CN215641163U - Intelligent environment monitoring system based on Internet of things - Google Patents

Abstract

The utility model discloses an intelligent environment monitoring system based on the Internet of things, which comprises a monitoring protective shell, a shielding cover, a detection assembly, a bottom plate and a lifting assembly, wherein the shielding cover is installed on the top end face of the monitoring protective shell through welding, the detection assembly is arranged inside the monitoring protective shell, the lifting assembly is arranged on the bottom end face of the monitoring protective shell, the bottom of the lifting assembly is provided with the bottom plate, and the detection assembly comprises a U-shaped gas pumping shell. The cost of environmental monitoring is reduced.

Description

Intelligent environment monitoring system based on Internet of things

Technical Field

The utility model relates to the technical field of environment monitoring, in particular to an intelligent environment monitoring system based on the Internet of things.

Background

The environmental monitoring is an important basis of environmental protection and management work, the pollution source and the environmental quality are continuously and effectively monitored for a long time by applying a new communication network technology through the application of an informatization technology, the environmental conditions of the governed area are scientifically, accurately, comprehensively and efficiently monitored and managed, in the environment monitoring work, the intelligent environment monitoring system is used for monitoring operation, the existing intelligent environment monitoring system needs to replace gas samples around the sensor by blowing of natural wind, the sensitivity of monitoring the outside gas is low, the requirement of real-time and efficient monitoring around the monitoring system cannot be met, the monitoring effect is poor, meanwhile, the existing intelligent environment monitoring system cannot meet the requirement of real-time monitoring of gases with multiple heights, and a plurality of monitoring systems need to be installed, so that the environment monitoring cost is greatly improved, and therefore, the design of the intelligent environment monitoring system based on the Internet of things is necessary.

SUMMERY OF THE UTILITY MODEL

The utility model solves the problem of providing an intelligent environment monitoring system based on the Internet of things, which has reasonable structural design and strong applicability, can detect the environmental gas in real time and replace the detection sample in real time when in use, improves the monitoring sensitivity, enhances the monitoring effect, can freely adjust the monitoring height, meets the requirement of monitoring the gas environments with multiple heights in real time, and reduces the cost of environment monitoring.

In order to achieve the purpose, the utility model adopts the following technical scheme:

an intelligent environment monitoring system based on the Internet of things comprises a monitoring protective shell, a shielding cover, a detection assembly, a bottom plate and a lifting assembly, wherein the shielding cover is installed on the top end face of the monitoring protective shell through welding, the detection assembly is arranged inside the monitoring protective shell, the lifting assembly is arranged on the bottom end face of the monitoring protective shell, and the bottom plate is arranged at the bottom of the lifting assembly;

the detection assembly comprises a U-shaped air pumping shell, a rectangular air inlet cylinder, an air inlet, a guide box, an arc-shaped motor shell, a positioning groove, a sensor bin, a central fluted disc, a transmission gear, an air pumping impeller and a rotating motor, wherein the central fluted disc is installed in the center of the inner wall at the top of the monitoring protective shell in a welding manner, the sensor bin is arranged in the center of the inner wall at the bottom of the monitoring protective shell, the guide box is installed on the end surface at the bottom of the monitoring protective shell in a welding manner, the arc-shaped motor shell is installed inside the guide box in a laminating manner, the rotating motor is installed on the inner wall at one side of the arc-shaped motor shell through a bolt, the air pumping impeller is installed at one end of the top of the rotating motor through a coupling, the U-shaped air pumping shell is installed in the middle of the end surface at the top of the arc-shaped motor shell in a welding manner, the rectangular air inlet cylinder is inserted into the outer side of the U-shaped air pumping shell, and the transmission gear is installed at one end of the top of the air pumping impeller in a welding manner, and the transmission gear is meshed and connected with the central fluted disc.

As a further scheme of the utility model: the lifting assembly comprises a fixed top plate, a connecting rod, a hydraulic cylinder and a hydraulic piston, the hydraulic cylinder is installed in the center of the top end face of the bottom plate through welding, the connecting rod is inserted in the center of the top end face of the hydraulic cylinder, the fixed top plate is installed at one end of the top of the connecting rod through welding, the fixed top plate is fixedly connected with the bottom end face of the monitoring protective shell through a bolt, the hydraulic piston is installed at one end of the bottom of the connecting rod through welding, and the outer wall of the hydraulic piston is attached to the inner wall of the hydraulic cylinder.

As a further scheme of the utility model: a plurality of first reinforcing rib plates are arranged between the bottom of the outer wall of the hydraulic cylinder and the bottom plate in a welding mode, and a plurality of second reinforcing rib plates are arranged between the top of the outer wall of the connecting rod and the fixed top plate in a welding mode.

As a further scheme of the utility model: two location strips are installed through the welding to the outer wall of arc motor casing, two constant head tanks have been seted up to the inner wall of direction box, and the outer wall of location strip and the inner wall laminating of constant head tank.

As a further scheme of the utility model: a plurality of air inlets are formed in the periphery of the outer wall of the monitoring protective shell, and the end face of the outer side of the rectangular air inlet cylinder is attached to the inner wall of the monitoring protective shell.

As a further scheme of the utility model: the limiting block is installed in the center of the top end face of the transmission gear through welding, the limiting groove is formed in the inner wall of the top of the monitoring protective shell, and the outer wall of the limiting block is attached to the inner wall of the limiting groove.

The utility model has the beneficial effects that: this intelligent environmental monitoring system based on thing networking, structural design is reasonable, the suitability is strong, when using, can carry out real-time detection to ambient gas through determine module, constantly carry the monitored control system gas all around the sensor, carry out real-time replacement to the testing sample, the monitoring sensitivity has been improved, the monitoring effect has been strengthened, simultaneously, can freely adjust the control height through lifting unit, satisfied the requirement of carrying out real time monitoring to the gaseous environment of a plurality of heights, the cost of environmental monitoring has been reduced.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of a first internal mechanism of the detecting assembly of the present invention;

FIG. 3 is a schematic view of a second internal mechanism of the detecting assembly of the present invention;

FIG. 4 is a schematic view of a third internal mechanism of the detecting assembly of the present invention;

FIG. 5 is a schematic view of the internal structure of the lift assembly of the present invention;

illustration of the drawings: 1. monitoring the protective shell; 2. a shielding cover; 3. a detection component; 4. a base plate; 5. a lifting assembly; 31. a U-shaped air exhaust shell; 32. a rectangular air inlet cylinder; 33. an air inlet; 34. a guide box; 35. an arc-shaped motor casing; 36. positioning a groove; 37. a sensor bin; 38. a central fluted disc; 39. a transmission gear; 310. an air exhaust impeller; 311. a rotating electric machine; 51. fixing a top plate; 52. a connecting rod; 53. a hydraulic cylinder; 54. a hydraulic piston.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the 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 invention.

Example (b):

as shown in fig. 1-4, an intelligent environment monitoring system based on the internet of things comprises a monitoring protective shell 1, a shielding cover 2, a detection assembly 3, a bottom plate 4 and a lifting assembly 5, wherein the shielding cover 2 is installed on the top end surface of the monitoring protective shell 1 through welding, the detection assembly 3 is arranged inside the monitoring protective shell 1, the lifting assembly 5 is arranged on the bottom end surface of the monitoring protective shell 1, and the bottom plate 4 is arranged at the bottom of the lifting assembly 5;

the detection component 3 comprises a U-shaped air suction shell 31, a rectangular air inlet cylinder 32, an air inlet 33, a guide box 34, an arc-shaped motor shell 35, a positioning groove 36, a sensor bin 37, a central fluted disc 38, a transmission gear 39, an air suction impeller 310 and a rotating motor 311, wherein the central fluted disc 38 is installed in the center of the inner wall of the top of the monitoring protective shell 1 through welding, the sensor bin 37 is arranged in the center of the inner wall of the bottom of the monitoring protective shell 1, the guide box 34 is installed on the end face of the bottom of the monitoring protective shell 1 through welding, the arc-shaped motor shell 35 is installed inside the guide box 34 in an attached mode, the rotating motor 311 is installed on the inner wall of one side of the arc-shaped motor shell 35 through bolts, the air suction impeller 310 is installed on one end of the top of the rotating motor 311 through a coupler, the U-shaped air suction shell 31 is installed in the middle of the end face of the top of the arc-shaped motor shell 35 through welding, and the rectangular air inlet cylinder 32 is inserted and connected to the outer side of the U-shaped air suction shell 31, one end of the top of the air exhaust impeller 310 is provided with a transmission gear 39 through welding, the transmission gear 39 is meshed with the central fluted disc 38, during operation, the rotating motor 311 is started to drive the air exhaust impeller 310 to rotate anticlockwise, so that external air gradually passes through the air inlet 33, the rectangular air inlet cylinder 32 and the U-shaped air exhaust shell 31 enter the monitoring protective shell 1, the air is continuously conveyed to the periphery of the sensor bin 37 to replace a detection sample in real time, when the air exhaust impeller 310 rotates, the transmission gear 39 is driven to rotate in a meshed mode on the outer side of the central fluted disc 38, the arc-shaped motor shell 35 slides slowly in the guide box 34, the rectangular air inlet cylinder 32 is enabled to rotate in a joint mode on the inner wall of the monitoring protective shell 1, the air around the outside of the monitoring protective shell 1 is continuously pumped into the monitoring protective shell 1, and the effect of replacing the detection sample in real time is achieved;

two positioning strips are welded on the outer wall of the arc-shaped motor shell 35, two positioning grooves 36 are formed in the inner wall of the guide box 34, the outer walls of the positioning strips are attached to the inner walls of the positioning grooves 36, and when the arc-shaped motor shell 35 slides in the guide box 34 in working, the positioning strips are attached to the inner walls of the positioning grooves 36 to slide, so that the movement of the arc-shaped motor shell 35 is limited, and the operation stability is improved;

a plurality of air inlets 33 are formed in the periphery of the outer wall of the monitoring protective shell 1, the end face of the outer side of the rectangular air inlet cylinder 32 is attached to the inner wall of the monitoring protective shell 1, and when the monitoring protective shell works, external air enters the monitoring protective shell 1 through the air inlets 33 and the rectangular air inlet cylinder 32;

the stopper is installed through the welding in drive gear 39's top end face central authorities, and the spacing groove has been seted up to the top inner wall of monitoring protective housing 1, and the outer wall of stopper and the inner wall laminating of spacing groove, and the during operation, the stopper slides at the inner wall laminating of spacing groove, has reached and has assisted spacing effect to U type shell 31 of bleeding.

The working principle is as follows: when the device is used, the environmental gas can be detected in real time through the detection assembly 3, the rotating motor 311 is started to drive the air suction impeller 310 to rotate anticlockwise, so that the external gas gradually enters the monitoring protective shell 1 through the air inlet 33, the rectangular air inlet cylinder 32 and the U-shaped air suction shell 31, the gas is continuously conveyed to the periphery of the sensor bin 37 to replace a detection sample in real time, when the air suction impeller 310 rotates, the transmission gear 39 is driven to rotate in a meshing manner outside the central fluted disc 38, the arc-shaped motor shell 35 slowly slides in the guide box 34, the positioning strip is attached to and slides on the inner wall of the positioning groove 36 to limit the movement of the arc-shaped motor shell 35, the limit block at the top of the transmission gear 39 is attached to and slides on the inner wall of the limit groove, the effect of assisting in limiting the movement of the U-shaped air suction shell 31 is achieved, and the rectangular air inlet cylinder 32 is attached to and rotates on the inner wall of the monitoring protective shell 1, constantly will monitor inside the outside gas suction all around of protective housing 1 monitors protective housing 1, improved the control sensitivity, strengthened the monitoring effect.

As shown in fig. 5, the lifting assembly 5 includes a fixed top plate 51, a connecting rod 52, a hydraulic cylinder 53 and a hydraulic piston 54, the hydraulic cylinder 53 is installed at the center of the top end surface of the bottom plate 4 by welding, and the center of the top end surface of the hydraulic cylinder 53 is inserted with a connecting rod 52, one end of the top of the connecting rod 52 is provided with a fixed top plate 51 by welding, and the fixed top plate 51 is fixedly connected with the bottom end face of the monitoring protective shell 1 through a bolt, one end of the bottom of the connecting rod 52 is provided with a hydraulic piston 54 through welding, the outer wall of the hydraulic piston 54 is attached to the inner wall of the hydraulic cylinder 53, when the hydraulic cylinder works, the liquid level of hydraulic oil in the hydraulic cylinder 53 slowly rises, hydraulic energy is converted into mechanical energy, the hydraulic piston 54 and the connecting rod 52 are pushed to move upwards, the fixed top plate 51 and the fixed top plate 51 are driven to move upwards, and the requirement of monitoring gas environments with multiple heights in real time is met; a plurality of first reinforcing rib plates are arranged between the bottom of the outer wall of the hydraulic cylinder 53 and the bottom plate 4 through welding, a plurality of second reinforcing rib plates are arranged between the top of the outer wall of the connecting rod 52 and the fixed top plate 51 through welding, and the effect of improving the structural stability is achieved through the first reinforcing rib plates and the second reinforcing rib plates.

The working principle is as follows: can freely adjust the control height through lifting unit 5, the effect that has improved structural stability has been reached through first reinforcement floor and second reinforcement floor, the liquid level of the inside hydraulic oil of hydraulic cylinder 53 slowly rises, change hydraulic energy into mechanical energy, promote hydraulic piston 54 and connecting rod 52 rebound, drive fixed roof 51 and fixed roof 51 rebound, the requirement of carrying out real time monitoring to the gaseous environment of a plurality of heights has been satisfied, the cost of environmental monitoring has been reduced.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered to be within the technical scope of the present invention, and equivalent alternatives or modifications according to the technical solution of the present invention and the inventive concept thereof should be covered by the scope of the present invention.

Claims (6)

1. The intelligent environment monitoring system based on the Internet of things is characterized by comprising a monitoring protective shell (1), a shielding cover (2), a detection assembly (3), a bottom plate (4) and a lifting assembly (5), wherein the shielding cover (2) is installed on the top end face of the monitoring protective shell (1) through welding, the detection assembly (3) is arranged inside the monitoring protective shell (1), the lifting assembly (5) is arranged on the bottom end face of the monitoring protective shell (1), and the bottom plate (4) is arranged at the bottom of the lifting assembly (5);

the detection assembly (3) comprises a U-shaped air suction shell (31), a rectangular air inlet cylinder (32), an air inlet (33), a guide box (34), an arc-shaped motor shell (35), a positioning groove (36), a sensor bin (37), a central fluted disc (38), a transmission gear (39), an air suction impeller (310) and a rotating motor (311), wherein the central fluted disc (38) is installed in the center of the inner wall of the top of the monitoring protective shell (1) through welding, the sensor bin (37) is arranged in the center of the inner wall of the bottom of the monitoring protective shell (1), the guide box (34) is installed on the end face of the bottom of the monitoring protective shell (1) through welding, the arc-shaped motor shell (35) is installed in the guide box (34) in an attaching mode, the rotating motor (311) is installed on the inner wall of one side of the arc-shaped motor shell (35) through bolts, and the air suction impeller (310) is installed on one end of the top of the rotating motor (311) through a coupler, u type shell (31) of bleeding is installed through the welding in the top end face middle part of arc motor casing (35), and the outside of U type shell (31) of bleeding is pegged graft and is had rectangle air inlet tube (32), drive gear (39) is installed through the welding in the top one end of impeller (310) of bleeding, and drive gear (39) and central fluted disc (38) meshing connection.

2. The intelligent environment monitoring system based on the Internet of things is characterized in that the lifting assembly (5) comprises a fixed top plate (51), a connecting rod (52), a hydraulic cylinder (53) and a hydraulic piston (54), the hydraulic cylinder (53) is installed in the center of the top end face of the bottom plate (4) through welding, the connecting rod (52) is inserted in the center of the top end face of the hydraulic cylinder (53), the fixed top plate (51) is installed at one end of the top of the connecting rod (52) through welding, the fixed top plate (51) is fixedly connected with the bottom end face of the monitoring protective shell (1) through bolts, the hydraulic piston (54) is installed at one end of the bottom of the connecting rod (52) through welding, and the outer wall of the hydraulic piston (54) is attached to the inner wall of the hydraulic cylinder (53).

3. The intelligent environment monitoring system based on the Internet of things is characterized in that a plurality of first reinforcing rib plates are installed between the bottom of the outer wall of the hydraulic cylinder (53) and the bottom plate (4) through welding, and a plurality of second reinforcing rib plates are installed between the top of the outer wall of the connecting rod (52) and the fixed top plate (51) through welding.

4. The intelligent environment monitoring system based on the Internet of things of claim 1, wherein two positioning strips are installed on the outer wall of the arc-shaped motor casing (35) through welding, two positioning grooves (36) are formed in the inner wall of the guide box (34), and the outer wall of each positioning strip is attached to the inner wall of each positioning groove (36).

5. The intelligent environment monitoring system based on the Internet of things of claim 1, wherein a plurality of air inlets (33) are formed in the periphery of the outer wall of the monitoring protective shell (1), and the outer end face of the rectangular air inlet cylinder (32) is attached to the inner wall of the monitoring protective shell (1).

6. The intelligent environment monitoring system based on the Internet of things of claim 1, wherein a limiting block is installed in the center of the top end face of the transmission gear (39) through welding, a limiting groove is formed in the inner wall of the top of the monitoring protective shell (1), and the outer wall of the limiting block is attached to the inner wall of the limiting groove.

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