at a part where the head end and the tail end of the rubber pressing strip are not connected, the temporary starting power switch is in a non-pressed starting state at the moment.

Further, an embedded mounting groove is formed in the front side of the top end of the auxiliary rotating block body, a group of timing reset keys are fixedly mounted on the bottom surface of the inner end of the embedded mounting groove, the timing reset keys are electrically connected with the microcontroller, the timing reset keys adopt a tact switch, the key ends of the timing reset keys face to the right upper side, and the top end surfaces of the key ends of the timing reset keys are higher than the top end surfaces of the auxiliary rotating block body; a rubber pressing convex block is fixedly adhered to the bottom end surface of the pressing matching plate, the rubber pressing convex block is of an arc-shaped block structure, and the bottom surface of the arc surface of the rubber pressing convex block is contacted with the top end surface of the auxiliary rotating block; the rubber pressing convex block and the embedded mounting groove are positioned on the same circular contour line, when the rubber pressing convex block corresponds to the embedded mounting groove, the timing reset key is in a pressed starting state, and when the rubber pressing convex block does not correspond to the embedded mounting groove, the timing reset key is in a non-pressed starting state; when the temporary starting power switch is positioned at the position where the head end and the tail end of the rubber pressing bar are not connected, the rubber pressing protruding block is positioned at the right side of the embedded mounting groove.

The atmospheric environment monitoring emergency early warning device provided by the invention has the following beneficial effects:

1. according to the invention, the atmospheric environment monitoring unit a and the atmospheric environment monitoring unit b are used for realizing data monitoring of the atmospheric environment, the atmospheric environment monitoring unit b belongs to an intermittent starting monitoring application design, and the monitoring judgment of whether the data monitoring pieces contained in the atmospheric environment monitoring unit a and the atmospheric environment monitoring unit b have faults or not is realized through the intermittent starting design, so that the data monitoring pieces in the atmospheric environment monitoring unit a are in a fault-free state, and the accuracy of the monitored data is ensured in a long period of time.

2. According to the invention, the self-starting monitoring application of the atmospheric environment monitoring unit b is realized through the pressing fit arrangement of the rubber pressing strip and the temporary starting power switch, and the automatic monitoring application stage of the atmospheric environment monitoring unit b is realized through the pressing fit arrangement of the rubber pressing protruding block and the timing reset key, so that the automatic monitoring judgment on whether the operation of the driving motor is faulty or not is realized, and the intermittent starting monitoring application of the atmospheric environment monitoring unit b can normally operate.

Drawings

In order to more clearly illustrate the technical solution of the embodiments of the present invention, the drawings of the embodiments will be briefly described below.

The drawings described below are only for illustration of some embodiments of the invention and are not intended to limit the invention.

In the drawings:

fig. 1 is an isometric view of an embodiment of the invention.

Fig. 2 is a schematic diagram of a split structure according to an embodiment of the present invention.

FIG. 3 is an isometric view of a top mounting plate according to an embodiment of the invention.

Fig. 4 is a schematic view of a partial enlarged structure at a in fig. 3 according to an embodiment of the present invention.

Fig. 5 is a schematic diagram of the axial structure of a main rotating block according to an embodiment of the present invention.

Fig. 6 is a schematic view of the main rotation block according to the embodiment of the present invention in a disassembled state.

Fig. 7 is an isometric view of a secondary pivoting block according to an embodiment of the present invention.

Fig. 8 is a schematic top end perspective view of an embodiment of the present invention in a disassembled state of a secondary rotating block.

Fig. 9 is a partially enlarged structural schematic diagram of fig. 8B in accordance with an embodiment of the present invention.

Fig. 10 is a schematic view of the bottom end perspective structure in the disassembled state of the auxiliary rotating block according to the embodiment of the present invention.

Fig. 11 is an enlarged partial sectional structural schematic view of a sub-rotating block according to an embodiment of the present invention.

FIG. 12 is an enlarged partial cross-sectional structural schematic view of C-C of FIG. 11 in accordance with an embodiment of the present invention.

FIG. 13 is an enlarged schematic view of the structure of FIG. 11 with D-D partially cut away, in accordance with an embodiment of the invention.

Fig. 14 is a schematic top view of an embodiment of the present invention.

FIG. 15 is an enlarged partial cross-sectional structural schematic of E-E of FIG. 14 in accordance with an embodiment of the present invention.

Fig. 16 is a system block diagram of an embodiment of the present invention.

Fig. 17 is a system component block diagram of an atmospheric environment monitoring unit a according to an embodiment of the present invention.

Fig. 18 is a system block diagram of an atmospheric environment monitoring unit b according to an embodiment of the present invention.

List of reference numerals:

1. a top mounting plate; 101. a rectangular support frame; 102. a bottom mounting plate; 103. monitoring and early warning shells; 104. a solar photovoltaic cell panel; 105. a support rod; 106. a mounting base plate; 107. installing hole sites; 108. a side support plate; 109. an auxiliary transmission gear; 1010. a rotating shaft a; 1011. a bearing a; 1012. a storage battery; 1013. a timing module; 1014. a timing module; 1015. a 5G module; 1016. a monitoring center; 1017. a microcontroller;

2. a main rotating block; 201. a driving motor; 202. a connecting support plate a; 203. a transmission gear a; 204. an L-shaped mounting plate a; 205. a rotating shaft b; 206. a bearing b;

3. a secondary rotating block; 301. pressing the matched plate; 302. a connecting support plate b; 303. a transmission gear b; 304. an L-shaped mounting plate b; 305. a rotating shaft c; 306. fixing the mounting hole; 307. a bearing c; 308. an annular pressing groove; 309. an embedded mounting groove; 3010. temporarily starting a power switch; 3011. a timing reset key; 3012. a rubber pressing bar; 3013. rubber pressing the protruding block;

001. an atmospheric environment monitoring unit a; 01. an air temperature sensor a; 02. an ultraviolet sensor a; 03. a solar radiation degree sensor a; 04. a wind direction sensor a; 05. PM2.5 sensor a; 06. an atmospheric pressure sensor a; 07. an illuminance sensor a; 08. an air humidity sensor a; 09. a wind speed sensor a; 010. a carbon dioxide sensor a;

002. an atmospheric environment monitoring unit b; 011. an air temperature sensor b; 021. an ultraviolet sensor b; 031. a solar radiation degree sensor b; 041. a wind direction sensor b; 051. PM2.5 sensor b; 061. an atmospheric pressure sensor b; 071. an illuminance sensor b; 081. an air humidity sensor b; 091. a wind speed sensor b; 0101. a carbon dioxide sensor b.

Detailed Description

In order to make the objects, aspects and advantages of the technical solution of the present invention more clear, the technical solution of the embodiment of the present invention will be clearly and completely described below with reference to the accompanying drawings of the specific embodiment of the present invention.

Please refer to fig. 1 to 18:

embodiment one: the invention provides an atmospheric environment monitoring emergency early warning device, which comprises a top side mounting plate 1, wherein a bottom side mounting plate 102 is fixedly arranged on the bottom end surface of the top side mounting plate 1 through a rectangular supporting frame 101, a mounting bottom plate 106 is fixedly arranged on the central part of the bottom end surface of the bottom side mounting plate 102 through a supporting rod 105, and a mounting hole site 107 is formed in the position of an included angle of four edges of the top end surface of the mounting bottom plate 106; the bottom end surface of the bottom side mounting plate 102 is fixedly provided with a monitoring and early warning shell 103, a microcontroller 1017 and a storage battery 1012 electrically connected with the microcontroller 1017 are arranged in the monitoring and early warning shell 103, the front end surface of the rectangular supporting frame 101 is fixedly provided with a group of solar photovoltaic cell power generation panels 104, and the solar photovoltaic cell power generation panels 104 are electrically connected with the storage battery 1012, so that the self-supply of a power supply is realized through the cooperation of the solar photovoltaic cell power generation panels 104 and the storage battery 1012; the interior of the monitoring and early-warning shell 103 is also provided with a timing module 1013, a timing module 1014 and a 5G module 1015, the initial set value of the timing module 1013 is twenty-four hours, the initial set value of the timing module 1013 is not limited to twenty-four hours, the timing module 1013 can be correspondingly increased or decreased according to the requirement, and the timing module 1013 is electrically connected with the microcontroller 1017; the initial setting value of the timing module 1014 is thirty minutes, the initial setting value of the timing module 1014 is not limited to thirty minutes, and can be correspondingly increased or decreased according to requirements, and the timing module 1014 is electrically connected with the microcontroller 1017; the 5G module 1015 is in wireless network transmission connection with the monitoring center 1016, so that the monitored data can be transmitted to the monitoring center 1016 in real time through the 5G module 1015.

The center part of the top end surface of the top side mounting plate 1 is rotatably provided with a rotating shaft a1010 through a group of bearings a1011, the top end of the rotating shaft a1010 is positioned above the top end surface of the top side mounting plate 1, the top end of the rotating shaft a1010 is fixedly provided with an auxiliary transmission gear 109, and synchronous meshing transmission of a transmission gear b303 and a transmission gear a203 is realized through the auxiliary transmission gear 109; a side supporting plate 108 is fixedly arranged on the front side, the rear side, the left side and the right side of the top end of the top side mounting plate 1.

A main rotating block 2 is arranged above the left side of the top side mounting plate 1, the main rotating block 2 is in a decagonal block structure, and the side end surface of the main rotating block 2 is fixedly connected with two side support plates 108 positioned on the left side through a connecting support plate a 202; the center part of the top end surface of the main rotary block 2 is rotatably provided with a rotary shaft b205 through a group of bearings b206, and the top end surface of the rotary shaft b205 and the top end surface of the main rotary block 2 are positioned on the same horizontal plane; the bottom end of the rotating shaft b205 is positioned below the bottom end surface of the main rotating block 2, a transmission gear a203 is fixedly arranged at the bottom end of the rotating shaft b205, and the transmission gear a203 is meshed with the auxiliary transmission gear 109; the top end surface of the main rotating block 2 is fixedly provided with a group of driving motors 201, the rotating shaft ends of the driving motors 201 are fixedly connected with the rotating shaft b205, the driving motors 201 are electrically connected with the micro controller 1017, the rotating shaft b205 is driven to rotate anticlockwise for one circle after the driving motors 201 are started, and the rotating time is one minute less than the initial set value of the timing module 1014, so that the timing of the timing module 1014 is reset one minute in advance when the driving motors 201 run without faults.

The main rotating block 2 is fixedly provided with an L-shaped mounting plate a204 on ten side end surfaces, the long end top end surfaces of the ten L-shaped mounting plates a204 are respectively and fixedly provided with an air temperature sensor a01, an ultraviolet sensor a02, a solar radiation degree sensor a03, a wind direction sensor a04, a PM2.5 sensor a05, an atmospheric pressure sensor a06, an illuminance sensor a07, an air humidity sensor a08, a wind speed sensor a09 and a carbon dioxide sensor a010, and the air temperature sensor a08, the wind speed sensor a09 and the carbon dioxide sensor a010 form an atmospheric environment monitoring unit a001 together, the atmospheric environment monitoring unit a001 is electrically connected with a microcontroller 1017, and the atmospheric environment monitoring unit a001 is used for monitoring the atmospheric environment in a daily state.

The upper right side of the top side mounting plate 1 is provided with a pair of rotary blocks 3, the pair of rotary blocks 3 are in a decagon block structure, and the side end surfaces of the pair of rotary blocks 3 are fixedly connected with two side support plates 108 positioned on the right side through a connecting support plate b 302; a rotating shaft c305 is rotatably arranged at the center part of the top end surface of the auxiliary rotating block 3 through a group of bearings c307, and the top end of the rotating shaft c305 is positioned above the top end surface of the auxiliary rotating block 3; the bottom end of the rotating shaft c305 is positioned below the bottom end surface of the auxiliary rotating block 3, a transmission gear b303 is fixedly arranged at the bottom end of the rotating shaft c305, and the transmission gear b303 and the transmission gear a203 have the same specification and size, so that when the transmission gear b303 rotates for one circle, the transmission gear a203 synchronously rotates for one circle, and the transmission gear b303 is meshed with the auxiliary transmission gear 109.

An L-shaped mounting plate b304 is fixedly mounted on ten side end surfaces of the auxiliary rotating block 3, an air temperature sensor b011, an ultraviolet sensor b021, a solar radiation sensor b031, a wind direction sensor b041, a PM2.5 sensor b051, an atmospheric pressure sensor b061, an illuminance sensor b071, an air humidity sensor b081, a wind speed sensor b091 and a carbon dioxide sensor b0101 are respectively and fixedly mounted on the long end top end surfaces of the ten L-shaped mounting plates b304, and together form an atmospheric environment monitoring unit b002, the atmospheric environment monitoring unit b002 is electrically connected with the microcontroller 1017, and the atmospheric environment monitoring unit b002 monitors the atmospheric environment so that staff can judge whether a data monitoring piece in the atmospheric environment monitoring unit a001 has faults through comparison of monitoring data.

Wherein, a pressing matching plate 301 is arranged above the auxiliary rotating block 3, the pressing matching plate 301 is in a circular plate structure, a fixed mounting hole 306 is arranged at the axle center part of the pressing matching plate 301, the fixed mounting hole 306 is fixedly mounted with the top end of the rotating shaft c305, and the bottom end surface of the pressing matching plate 301 is higher than the top end surface of the auxiliary rotating block 3; an annular pressing groove 308 is formed in the top end surface of the auxiliary rotating block 3, a group of temporary starting power switches 3010 are fixedly arranged at the front side of the bottom surface of the inner end of the annular pressing groove 308, the temporary starting power switches 3010 are electrically connected with the microcontroller 1017, the temporary starting power switches 3010 are light-touch switches, the key ends of the temporary starting power switches 3010 face right above, and the top end surfaces of the key ends of the temporary starting power switches 3010 and the top end surface of the auxiliary rotating block 3 are in the same horizontal plane; a rubber pressing strip 3012 is fixedly adhered to the bottom end surface of the pressing fit plate 301 relative to the annular pressing groove 308, the head and tail ends of the rubber pressing strip 3012 are not contacted, and the head and tail non-connected part of the rubber pressing strip 3012 corresponds to the position where the temporary starting power switch 3010 is located; the longitudinal section of the rubber pressing strip 3012 is of an arc-shaped structure, and the bottom end of the arc surface of the rubber pressing strip 3012 is positioned in the annular pressing groove 308; when the rubber pressing strip 3012 is in contact with the temporary starting power switch 3010, the temporary starting power switch 3010 is in a pressed starting state at this time, and when the temporary starting power switch 3010 is positioned at a position where the head end and the tail end of the rubber pressing strip 3012 are not connected, the temporary starting power switch 3010 is in an unpressed starting state at this time.

Specific use and action of the embodiment:

when the daily atmospheric environment monitoring application is carried out, the atmospheric environment monitoring unit a001 is in a starting state, the data monitoring of the current environment is realized through the air temperature sensor a01, the ultraviolet sensor a02, the solar radiation sensor a03, the wind direction sensor a04, the PM2.5 sensor a05, the atmospheric pressure sensor a06, the illuminance sensor a07, the air humidity sensor a08, the wind speed sensor a09 and the carbon dioxide sensor a010, and the monitored data are transmitted to the monitoring center 1016 in real time through the 5G module 1015, so that staff in the monitoring center 1016 can judge the specific condition of the monitored environment by observing the monitored data, so that monitoring early warning is realized when a certain group of monitoring data is observed to exceed a threshold value, so that the staff can be conveniently sent to go to the actual investigation in time, and corresponding improvement measures are determined according to the specific condition;

the invention is also provided with an atmospheric environment monitoring unit b002, when the atmospheric environment monitoring unit b002 is in an unactuated state in daily atmospheric environment monitoring application, and when the timing value set by the timing module 1013 is reached, the atmospheric environment monitoring unit b002 gives a feedback signal to the microcontroller 1017, the microcontroller 1017 simultaneously controls the driving motor 201 and the timing module 1014 to start, the driving motor 201 rotates the driving rotating shaft b205 after starting, thereby synchronously driving the transmission gear a203 to rotate, the transmission gear a203 is meshed with the transmission gear b303 through the auxiliary transmission gear 109 to rotate in the same direction, when the transmission gear b303 rotates, the transmission gear b303 drives the pressing fit plate 301 to rotate through the rotating shaft c305, and during the rotation of the pressing fit plate 301, the rubber pressing strip 3012 which is not contacted with the key end of the temporary starting power switch 3010 is contacted with the pressing strip 3010 at the moment, the temporary starting power switch 3010 is in a pressed starting state, the feedback signal is given to the microcontroller 1017, the microcontroller 1017 controls the atmospheric environment monitoring unit b002 to start, and the data of the current environment is monitored by the air temperature sensor b011, the ultraviolet sensor b021, the solar radiation sensor b031, the wind direction sensor b041, the PM2.5 sensor b051, the atmospheric pressure sensor b061, the illuminance sensor b071, the air humidity sensor b081, the wind speed sensor b091 and the carbon dioxide sensor b0101, and the monitored data is transmitted to the monitoring center 1016 in real time through the 5G module 1015, so that the monitored data transmitted by the staff in the monitoring center 1016 through the atmospheric environment monitoring unit a001 is compared with the monitored data transmitted by the atmospheric environment monitoring unit b002, whether the data difference is too large is compared, and whether a certain group of data monitoring pieces contained in the atmospheric environment monitoring unit a001 or the atmospheric environment monitoring unit b002 fail is judged, when the difference of a certain group of data is too large, the corresponding group of data monitoring pieces contained in the atmospheric environment monitoring unit a001 or the atmospheric environment monitoring unit b002 is judged to be faulty, so that a worker can be sent out in time to carry out maintenance treatment, and the situation that the monitoring data corresponding to the data monitoring pieces in a long period of time are in a monitoring error state and influence the corresponding atmospheric environment monitoring judgment is avoided.

Embodiment two: based on the first embodiment, the atmospheric environment monitoring emergency early warning device provided by the first embodiment can judge whether the data monitoring piece contained in the atmospheric environment monitoring unit a001 or the atmospheric environment monitoring unit b002 fails or not through the comparison of the monitoring data of the atmospheric environment monitoring unit a001 and the atmospheric environment monitoring unit b002, and the atmospheric environment monitoring emergency early warning device further comprises: an embedded mounting groove 309 is formed in the front side of the top end face of the auxiliary rotating block 3, a group of timing reset keys 3011 are fixedly mounted on the bottom face of the inner end of the embedded mounting groove 309, the timing reset keys 3011 are electrically connected with a microcontroller 1017, the timing reset keys 3011 are light touch switches, the key ends of the timing reset keys 3011 face right above, and the top end face of the key ends of the timing reset keys 3011 is higher than the top end face of the auxiliary rotating block 3; a rubber pressing protruding block 3013 is fixedly adhered to the bottom end surface of the pressing matching plate 301, the rubber pressing protruding block 3013 is of an arc-shaped block structure, and the bottom surface of the arc surface of the rubber pressing protruding block 3013 is contacted with the top end surface of the auxiliary rotating block 3; the rubber pressing protruding block 3013 and the embedded mounting groove 309 are positioned on the same circular contour line, when the rubber pressing protruding block 3013 corresponds to the embedded mounting groove 309 in position, the timing reset key 3011 is in a pressed starting state, and when the rubber pressing protruding block 3013 does not correspond to the embedded mounting groove 309 in position, the timing reset key 3011 is in a non-pressed starting state; when the temporary starting power switch 3010 is positioned at the position where the two ends of the head end and the tail end of the rubber pressing strip 3012 are not connected, the rubber pressing protruding block 3013 is positioned at the right side of the embedded mounting groove 309, so that when the pressing matching plate 301 rotates anticlockwise, the rubber pressing protruding block 3013 does not start to press the timing reset key 3011, when the pressing matching plate 301 rotates anticlockwise to reach one circle, the rubber pressing protruding block 3013 inevitably presses the timing reset key 3011, and then when the rubber pressing protruding block 3013 reaches one circle, the rubber pressing protruding block 3013 is separated from the timing reset key 3011;

the time for driving the rotating shaft b205 to rotate anticlockwise for one circle after the driving motor 201 is started is less than the initial set value of the timing module 1014 by one minute, so when the driving motor 201 runs without faults, when the driving motor 201 drives the rotating shaft b205 to rotate to one circle, the rubber pressing bulge block 3013 presses the key end of the timing reset key 3011, at the moment, the timing reset key 3011 is in a pressed starting state, a feedback signal of the timing reset key 3011 is given to the microcontroller 1017, the microcontroller 1017 controls the timing module 1014 to reset the timing, and when the driving motor 201 drives the rotating shaft b205 to rotate to one circle, at the moment, the temporary starting power switch 3010 is positioned at a position where the head end and the tail end of the rubber pressing strip 3012 are not connected, the rubber pressing strip 3012 is separated from the key end of the temporary starting power switch 3010, and at the moment, the driving motor 201, the timing module 1014 and the atmospheric environment monitoring unit b002 are all in a closed state;

when the driving motor 201 fails, the timing module 1014 determines that the driving motor 201 fails when the driving motor reaches the button end of the timing reset button 3011 which is not pressed by the rubber pressing protrusion block 3013 before the driving motor 201 fails, and when the timing module 1014 reaches the button end of the timing reset button 3011 to count the time, the timing module 1014 gives a feedback signal to the microcontroller 1017, and the microcontroller 1017 sends a message to the monitoring center 1016 through the 5G module 1015, so that a worker in the monitoring center 1016 can timely learn that the driving motor 201 fails, and needs to dispatch a worker to go to perform maintenance processing.

The above is only an exemplary embodiment of the present invention and is not intended to limit the scope of the present invention, which is defined by the appended claims.

Claims

1. An atmospheric environment monitoring emergency early warning device, which is characterized by comprising: the device comprises a top side mounting plate (1), wherein a bottom side mounting plate (102) is fixedly mounted on the bottom end surface of the top side mounting plate (1) through a rectangular supporting frame (101), a mounting bottom plate (106) is fixedly mounted on the center part of the bottom end surface of the bottom side mounting plate (102) through a supporting rod (105), and a mounting hole site (107) is formed in the position of an included angle of four edges of the top end surface of the mounting bottom plate (106); a monitoring and early warning shell (103) is fixedly arranged on the bottom end surface of the bottom side mounting plate (102), a microcontroller (1017) and a storage battery (1012) electrically connected with the microcontroller are arranged in the monitoring and early warning shell (103), a group of solar photovoltaic cell generating panels (104) are fixedly arranged on the front end surface of the rectangular supporting frame (101), and the solar photovoltaic cell generating panels (104) are electrically connected with the storage battery (1012); a timing module (1013), a timing module (1014) and a 5G module (1015) are further arranged in the monitoring and early-warning shell (103), an initial set value of the timing module (1013) is twenty-four hours, and the timing module (1013) is electrically connected with the microcontroller (1017); the initial set value of the timing module (1014) is thirty minutes, and the timing module (1014) is electrically connected with the microcontroller (1017); the 5G module (1015) is in wireless network transmission connection with the monitoring center (1016);

a main rotating block (2) is arranged above the left side of the top side mounting plate (1); an L-shaped mounting plate a (204) is fixedly mounted on ten side end surfaces of the main rotating block body (2), an air temperature sensor a (01), an ultraviolet sensor a (02), a solar radiation sensor a (03), a wind direction sensor a (04), a PM2.5 sensor a (05), an atmospheric pressure sensor a (06), an illuminance sensor a (07), an air humidity sensor a (08), a wind speed sensor a (09) and a carbon dioxide sensor a (010) are fixedly mounted on the top end surfaces of the long ends of the ten L-shaped mounting plate a (204), and the air temperature sensor a (001), the wind direction sensor a (04), the PM2.5 sensor a (05), the atmospheric pressure sensor a (06), the illuminance sensor a (07), the air humidity sensor a (08), the wind speed sensor a (09) and the carbon dioxide sensor a (010) form an atmospheric environment monitoring unit a (001) together, and the atmospheric environment monitoring unit a (001) is electrically connected with a microcontroller (1017);

a secondary rotating block (3) is arranged above the right side of the top side mounting plate (1); an L-shaped mounting plate b (304) is fixedly mounted on ten side end surfaces of the auxiliary rotating block (3), an air temperature sensor b (011), an ultraviolet sensor b (021), a solar radiation degree sensor b (031), a wind direction sensor b (041), a PM2.5 sensor b (051), an atmospheric pressure sensor b (061), an illuminance sensor b (071), an air humidity sensor b (081), a wind speed sensor b (091) and a carbon dioxide sensor b (0101) are fixedly mounted on the top end surfaces of the long ends of the ten L-shaped mounting plates b (304) respectively, and the air temperature sensor b (002), the atmospheric environment monitoring unit b (002) and the microcontroller (1017) are electrically connected;

a rotating shaft c (305) is rotatably arranged at the center part of the top end surface of the auxiliary rotating block (3) through a group of bearings c (307); a pressing and matching plate (301) is arranged above the auxiliary rotating block (3), the pressing and matching plate (301) is of a circular plate structure, a fixed mounting hole (306) is formed in the axial center of the pressing and matching plate (301), the fixed mounting hole (306) is fixedly mounted with the top end of the rotating shaft c (305), and the bottom end surface of the pressing and matching plate (301) is higher than the top end surface of the auxiliary rotating block (3); an annular pressing groove (308) is formed in the top end surface of the auxiliary rotating block (3), a group of temporary starting power switches (3010) are fixedly arranged at the front side of the bottom surface of the inner end of the annular pressing groove (308), the temporary starting power switches (3010) are electrically connected with the microcontroller (1017), the temporary starting power switches (3010) are light-touch switches, the key ends of the temporary starting power switches (3010) face right above, and the top end surface of the key ends of the temporary starting power switches (3010) and the top end surface of the auxiliary rotating block (3) are in the same horizontal plane; a rubber pressing strip (3012) is fixedly adhered to the bottom end surface of the pressing fit plate (301) relative to the annular pressing groove (308), the head end and the tail end of the rubber pressing strip (3012) are not contacted, and the head end and the tail end of the rubber pressing strip (3012) are not connected, and correspond to the position where the temporary starting power switch (3010) is located; the longitudinal section of the rubber pressing strip (3012) is of an arc-shaped structure, and the bottom end of the arc surface of the rubber pressing strip (3012) is positioned in the annular pressing groove (308); when the rubber pressing strip (3012) is contacted with the temporary starting power switch (3010), the temporary starting power switch (3010) is in a pressed starting state at the moment, and when the temporary starting power switch (3010) is positioned at a part where the head end and the tail end of the rubber pressing strip (3012) are not connected, the temporary starting power switch (3010) is in an unpressed starting state at the moment.

2. The atmospheric environment monitoring emergency pre-warning device according to claim 1, wherein: a rotating shaft a (1010) is rotatably arranged at the center part of the top end surface of the top side mounting plate (1) through a group of bearings a (1011), the top end of the rotating shaft a (1010) is positioned above the top end surface of the top side mounting plate (1), and an auxiliary transmission gear (109) is fixedly arranged at the top end of the rotating shaft a (1010); a side supporting plate (108) is fixedly arranged on the left side and the right side of the front part and the rear part of the top end of the top side mounting plate (1).

3. The atmospheric environment monitoring emergency pre-warning device according to claim 2, wherein: the main rotating block body (2) is in a decagonal block structure, and the side end surface of the main rotating block body (2) is fixedly connected with two side support plates (108) positioned at the left side through a connecting support plate a (202); a rotating shaft b (205) is rotatably arranged at the center part of the top end surface of the main rotating block (2) through a group of bearings b (206), and the top end surface of the rotating shaft b (205) and the top end surface of the main rotating block (2) are positioned on the same horizontal plane; the bottom end of the rotating shaft b (205) is positioned below the bottom end surface of the main rotating block body (2), the bottom end of the rotating shaft b (205) is fixedly provided with a transmission gear a (203), and the transmission gear a (203) is meshed with the auxiliary transmission gear (109); the top end surface of the main rotating block body (2) is fixedly provided with a group of driving motors (201), the rotating shaft ends of the driving motors (201) are fixedly connected with the rotating shaft b (205), the driving motors (201) are electrically connected with the microcontroller (1017), the driving motors (201) are started to drive the rotating shaft b (205) to rotate anticlockwise for one circle, and the time for one circle of rotation is less than the initial set value of the timing module (1014) by one minute.

4. The atmospheric environment monitoring emergency pre-warning device according to claim 3, wherein: the auxiliary rotating block body (3) is in a decagonal block structure, and the side end surface of the auxiliary rotating block body (3) is fixedly connected with two side support plates (108) positioned on the right side through a connecting support plate b (302); the top end of the rotating shaft c (305) is positioned above the top end surface of the auxiliary rotating block (3); the bottom end of the rotating shaft c (305) is positioned below the bottom end surface of the auxiliary rotating block body (3), a transmission gear b (303) is fixedly arranged at the bottom end of the rotating shaft c (305), the transmission gear b (303) and the transmission gear a (203) have the same specification and size, and the transmission gear b (303) is meshed with the auxiliary transmission gear (109).

5. The atmospheric environment monitoring emergency pre-warning device according to claim 4, wherein: an embedded mounting groove (309) is formed in the front side of the top end face of the auxiliary rotating block body (3), a group of timing reset keys (3011) are fixedly arranged on the bottom face of the inner end of the embedded mounting groove (309), the timing reset keys (3011) are electrically connected with a microcontroller (1017), the timing reset keys (3011) adopt a tact switch, the key ends of the timing reset keys (3011) face to the right upper side, and the top end faces of the key ends of the timing reset keys (3011) are higher than the top end faces of the auxiliary rotating block body (3); a rubber pressing convex block (3013) is fixedly adhered to the bottom end surface of the pressing matching plate (301), the rubber pressing convex block (3013) is of an arc-shaped block structure, and the cambered bottom surface of the rubber pressing convex block (3013) is contacted with the top end surface of the auxiliary rotating block (3); the rubber pressing convex block (3013) and the embedded mounting groove (309) are positioned on the same circular contour line, when the rubber pressing convex block (3013) corresponds to the embedded mounting groove (309), the timing reset key (3011) is in a pressed starting state, and when the rubber pressing convex block (3013) does not correspond to the embedded mounting groove (309), the timing reset key (3011) is in an unpressed starting state; when the temporary starting power switch (3010) is positioned at the part where the head end and the tail end of the rubber pressing strip (3012) are not connected, the rubber pressing convex block (3013) is positioned at the right side part of the embedded mounting groove (309).