CN111947717A

CN111947717A - Environmental monitoring device based on big data

Info

Publication number: CN111947717A
Application number: CN202010829280.2A
Authority: CN
Inventors: 陈美霞
Original assignee: Individual
Current assignee: Hebei Qiujing Environmental Protection Technology Co Ltd
Priority date: 2020-08-18
Filing date: 2020-08-18
Publication date: 2020-11-17
Anticipated expiration: 2040-08-18
Also published as: CN111947717B

Abstract

The invention relates to the technical field of environmental monitoring, in particular to an environmental monitoring device based on big data, which comprises an environmental information acquisition mechanism, a vertical frame mechanism, an installation table, a supporting leg mechanism and a control mechanism, wherein the environmental information acquisition mechanism is connected to the vertical frame mechanism in a matching way; the vertical frame mechanism is connected to the mounting table in a matching manner; the three support leg mechanisms are uniformly and fixedly connected to the mounting table in a surrounding manner; the mounting table is positioned between the support leg mechanism and the stand mechanism; the middle part of the control mechanism is movably connected to the mounting table; the control mechanism is in transmission connection with the stand mechanism and the three support leg mechanisms. The overall height of the invention is convenient to adjust, so that the environmental information acquisition mechanism can monitor the environmental condition of the environment to be detected at different heights, the environmental condition of the environment to be detected is convenient to analyze, and the accuracy of monitoring the environment to be detected is improved.

Description

Environmental monitoring device based on big data

Technical Field

The invention relates to the technical field of environment monitoring, in particular to an environment monitoring device based on big data.

Background

The current method for monitoring the environment generally places an environment monitoring device in the environment to be measured, and then determines the condition of the environment to be measured according to the readings of the environment monitoring device. However, the height of the environment monitoring device in the prior art cannot be adjusted after the environment monitoring device is installed, the height of the environment monitoring device is not convenient to adjust, the atmospheric environments with different heights are not convenient to monitor, and the accuracy of the environment monitoring of the environment to be measured is not accurate enough.

Disclosure of Invention

The invention aims to provide an environment monitoring device based on big data, which can effectively solve the problems in the prior art; the overall height of the invention is convenient to adjust, so that the environmental information acquisition mechanism can monitor the environmental condition of the environment to be detected at different heights, the environmental condition of the environment to be detected is convenient to analyze, and the accuracy of monitoring the environment to be detected is improved.

In order to achieve the purpose, the application provides an environment monitoring device based on big data, which comprises an environment information acquisition mechanism, a vertical frame mechanism, a mounting table, a support leg mechanism and a control mechanism, wherein the environment information acquisition mechanism is connected to the vertical frame mechanism in a matching manner; the vertical frame mechanism is connected to the mounting table in a matching manner; the three support leg mechanisms are uniformly and fixedly connected to the mounting table in a surrounding manner; the mounting table is positioned between the support leg mechanism and the stand mechanism; the middle part of the control mechanism is movably connected to the mounting table; the control mechanism is in transmission connection with the stand mechanism and the three support leg mechanisms.

Optionally, the environmental information collecting mechanism includes a sensor mounting seat, a fixed sensor and a vertical supporting rod; three connecting and installing grooves are uniformly arranged on the sensor installing seat in a surrounding mode, and the inner sides of the three connecting and installing grooves are fixedly connected with a fixed sensor respectively; the middle of the bottom end of the sensor mounting seat is fixedly connected with the top end of the vertical supporting rod; the bottom end of the vertical supporting rod is fixedly connected to the vertical frame mechanism.

Optionally, the environment information collecting mechanism further comprises a movable sensor, an inner sliding plate, an outer sliding plate, an inclined connecting rod, a push-pull ring and an internal threaded pipe; the vertical supporting rod is of a screw rod structure, the internal thread pipe is matched on the vertical supporting rod through threads, and the internal thread pipe is connected in a central through hole of the push-pull ring in a rotating matching manner; the outer side of the push-pull ring is uniformly connected with the lower ends of three oblique connecting rods in a surrounding and rotating manner, the upper ends of the three oblique connecting rods are respectively connected with the inner ends of the inner and outer sliding plates in a rotating manner, and the three inner and outer sliding plates are in sliding fit in the inner and outer slideways of the sensor mounting seat; the outer ends of the three inner and outer sliding plates are respectively fixedly connected with a movable sensor, the movable sensors and the fixed sensors are arranged at intervals.

Optionally, the fixed sensor and the movable sensor are air quality sensors, PM2.5 sensors, or temperature and humidity sensors.

Optionally, the vertical frame mechanism comprises a lifting seat, a vertical screw, a rotating sleeve, a linkage chain wheel and a synchronous chain; the lifting seat is fixedly connected to the upper ends of the two vertical screw rods, the lower ends of the two vertical screw rods are respectively matched with the two rotary sleeves through threads, the lower ends of the two rotary sleeves are relatively and rotatably connected to the two ends of the mounting table in a matched manner, and the lower ends of the two rotary sleeves are respectively and fixedly connected with a linkage chain wheel; the two linkage chain wheels are in transmission connection with the control mechanism through synchronous chains.

Optionally, the lifting seat comprises a fixed transverse plate, a sliding transverse plate, a door-shaped seat plate, a positioning insertion rod, a hand-pulling frame and a reset tension spring; two ends of the fixed transverse plate are fixedly connected with the top ends of the two vertical screw rods; the middle part of the sliding transverse plate is in sliding fit with the rectangular slide way of the fixed transverse plate; the top end of the sliding transverse plate is fixedly connected with the door-shaped seat plate; the lower end of the vertical screw is fixedly connected to the middle of the top surface of the door-shaped seat plate; a rod penetrating hole is formed in the middle of the bottom surface of the fixed transverse plate, and a plurality of positioning insertion holes are formed in the sliding transverse plate; the middle part of the positioning inserted bar is in sliding fit in the bar penetrating hole, the upper end of the positioning inserted bar is inserted in one positioning inserted hole, and the lower end of the positioning inserted bar is fixedly connected with a hand-pulling frame; the hand-pulling frame and the fixed transverse plate are fixedly connected through a plurality of reset tension springs.

Optionally, the control mechanism comprises a movable turntable, a sliding column, a hexagonal prism, a control rotating pipe, a rotating pipe bracket, a driving sprocket, a compression spring, an insertion column, a fixed turntable and a first worm; the movable turntable is fixedly connected to the sliding column; the upper end of the sliding column is fixedly connected with the hexagonal prism; the hexagonal prism is in sliding fit in the hexagonal slideway of the control rotating pipe; the control rotating pipe is rotatably connected to the middle of the rotating pipe bracket; the lower ends of the two rotary sleeves are connected to the two ends of the rotary pipe bracket in a rotating fit manner; the control rotating pipe is fixedly connected with the driving chain wheel; the driving chain wheel is in transmission connection with the two linkage chain wheels through a synchronous chain; the lower end of the sliding column is in sliding fit with the cylindrical sliding groove on the top surface of the first worm, and a compression spring is arranged inside the cylindrical sliding groove; the lower end of the first worm is meshed with the three support leg mechanisms in a transmission mode, the middle of the first worm is connected to the middle of the mounting table in a rotating fit mode, the upper end of the first worm is fixedly connected with the fixed rotary table, a plurality of linkage insertion holes are uniformly formed in the fixed rotary table in a surrounding mode, the lower end of the movable rotary table is uniformly provided with a plurality of insertion columns in a surrounding mode, and the plurality of insertion columns and the plurality of linkage insertion holes are arranged in a vertically opposite mode.

Optionally, the supporting leg mechanism comprises a first worm wheel, a turnover shaft, a bearing seat and a turnover support plate; the first worm is in meshed transmission connection with the first worm wheel; the first worm wheel is fixedly connected to the middle of the turnover shaft; the overturning shaft is rotationally connected to the bearing seat; the bearing seat is fixedly connected to the mounting table; two ends of the turnover shaft are respectively and fixedly connected with one end of one turnover support plate, and the two turnover support plates are oppositely arranged at two ends of the first worm wheel.

Optionally, the supporting leg mechanism further comprises a traveling wheel; and the two ends of the travelling wheels are connected to the other ends of the two overturning support plates in a rotating fit manner.

Optionally, the leg mechanism further comprises an auxiliary bracket; the auxiliary support comprises a second worm, a rod frame, a second worm wheel, a wheel shaft, a roll-over stand, a cross-shaped sliding plate, a tension spring, a sliding screw, an adjusting rotating pipe and a spherical supporting leg; the second worm is rotatably connected to the two rod frames, and the two rod frames are fixedly connected to the inner sides of the two turnover support plates; the second worm is in meshed transmission connection with the second worm wheel; the second worm wheel is fixedly connected to the middle of the wheel shaft; two ends of the wheel shaft are rotatably connected to the two turnover support plates; one end of the roll-over stand is fixedly connected to the wheel shaft; the other end of the roll-over stand is connected with the adjusting rotating pipe in a rotating fit manner; the inner side of the adjusting rotating pipe is connected with the middle of the sliding screw rod in a threaded fit manner; two ends of the sliding screw are respectively fixedly connected with the cross-shaped sliding plate and the spherical support leg; the cross-shaped sliding plate is in sliding fit with the cross-shaped slide way of the roll-over stand; the cross-shaped sliding plate is fixedly connected with the inner side surface of the cross-shaped slide way through a tension spring.

The invention has the beneficial effects that:

the overall height of the invention is convenient to adjust, so that the environmental information acquisition mechanism can monitor the environmental condition of the environment to be detected at different heights, the environmental condition of the environment to be detected is convenient to analyze, and the accuracy of monitoring the environment to be detected is improved; the invention can be adjusted to be in a state convenient for moving, and the support leg mechanism is supported on the ground at the moment, so that the invention is convenient to adjust; the internal support leg mechanism can be buried in the soil, so that the invention is regulated to be in an immovable state, but the stability of the invention in use can be improved.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention or related technologies, the drawings used in the description of the embodiments or related technologies will be briefly introduced below, and it is obvious that the drawings in the following description are some embodiments of the present invention, and other drawings can be obtained by those skilled in the art without creative efforts.

FIG. 1 is a first general schematic diagram provided in accordance with an embodiment of the present invention;

FIG. 2 is a second overall view provided in accordance with an embodiment of the present invention;

fig. 3 is a first schematic diagram of an environment information acquisition mechanism according to an embodiment of the present invention;

fig. 4 is a second schematic diagram of an environmental information acquisition mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic view of a stand mechanism provided in accordance with an embodiment of the present invention;

FIG. 6 is a schematic view of a lifting base according to an embodiment of the present invention;

FIG. 7 is a first schematic view of a leg mechanism provided in an embodiment of the present invention;

FIG. 8 is a second schematic view of a leg mechanism provided in the embodiment of the present invention;

FIG. 9 is a schematic view of an auxiliary stand provided in accordance with an embodiment of the present invention;

FIG. 10 is a schematic view of a control mechanism provided in accordance with an embodiment of the present invention;

fig. 11 is a partial structural sectional view of a control mechanism according to an embodiment of the present invention.

Icon: an environmental information acquisition mechanism 1; a sensor mount 101; a stationary sensor 102; a vertical strut 103; a ambulatory sensor 104; inner and outer slide plates 105; an oblique link 106; a push-pull ring 107; an internally threaded tube 108; a stand mechanism 2; a lifting base 201; a fixed transverse plate 201A; a slide transverse plate 201B; a door-shaped seat plate 201C; a positioning insertion rod 201D; a hand-held frame 201E; a return tension spring 201F; a vertical screw 202; a rotating sleeve 203; a link sprocket 204; a synchronization chain 205; a mounting table 3; a leg mechanism 4; a first worm wheel 401; a tumble shaft 402; a bearing seat 403; turning over the support plate 404; a road wheel 405; an auxiliary support 406; a second worm 406A; a pole frame 406B; a second worm gear 406C; an axle 406D; a roll-over stand 406E; a cross slide 406F; tension spring 406G; a sliding screw 406H; an adjusting rotary pipe 406I; a spherical foot 406J; a control mechanism 5; a movable turntable 501; a sliding post 502; a hexagonal prism 503; a control relay 504; a pipe transfer bracket 505; a drive sprocket 506; a compression spring 507; a plug-in post 508; a fixed turntable 509; a first worm 510.

Detailed Description

In order to make those skilled in the art better understand the technical solutions in the present application, the technical solutions in the embodiments of the present application will be clearly and completely described below, and it is obvious that the described embodiments are only a part of the embodiments of the present application, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It will be understood that when an element is referred to as being "fixed" or "disposed" on another element, it can be directly on the other element or be indirectly disposed on the other element; when an element is referred to as being "connected to" another element, it can be directly connected to the other element or be indirectly connected to the other element.

It will be understood that the terms "length," "width," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like, refer to an orientation or positional relationship illustrated in the drawings for convenience in describing the present application and to simplify description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present application.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of the present application, the meaning of a plurality of or a plurality of is two or more unless specifically limited otherwise.

It should be understood that the structures, ratios, sizes, and the like shown in the drawings and described in the specification are only used for understanding and reading the contents disclosed in the specification, and are not used for limiting the conditions that the present application can implement, so the present invention has no technical significance, and any structural modification, ratio relationship change or size adjustment should still fall within the scope of the technical content disclosed in the present application without affecting the efficacy and the achievable purpose of the present application. In addition, the terms "upper", "lower", "left", "right", "middle" and "one" used in the present specification are for clarity of description, and are not intended to limit the scope of the present application, and changes or modifications in the relative relationship may be made without substantial technical changes.

The invention is described in further detail below with reference to fig. 1-11.

The first embodiment is as follows:

as shown in fig. 1 to 11, the environment monitoring device based on big data includes an environment information collecting mechanism 1, a stand mechanism 2, an installation table 3, a leg mechanism 4 and a control mechanism 5, wherein the environment information collecting mechanism 1 is connected to the stand mechanism 2 in a matching manner; the vertical frame mechanism 2 is connected to the mounting table 3 in a matching manner; the three support leg mechanisms 4 are uniformly and fixedly connected to the mounting table 3 in a surrounding manner; the mounting table 3 is positioned between the support leg mechanism 4 and the stand mechanism 2; the middle part of the control mechanism 5 is movably connected to the mounting table 3; the control mechanism 5 is in transmission connection with the stand mechanism 2 and the three support leg mechanisms 4. The environment monitoring device based on big data is used for detecting the atmospheric environment, a plurality of environment monitoring devices can be arranged at different positions of the same area, so that the atmospheric environment at different positions of the area can be detected; the storage battery pack can be arranged in the solar water heater or the electric supply is adopted for supplying power, so that electric energy is provided for the solar water heater; when the invention is used, the invention can be supported on the ground by adjusting the three support leg mechanisms 4, or the invention can be adjusted to be in an immovable state by burying the three support leg mechanisms 4 into the soil, but the stability of the invention in use can be improved; the overall height of the invention can be adjusted by the control mechanism 5, and the overall length of the vertical frame mechanism 2 can be adjusted by the control mechanism 5, so that the vertical frame mechanism 2 drives the height of the environmental information acquisition mechanism 1 to change, the position of the environmental information acquisition mechanism 1 is adjusted, the environmental condition of the environment to be detected is monitored by the environmental information acquisition mechanism 1 at different heights, the environmental condition of the environment to be detected is conveniently analyzed, and the accuracy of monitoring the environment to be detected is improved.

The second embodiment is as follows:

as shown in fig. 1 to 11, the environmental information collecting mechanism 1 includes a sensor mounting seat 101, a fixed sensor 102, and a vertical strut 103; three connecting and installing grooves are uniformly arranged on the sensor installing seat 101 in a surrounding mode, and the inner sides of the three connecting and installing grooves are fixedly connected with a fixed sensor 102 respectively; the middle of the bottom end of the sensor mounting seat 101 is fixedly connected with the top end of the vertical supporting rod 103; the bottom end of the vertical supporting rod 103 is fixedly connected to the vertical frame mechanism 2.

The environment information acquisition mechanism 1 further comprises a movable sensor 104, an inner sliding plate 105, an outer sliding plate 105, an inclined connecting rod 106, a push-pull ring 107 and an internal threaded pipe 108; the vertical supporting rod 103 is of a screw rod structure, the internal threaded pipe 108 is matched with the vertical supporting rod 103 through threads, and the internal threaded pipe 108 is connected in a center through hole of the push-pull ring 107 in a rotating matching manner; the outer side of the push-pull ring 107 is uniformly connected with the lower ends of three inclined connecting rods 106 in a surrounding manner, the upper ends of the three inclined connecting rods 106 are respectively connected with the inner ends of the inner and outer sliding plates 105 in a rotating manner, and the three inner and outer sliding plates 105 are in sliding fit in the inner and outer slideways of the sensor mounting seat 101; the outer ends of the three inner and outer sliding plates 105 are respectively fixedly connected with a movable sensor 104, and the three movable sensors 104 and the three fixed sensors 102 are arranged at intervals.

The fixed sensor 102 and the movable sensor 104 are air quality sensors or PM2.5 sensors or temperature and humidity sensors.

When the environmental information acquisition mechanism 1 is used, atmospheric environment can be detected by three fixed sensors 102 in a conventional state, when detection precision needs to be improved or three fixed sensors 102 have problems, three movable sensors 104 can be controlled to extend out of the outer end of a sensor mounting seat 101, atmospheric environment monitoring is carried out by matching the three movable sensors 104 with the three fixed sensors 102, when three movable sensors 104 are controlled to extend out of the outer end of the sensor mounting seat 101, the contact position of the internal threaded pipe 108 and the vertical supporting rod 103 is changed by rotating the internal threaded pipe 108, so that the push-pull ring 107 is driven to move up and down, the push-pull ring 107 drives three inner and outer sliding plates 105 to slide inside and outside the inner and outer slideways of the sensor mounting seat 101 through three inclined connecting rods 106, and the three movable sensors 104 are driven to extend out of the sensor mounting seat through the three inner and outer sliding plates 105 101, the sensor mounting seat 101 can play a protective role to a certain extent, and the three movable sensors 104 are protected when not used.

The third concrete implementation mode:

as shown in fig. 1-11, the stand mechanism 2 includes a lifting seat 201, a vertical screw 202, a rotary sleeve 203, a link sprocket 204 and a synchronous chain 205; the lifting seat 201 is fixedly connected to the upper ends of the two vertical screws 202, the lower ends of the two vertical screws 202 are respectively matched with the two rotating sleeves 203 through threads, the lower ends of the two rotating sleeves 203 are connected to the two ends of the mounting table 3 in a relatively rotating and matching manner, and the lower ends of the two rotating sleeves 203 are respectively fixedly connected with a linkage chain wheel 204; the two linkage sprockets 204 and the control mechanism 5 are in transmission connection through a synchronous chain 205. When the vertical frame mechanism 2 is used, the control mechanism 5 drives two linkage sprockets 204 to rotate through the transmission of the synchronous chain 205, the linkage sprockets 204 can drive the two rotary sleeves 203 to rotate around the axes of the two rotary sleeves 203 when rotating, the two rotary sleeves 203 can drive the two vertical screws 202 to move up and down when rotating, and the two vertical screws 202 drive the lifting seat 201 to be adjusted in height, so that the height of the environment information acquisition mechanism 1 is appropriately adjusted.

The fourth concrete implementation mode:

as shown in fig. 1 to 11, the lifting seat 201 includes a fixed transverse plate 201A, a sliding transverse plate 201B, a door-shaped seat plate 201C, a positioning insertion rod 201D, a hand-pulling frame 201E and a return tension spring 201F; two ends of the fixed transverse plate 201A are fixedly connected with the top ends of the two vertical screw rods 202; the middle part of the sliding transverse plate 201B is in sliding fit with the rectangular slide way of the fixed transverse plate 201A; the top end of the sliding transverse plate 201B is fixedly connected with a door-shaped seat plate 201C; the lower end of the vertical screw 202 is fixedly connected to the middle of the top surface of the door-shaped seat plate 201C; a rod penetrating hole is formed in the middle of the bottom surface of the fixed transverse plate 201A, and a plurality of positioning insertion holes are formed in the sliding transverse plate 201B; the middle part of the positioning inserted rod 201D is in sliding fit in the rod penetrating hole, the upper end of the positioning inserted rod 201D is inserted in one positioning inserted hole, and the lower end of the positioning inserted rod 201D is fixedly connected with a hand-pulling frame 201E; the hand-pulling frame 201E is fixedly connected with the fixed transverse plate 201A through a plurality of reset tension springs 201F. When the lifting seat 201 is used, the positioning insertion rod 201D is kept in a state of being tightly inserted into the positioning insertion hole of the sliding transverse plate 201B under the elastic force action of the reset tension spring 201F in a conventional state, the hand-pulling frame 201E is pulled downwards to drive the positioning insertion rod 201D to move downwards, the positioning insertion rod 201D moves downwards to release the locking of the sliding transverse plate 201B, and at the moment, the position of the positioning insertion rod 201D on the fixed transverse plate 201A can be adjusted by sliding the sliding transverse plate 201B, so that the position of the door-shaped seat plate 201C is driven to be adjusted, the position of the environment information acquisition mechanism 1 is changed, the position of the environment information acquisition mechanism 1 is conveniently subjected to fine adjustment after the integral installation of the lifting seat 201, and the monitoring effect is better.

The fifth concrete implementation mode:

as shown in fig. 1-11, the control mechanism 5 comprises a movable turntable 501, a sliding column 502, a hexagonal prism 503, a control rotating pipe 504, a rotating pipe bracket 505, a driving sprocket 506, a compression spring 507, a plug column 508, a fixed turntable 509 and a first worm 510; the movable turntable 501 is fixedly connected to the sliding column 502; the upper end of the sliding column 502 is fixedly connected with the hexagonal prism 503; the hexagonal prism 503 is slidably fitted in the hexagonal slideway of the control rotating pipe 504; the control rotating pipe 504 is rotatably connected to the middle of the rotating pipe bracket 505; the lower ends of the two rotary sleeves 203 are connected with the two ends of the rotary pipe bracket 505 in a rotating fit manner; the control rotating pipe 504 is fixedly connected with the driving chain wheel 506; the driving sprocket 506 is in transmission connection with the two linkage sprockets 204 through a synchronous chain 205; the lower end of the sliding column 502 is in sliding fit with a cylindrical sliding groove on the top surface of the first worm 510, and a compression spring 507 is arranged inside the cylindrical sliding groove; the lower end of the first worm 510 is in meshing transmission connection with the three support leg mechanisms 4, the middle of the first worm 510 is connected to the middle of the mounting table 3 in a rotating fit mode, the upper end of the first worm 510 is fixedly connected with the fixed turntable 509, a plurality of linkage jacks are uniformly arranged on the fixed turntable 509 in a surrounding mode, the lower end of the movable turntable 501 is uniformly provided with a plurality of inserting columns 508 in a surrounding mode, and the inserting columns 508 and the linkage jacks are arranged in a vertically opposite mode. When the control mechanism 5 is used, the plurality of inserting columns 508 and the plurality of linkage inserting holes are in a separated state in a conventional state, at this time, the sliding column 502 is driven to rotate when the movable turntable 501 is rotated, the sliding column 502 drives the control rotating pipe 504 to rotate through the hexagonal prism 503, the drive sprocket 506 is driven to rotate when the control rotating pipe 504 rotates, and the drive sprocket 506 drives the two linkage sprockets 204 to rotate through chain transmission when rotating, so that the whole stand mechanism 2 is driven to be lifted or lowered; when the movable turntable 501 is pressed downwards, the movable turntable 501 can drive the sliding column 502 to move downwards and compress the compression spring 507, when the plurality of inserting columns 508 and the plurality of linkage inserting holes are in an inserting state, the movable turntable 501 can be rotated to drive the fixed turntable 509 to rotate through the inserting columns 508, the fixed turntable 509 can be driven to rotate when rotating, and the first worm 510 can drive the three support leg mechanisms 4 to expand outwards or contract inwards when rotating; the three support leg mechanisms 4 are driven to expand outwards when the movable rotary disc 501 is rotated to control the integral rising of the stand mechanism 2, so that the stability of the invention is improved, and conversely, the three support leg mechanisms 4 are driven to contract inwards when the integral lowering of the stand mechanism 2 is controlled, so that the occupied area of the invention is reduced, and the movement is facilitated; in addition, the fixed rotating disc 509 can be independently rotated to control the three leg mechanisms 4 to turn over or contract, so that the three leg mechanisms are convenient to use when the overall height of the stand mechanism 2 is not required to be adjusted; the three support leg mechanisms 4 can be controlled to turn 90 degrees, so that the support leg mechanisms are conveniently buried in the soil, and the stability of the invention is improved.

The sixth specific implementation mode:

as shown in fig. 1 to 11, the leg mechanism 4 includes a first worm gear 401, a turnover shaft 402, a bearing seat 403 and a turnover support plate 404; the first worm 510 is in meshing transmission connection with the first worm wheel 401; the first worm wheel 401 is fixedly connected to the middle of the turning shaft 402; the turning shaft 402 is rotatably connected to the bearing seat 403; the bearing seat 403 is fixedly connected to the mounting table 3; two ends of the turning shaft 402 are respectively and fixedly connected with one end of one turning support plate 404, and the two turning support plates 404 are oppositely arranged at two ends of the first worm wheel 401. The first worm wheel 401 in the leg mechanism 4 can be driven by the first worm 510 to rotate, the first worm wheel 401 can drive the turning shaft 402 to rotate when rotating, and the turning shaft 402 can drive the turning support plate 404 to turn outwards or shrink inwards when rotating, when the invention is carried and moved, the invention can be in a shrinking state, so that the volume of the invention is reduced, when the invention is supported on the ground, the invention can be adjusted to be in a state of turning to the outer end, so that the supporting effect of the invention is improved; the first worm wheel 401 and the first worm 510 are structurally arranged, so that locking is achieved after adjustment, and structural stability is good.

The leg mechanism 4 further comprises a road wheel 405; two ends of the travelling wheel 405 are connected to the other ends of the two turnover support plates 404 in a rotating fit mode. The arrangement of the walking wheels 405 makes the invention more convenient to move and also facilitates the outward unfolding of the three leg mechanisms 4.

The leg mechanism 4 further comprises an auxiliary bracket 406; the auxiliary bracket 406 comprises a second worm 406A, a rod frame 406B, a second worm gear 406C, a wheel shaft 406D, a roll-over frame 406E, a cross-shaped sliding plate 406F, a tension spring 406G, a sliding screw 406H, an adjusting rotary pipe 406I and a spherical support leg 406J; the second worm 406A is rotatably connected to the two bar frames 406B, and the two bar frames 406B are fixedly connected to the inner sides of the two turnover support plates 404; the second worm 406A is in meshing transmission connection with the second worm gear 406C; the second worm gear 406C is fixedly connected to the middle of the wheel shaft 406D; two ends of the wheel shaft 406D are rotatably connected to the two turnover support plates 404; one end of the roll-over stand 406E is fixedly connected to the wheel shaft 406D; the other end of the turning frame 406E is connected with the adjusting rotating pipe 406I in a rotating fit manner; the inner side of the adjusting rotary pipe 406I is connected with the middle of the sliding screw rod 406H in a threaded fit manner; two ends of the sliding screw 406H are respectively fixedly connected with the cross-shaped sliding plate 406F and the spherical supporting foot 406J; the cross-shaped sliding plate 406F is in sliding fit in the cross-shaped slide way of the roll-over stand 406E; the cross-shaped sliding plate 406F is fixedly connected with the inner side surface of the cross-shaped slideway through a tension spring 406G. The auxiliary bracket 406 can enhance the supporting effect of the supporting leg mechanism 4 after being unfolded, the second worm 406A can be driven to rotate by rotating the second worm 406A, the wheel shaft 406D can be driven to rotate when the second worm wheel 406C rotates, the wheel shaft 406D can rotate to turn out the roll-over stand 406E retracted inside the roll-over support 404 inwards so that the spherical supporting leg 406J at the lower end thereof is supported on the ground, when the spherical supporting leg 406J cannot be in contact with the ground or the ground is uneven, the height of the spherical supporting leg 406J can be adjusted by rotating the adjusting rotating tube 406I so that the spherical supporting leg 406J is stably supported on the ground, the contact position of the adjusting rotating tube 406I and the sliding screw 406H can be changed by rotating the adjusting rotating tube 406I, so that the sliding screw 406H drives the cross-shaped sliding plate 406F to slide in the cross-shaped slide way of the roll-over stand 406E, and finally the position of the, the tension spring 406G plays a role in tension limiting, and the stability of the spherical support 406J after position adjustment is improved.

The principle is as follows: the environment monitoring device based on big data is used for detecting the atmospheric environment, a plurality of environment monitoring devices can be arranged at different positions of the same area, so that the atmospheric environment at different positions of the area can be detected; the storage battery pack can be arranged in the solar water heater or the electric supply is adopted for supplying power, so that electric energy is provided for the solar water heater; when the invention is used, the invention can be supported on the ground by adjusting the three support leg mechanisms 4, or the invention can be adjusted to be in an immovable state by burying the three support leg mechanisms 4 into the soil, but the stability of the invention in use can be improved; the overall height of the invention can be adjusted by the control mechanism 5, and the overall length of the vertical frame mechanism 2 can be adjusted by the control mechanism 5, so that the vertical frame mechanism 2 drives the height of the environmental information acquisition mechanism 1 to change, the position of the environmental information acquisition mechanism 1 is adjusted, the environmental condition of the environment to be detected is monitored by the environmental information acquisition mechanism 1 at different heights, the environmental condition of the environment to be detected is conveniently analyzed, and the accuracy of monitoring the environment to be detected is improved.

The embodiments are described in a progressive manner in the specification, each embodiment focuses on differences from other embodiments, and the same and similar parts among the embodiments are referred to each other. It should be noted that, for those skilled in the art, it is possible to make several improvements and modifications to the present application without departing from the principle of the present application, and such improvements and modifications also fall within the scope of the claims of the present application.

It is further noted that, in the present specification, relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus. Without further limitation, an element defined by the phrase "comprising an … …" does not exclude the presence of other identical elements in a process, method, article, or apparatus that comprises the element.

Claims

1. Environmental monitoring device based on big data, including environmental information acquisition mechanism (1), grudging post mechanism (2), mount table (3), stabilizer blade mechanism (4) and control mechanism (5), its characterized in that: the environment information acquisition mechanism (1) is connected to the vertical frame mechanism (2) in a matching manner; the vertical frame mechanism (2) is connected to the mounting table (3) in a matching manner; the three support leg mechanisms (4) are uniformly and fixedly connected to the mounting table (3) in a surrounding manner; the mounting table (3) is positioned between the support leg mechanism (4) and the stand mechanism (2); the middle part of the control mechanism (5) is movably connected to the mounting table (3); the control mechanism (5) is in transmission connection with the stand mechanism (2) and the three support leg mechanisms (4).

2. The big-data based environmental monitoring apparatus of claim 1, wherein: the environment information acquisition mechanism (1) comprises a sensor mounting seat (101), a fixed sensor (102) and a vertical supporting rod (103); three connecting and installing grooves are uniformly arranged on the sensor installing seat (101) in a surrounding mode, and the inner sides of the three connecting and installing grooves are fixedly connected with a fixed sensor (102) respectively; the middle of the bottom end of the sensor mounting seat (101) is fixedly connected with the top end of the vertical supporting rod (103); the bottom end of the vertical supporting rod (103) is fixedly connected to the vertical frame mechanism (2).

3. The big-data based environmental monitoring apparatus of claim 2, wherein: the environment information acquisition mechanism (1) further comprises a movable sensor (104), an inner sliding plate, an outer sliding plate (105), an inclined connecting rod (106), a push-pull ring (107) and an internal threaded pipe (108); the vertical supporting rod (103) is of a screw rod structure, the internal threaded pipe (108) is matched with the vertical supporting rod (103) through threads, and the internal threaded pipe (108) is connected in a central through hole of the push-pull ring (107) in a rotating matching manner; the outer side of the push-pull ring (107) is uniformly connected with the lower ends of three inclined connecting rods (106) in a surrounding and rotating manner, the upper ends of the three inclined connecting rods (106) are respectively connected with the inner ends of the inner and outer sliding plates (105) in a rotating manner, and the three inner and outer sliding plates (105) are in sliding fit in inner and outer slideways of the sensor mounting seat (101); the outer ends of the three inner and outer sliding plates (105) are respectively fixedly connected with a movable sensor (104), and the three movable sensors (104) and the three fixed sensors (102) are arranged at intervals.

4. The big-data based environmental monitoring apparatus of claim 3, wherein: the fixed sensor (102) and the movable sensor (104) are air quality sensors or PM2.5 sensors or temperature and humidity sensors.

5. The big-data based environmental monitoring apparatus of claim 1, wherein: the vertical frame mechanism (2) comprises a lifting seat (201), a vertical screw (202), a rotating sleeve (203), a linkage chain wheel (204) and a synchronous chain (205); the lifting seat (201) is fixedly connected to the upper ends of the two vertical screws (202), the lower ends of the two vertical screws (202) are respectively matched with the two rotating sleeves (203) through threads, the lower ends of the two rotating sleeves (203) are correspondingly and rotatably connected to the two ends of the mounting table (3), and the lower ends of the two rotating sleeves (203) are respectively and fixedly connected with a linkage chain wheel (204); the two linkage chain wheels (204) are in transmission connection with the control mechanism (5) through a synchronous chain (205).

6. The big-data based environmental monitoring apparatus of claim 5, wherein: the lifting seat (201) comprises a fixed transverse plate (201A), a sliding transverse plate (201B), a door-shaped seat plate (201C), a positioning inserted bar (201D), a hand-pulling frame (201E) and a reset tension spring (201F); two ends of the fixed transverse plate (201A) are fixedly connected with the top ends of the two vertical screw rods (202); the middle part of the sliding transverse plate (201B) is in sliding fit with the rectangular slide way of the fixed transverse plate (201A); the top end of the sliding transverse plate (201B) is fixedly connected with a door-shaped seat plate (201C); the lower end of the vertical screw rod (202) is fixedly connected to the middle of the top surface of the door-shaped seat plate (201C); a rod penetrating hole is formed in the middle of the bottom surface of the fixed transverse plate (201A), and a plurality of positioning insertion holes are formed in the sliding transverse plate (201B); the middle part of the positioning inserted rod (201D) is in sliding fit with the rod penetrating hole, the upper end of the positioning inserted rod (201D) is inserted into one positioning inserted hole, and the lower end of the positioning inserted rod (201D) is fixedly connected with a hand-pulling frame (201E); the hand-pulling frame (201E) is fixedly connected with the fixed transverse plate (201A) through a plurality of reset tension springs (201F).

7. The big-data based environmental monitoring apparatus of claim 6, wherein: the control mechanism (5) comprises a movable turntable (501), a sliding column (502), a hexagonal prism (503), a control rotating pipe (504), a rotating pipe bracket (505), a driving chain wheel (506), a compression spring (507), an insertion column (508), a fixed turntable (509) and a first worm (510); the movable turntable (501) is fixedly connected to the sliding column (502); the upper end of the sliding column (502) is fixedly connected with the hexagonal prism (503); the hexagonal prism (503) is in sliding fit in a hexagonal slideway of the control rotating pipe (504); the control rotating pipe (504) is rotatably connected to the middle of the rotating pipe bracket (505); the lower ends of the two rotary sleeves (203) are connected to the two ends of the rotary pipe bracket (505) in a rotating fit manner; the control rotating pipe (504) is fixedly connected with the driving chain wheel (506); the driving chain wheel (506) is in transmission connection with the two linkage chain wheels (204) through a synchronous chain (205); the lower end of the sliding column (502) is in sliding fit with a cylindrical sliding groove on the top surface of the first worm (510), and a compression spring (507) is arranged inside the cylindrical sliding groove; the lower extreme meshing transmission of first worm (510) is connected threely stabilizer blade mechanism (4), and the middle part normal running fit of first worm (510) is connected the centre of mount table (3), the upper end fixed connection of first worm (510) fixed turntable (509), fixed turntable (509) go up evenly to encircle and set up a plurality of linkage jacks, the lower extreme of activity carousel (501) evenly encircles and sets up a plurality of grafting posts (508), and a plurality of grafting posts (508) set up with a plurality of linkage jacks relative from top to bottom.

8. The big-data based environmental monitoring apparatus of claim 7, wherein: the supporting leg mechanism (4) comprises a first worm wheel (401), a turnover shaft (402), a bearing seat (403) and a turnover support plate (404); the first worm (510) is in meshed transmission connection with the first worm wheel (401); the first worm wheel (401) is fixedly connected to the middle of the overturning shaft (402); the overturning shaft (402) is rotationally connected to the bearing seat (403); the bearing seat (403) is fixedly connected to the mounting table (3); two ends of the overturning shaft (402) are respectively and fixedly connected with one end of one overturning support plate (404), and the two overturning support plates (404) are oppositely arranged at two ends of the first worm wheel (401).

9. The big-data based environmental monitoring apparatus of claim 8, wherein: the support leg mechanism (4) further comprises a travelling wheel (405); and two ends of the travelling wheels (405) are connected to the other ends of the two overturning support plates (404) in a rotating fit manner.

10. The big-data based environmental monitoring apparatus of claim 9, wherein: the foot mechanism (4) further comprises an auxiliary bracket (406); the auxiliary bracket (406) comprises a second worm (406A), a rod frame (406B), a second worm gear (406C), a wheel shaft (406D), a roll-over frame (406E), a cross-shaped sliding plate (406F), a tension spring (406G), a sliding screw (406H), an adjusting rotary pipe (406I) and a spherical supporting leg (406J); the second worm (406A) is rotatably connected to the two rod frames (406B), and the two rod frames (406B) are fixedly connected to the inner sides of the two turnover support plates (404); the second worm (406A) is in meshed transmission connection with the second worm wheel (406C); the second worm gear (406C) is fixedly connected to the middle of the wheel shaft (406D); two ends of the wheel shaft (406D) are rotatably connected to the two turnover support plates (404); one end of the roll-over stand (406E) is fixedly connected to the wheel shaft (406D); the other end of the roll-over stand (406E) is connected with the adjusting rotating pipe (406I) in a rotating fit manner; the inner side of the adjusting rotating pipe (406I) is connected with the middle of the sliding screw rod (406H) through thread fit; two ends of the sliding screw rod (406H) are respectively and fixedly connected with the cross-shaped sliding plate (406F) and the spherical supporting foot (406J); the cross-shaped sliding plate (406F) is in sliding fit with the cross-shaped slide way of the roll-over stand (406E); the cross-shaped sliding plate (406F) is fixedly connected with the inner side surface of the cross-shaped slide way through a tension spring (406G).