CN111596023A

CN111596023A - Cloud service control submersible water quality monitoring equipment

Info

Publication number: CN111596023A
Application number: CN202010492762.3A
Authority: CN
Inventors: 陈亚
Original assignee: Individual
Current assignee: Hengshui Avenue Environmental Technology Co ltd; Shenzhen Tideiot Technology Co ltd
Priority date: 2020-06-03
Filing date: 2020-06-03
Publication date: 2020-08-28
Anticipated expiration: 2040-06-03
Also published as: CN111596023B

Abstract

The invention discloses a cloud service control submersible water quality monitoring device which comprises a machine body, wherein a plurality of positioning rods are symmetrically arranged on the side wall of the machine body, a supporting plate is jointly arranged at the upper ends of the positioning rods, and a signal transceiver is arranged on the upper surface of the supporting plate. The invention realizes that the blades always rotate towards the same direction through the rigid limit and the elastic limit between the blades and the shaft lever, thereby increasing the generating efficiency, ensuring the normal work of the water pump, reducing the labor force through the real-time monitoring of the machine body in water for a long time, and shortening the analysis period by synchronously carrying out multiple areas.

Description

Cloud service control submersible water quality monitoring equipment

Technical Field

The invention relates to the field of cloud equipment, in particular to a cloud service control submersible water quality monitoring device.

Background

The water quality detection can investigate the change of water quality in an area, and the implementation situation of environmental protection in the area, the health conditions of people and animals and the like can be seen from the change.

The existing water quality detection usually adopts manual sampling detection, namely a detector is placed in a water area to a certain depth or sample water is taken from the deep layer of the water area to detect the water, the detection mode needs manual work to go to each water area periodically to carry out sample collection, the workload is large, the time for collecting data is long due to different times for collecting different water areas, the period for analyzing the whole water sample is long, and the implementation scheme cannot be rapidly made according to the current situation.

Disclosure of Invention

The invention aims to solve the defects that the manual sampling workload is large and the analysis period is long due to different sampling times in the prior art, and provides a cloud service control submersible water quality monitoring device.

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

a cloud service control submersible water quality monitoring device comprises a machine body, wherein a plurality of positioning rods are symmetrically arranged on the side wall of the machine body, a supporting plate is jointly arranged at the upper ends of the plurality of positioning rods, a signal transceiver is arranged on the upper surface of the supporting plate, a transmission cavity is respectively formed in the machine body, an energy storage cavity and a working cavity are respectively formed below the transmission cavity in the machine body, a control cavity and a sample cavity are respectively formed below the energy storage cavity and the working cavity in the machine body, an energy storage battery is arranged in the energy storage cavity, a control detector is arranged in the control cavity, a detection rod is arranged on the control detector and extends into the sample cavity, a filter screen is embedded on the inner bottom wall of the sample cavity, a generator is arranged in the working cavity and comprises a bidirectional shaft, and a water pump is arranged at the lower end of the bidirectional shaft, a water inlet pipe and a water outlet pipe are respectively arranged on the water pump;

a straight pipe is inserted into the machine body in a rotating mode, the lower end of the straight pipe extends into a transmission cavity and is provided with a driving gear, the upper end of the bidirectional shaft extends into the transmission cavity and is provided with a driven gear, the driven gear is meshed with the driving gear, a plurality of groups of supports are annularly and symmetrically arranged at the upper end of the straight pipe, a shaft lever is arranged between each group of supports, each shaft lever is rotatably sleeved with a blade, two first blocking pieces are symmetrically arranged on the side wall of each shaft lever, a rotating hole is formed in each blade, two second blocking pieces are symmetrically arranged on the wall of each rotating hole, and two reset springs are respectively arranged between the two first blocking pieces and the two second blocking pieces;

the signal transceiver is provided with a signal line, the lower end of the signal line penetrates through the straight pipe to extend into the control cavity and is connected with the control detector, one section of the signal line, which is positioned in the straight pipe, is rotatably sleeved with a plurality of positioning bearings, and each positioning bearing is fixed on the inner wall of the straight pipe.

Preferably, the water inlet pipe extends into the sample cavity, and the water outlet pipe extends to the outer side of the machine body.

Preferably, the generator is electrically connected with an energy storage battery, and the energy storage battery is electrically connected with the control detector.

The invention has the following beneficial effects:

1. the water flow at the bottom is induced by the blades, the water flow impacts the blades to enable the blades to drive the straight pipe to rotate through the bracket, when the water flow impacts the blades, because the blades are limited by the first blocking piece and the second blocking piece, the water flow impacts the blades to rotate to drive the shaft lever, the bracket and the straight pipe to rotate, when the blade is impacted by water flow in the direction of the limit of the return spring, the blade rotates around the shaft rod, the stressed area is reduced, namely, the force of the blade limited by the first blocking piece and the second blocking piece is larger than that of the blade limited by the return spring, namely, the water flow always pushes the blades to rotate towards the mutual limiting direction of the first baffle plate and the second baffle plate, thus ensuring that the rotating directions of the blades and the straight pipe are not changed no matter how the water flow direction changes, namely, the rotating direction of the driving gear can be kept unchanged, namely, the normal operation of the water pump and the normal operation of the generator are ensured through the meshing of the driven gear.

2. The water pump makes the continuous circulation of water in the sample chamber update through inlet tube and drain pipe, guarantees that the water in the sample chamber is unanimous with the water in the waters, increases the accuracy that detects.

3. The water flow energy is converted into the electric energy through the generator, the electric energy is stored in the energy storage battery and used for controlling the detector, the power supply through the cable is not needed, the electric energy is saved, and the situation that the cable is damaged easily during long-term work in water and the maintenance work is increased is avoided.

4. Be in aquatic real-time supervision quality of water condition for a long time through the organism to through signal line and signal transceiver and external transmission data signal, need not artifical monitoring, can a plurality of regions monitor simultaneously and acquire data, shorten water quality analysis's cycle.

In conclusion, the blade is enabled to rotate towards the same direction all the time through the rigid limit and the elastic limit between the blade and the shaft rod, the power generation efficiency is increased, the water pump can work normally, real-time monitoring is carried out in water for a long time through the machine body, labor force is reduced, multiple regions can be synchronously carried out, and the analysis period is shortened.

Drawings

FIG. 1 is a schematic structural diagram of a cloud service control submersible water quality monitoring device according to the present invention;

FIG. 2 is an enlarged view of a body part structure of the cloud service control submersible water quality monitoring device provided by the invention;

FIG. 3 is an enlarged view of a straight pipe part of the cloud service control submersible water quality monitoring device provided by the invention;

FIG. 4 is an enlarged view of a shaft portion of a cloud service control submersible water quality monitoring device according to the present invention.

In the figure: 1 machine body, 11 transmission cavities, 12 energy storage cavities, 13 control cavities, 14 working cavities, 15 sample cavities, 151 filter screens, 16 positioning rods, 161 supporting plates, 2 signal transceivers, 3 straight pipes, 31 brackets, 32 shaft rods, 321 first baffle plates, 3211 reset springs, 33 blades, 331 rotating holes, 3311 second baffle plates, 34 driving gears, 4 signal lines, 41 positioning bearings, 5 energy storage batteries, 6 control detectors, 61 detection rods, 7 generators, 71 bidirectional shafts, 711 driven gears, 8 water pumps, 81 water inlet pipes and 82 water outlet pipes.

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.

Referring to fig. 1-4, a cloud service control submersible water quality monitoring device comprises a machine body 1, a plurality of positioning rods 16 are symmetrically installed on the side wall of the machine body 1, a supporting plate 161 is installed at the upper ends of the positioning rods 16, a signal transceiver 2 is installed on the upper surface of the supporting plate 161, a transmission cavity 11 is respectively arranged in the machine body 1, an energy storage cavity 12 and a working cavity 14 are respectively arranged in the machine body 1 below the transmission cavity 11, a control cavity 13 and a sample cavity 15 are respectively arranged in the machine body 1 below the energy storage cavity 12 and the working cavity 14, an energy storage battery 5 is installed in the energy storage cavity 12, a control detector 6 is installed in the control cavity 13, a detection rod 61 is installed on the control detector 6, the detection rod 61 extends into the sample cavity 15, a filter screen 151 is embedded on the inner bottom wall of the sample cavity 15, a generator 7 is installed in the working cavity 14, the generator 7 comprises a bidirectional shaft, the lower end of the bidirectional shaft 71 is provided with a water pump 8, and the water pump 8 is provided with a water inlet pipe 81 and a water outlet pipe 82 respectively;

a straight pipe 3 is rotatably inserted into the machine body 1, the lower end of the straight pipe 3 extends into the transmission cavity 11 and is provided with a driving gear 34, the upper end of a bidirectional shaft 71 extends into the transmission cavity 11 and is provided with a driven gear 711, the driven gear 711 is meshed with the driving gear 34, a plurality of groups of supports 31 are annularly and symmetrically arranged at the upper end of the straight pipe 3, a shaft lever 32 is arranged between each group of supports 31, each shaft lever 32 is rotatably sleeved with a blade 33, two first blocking pieces 321 are symmetrically arranged on the side wall of the shaft lever 32, a rotating hole 331 is formed in each blade 33, two second blocking pieces 3311 are symmetrically arranged on the hole wall of each rotating hole 331, and two reset springs 3211 are respectively arranged between each first blocking piece 321 and each second blocking;

when water flow impacts the blade 33, because the blade 33 is limited by the first blocking piece 321 and the second blocking piece 3311, the water flow impacts the blade to rotate to drive the shaft rod 32, the bracket 31 and the straight tube 3 to rotate, and when the blade is impacted by the water flow in the limiting direction of the return spring 3211, the blade 33 rotates around the shaft rod 32, the stressed area is reduced, namely the stress of the blade 33 limited by the first blocking piece 321 and the second blocking piece 3311 is greater than that of the blade 33 limited by the return spring 3211, namely, the water flow always pushes the blade 33 to rotate towards the limiting direction of the first blocking piece 321 and the second blocking piece 3311, namely, the rotating direction of the blade 33 and the straight tube 3 is not changed no matter how the water flow direction changes, namely, the rotating direction of the driving gear 34 is not changed;

a signal wire 4 is arranged on the signal transceiver 2, the lower end of the signal wire 4 penetrates through the straight pipe 3 and extends into the control cavity 13 and is connected with the control detector 6, a section of the signal wire 4, which is positioned in the straight pipe 3, is rotatably sleeved with a plurality of positioning bearings 41, and each positioning bearing 41 is fixed on the inner wall of the straight pipe 3;

signal transceiver 2 and high in the clouds server wireless connection, signal transceiver 2 is transmitted to through signal line 4 to the quality of water condition in the control detector 6 real-time detection sample chamber 15 through detecting stick 61, transmit data to the unified analysis of high in the clouds server through signal transceiver 2, and simultaneously, the cycle etc. of high in the clouds server accessible signal transceiver 2 and the 4 remote operation change control detector 6 detection water quality of signal line for multizone quality of water detects the collection simultaneously, shorten the water quality analysis cycle.

In inlet tube 81 extends to sample chamber 15, drain pipe 82 extends to the outside of organism 1, and water pump 8 is driven work by two-way axle 71 in hydroelectric power generation, makes the sample water continuous cycle in the sample chamber 15 through inlet tube 81 and drain pipe 82, guarantees the accuracy that detects.

Generator 7 electric connection energy storage battery 5, energy storage battery 5 electric connection control detector 6, water impact blade 33 makes straight tube 3 rotate towards same direction, it keeps unchangeable to make driving gear 34 drive driven gear 711 rotation direction, it is unchangeable to make the rotation direction of two-way axle 71, then water pump 8 can last normal work, and need not power consumptive operation, then generator 7 can last stable electricity generation, increase the generating efficiency, the electric energy input energy storage battery 5 storage that generator 7 produced, the electric energy of energy storage battery 5 storage supplies control detector 6 and signal transceiver 2 to use and need not external power supply, can make organism 1 move in aqueous for a long time.

When the water pump is used, water flow impacts the blade 33, the blade 33 cannot rotate along with the shaft lever 32 in the direction limited by the first blocking piece 321 and the second blocking piece 3311, and only can rotate in the direction limited by the return spring 3211, so that the resistance in the direction limited by the first blocking piece 321 and the second blocking piece 3311 is greater than the direction limited by the return spring 3211, when the water flow in any direction impacts the blade 33, the blade 33 only can push the straight pipe 3 to rotate in one direction through the shaft lever 32 and the bracket 31, so that the driving gear 34 rotates in the same direction, the driven gear 711 rotates in one direction, the generator 7 generates electricity stably, the water pump 8 works stably, the generator 7 transmits the electric energy to the energy storage battery 5 for storage, and the energy storage battery 5 supplies the electric energy to the control detector 6 and the signal transceiver 2;

water pump 8 makes the rivers in the sample chamber 15 constantly flow through inlet tube 81 and drain pipe 82, increases the accuracy that detects stick 61 and detects, and control detector 6 transmits signal transceiver 2 through signal line 4 through the data that detect stick 61 detected, and signal transceiver 2 is with data transmission to high in the clouds server analysis calculation, and the period that quality of water analysis can be shortened in the upload of a plurality of regional collection data simultaneously, and reduces artifical sample detection's work load.

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 the technical solutions and the inventive concepts thereof according to the present invention should be equivalent or changed within the scope of the present invention.

Claims

1. A cloud service control submersible water quality monitoring device comprises a machine body (1) and is characterized in that a plurality of positioning rods (16) are symmetrically installed on the side wall of the machine body (1), a supporting plate (161) is installed at the upper ends of the positioning rods (16) together, a signal transceiver (2) is installed on the upper surface of the supporting plate (161), a transmission cavity (11) is formed in the machine body (1), an energy storage cavity (12) and a working cavity (14) are respectively formed in the machine body (1) below the transmission cavity (11), a control cavity (13) and a sample cavity (15) are respectively formed in the machine body (1) below the energy storage cavity (12) and the working cavity (14), an energy storage battery (5) is installed in the energy storage cavity (12), a control detector (6) is installed in the control cavity (13), and a detection rod (61) is installed on the control detector (6), the detection rod (61) extends into the sample cavity (15), a filter screen (151) is embedded in the inner bottom wall of the sample cavity (15), a generator (7) is installed in the working cavity (14), the generator (7) comprises a bidirectional shaft (71), a water pump (8) is installed at the lower end of the bidirectional shaft (71), and a water inlet pipe (81) and a water outlet pipe (82) are installed on the water pump (8) respectively;

a straight pipe (3) is rotatably inserted on the machine body (1), the lower end of the straight pipe (3) extends into the transmission cavity (11) and is provided with a driving gear (34), the upper end of the bidirectional shaft (71) extends into the transmission cavity (11) and is provided with a driven gear (711), the driven gear (711) is meshed with the driving gear (34), a plurality of groups of supports (31) are annularly and symmetrically arranged at the upper end of the straight pipe (3), a shaft lever (32) is arranged between each group of supports (31), each shaft lever (32) is rotatably sleeved with a blade (33), two first blocking pieces (321) are symmetrically arranged on the side wall of the shaft lever (32), a rotating hole (331) is formed in the blade (33), two second blocking pieces (3311) are symmetrically arranged on the wall of the rotating hole (331), and two return springs (3211) are respectively arranged between the two first blocking pieces (321) and the two second blocking pieces (3311);

install signal line (4) on signal transceiver (2), the lower extreme of signal line (4) passes straight tube (3) and extends to in control chamber (13) and connects control detector (6), one section rotation cover that signal line (4) are located straight tube (3) is equipped with a plurality of location bearing (41), every location bearing (41) are all fixed on the inner wall of straight tube (3).

2. The submersible water quality monitoring device with cloud service control as claimed in claim 1, wherein the water inlet pipe (81) extends into the sample chamber (15) and the water outlet pipe (82) extends to the outside of the machine body (1).

3. The submersible water quality monitoring device with cloud service control as claimed in claim 1, wherein the generator (7) is electrically connected with an energy storage battery (5), and the energy storage battery (5) is electrically connected with the control detector (6).