CN111157053A

CN111157053A - Intelligent water supply and drainage monitoring device based on Internet of things

Info

Publication number: CN111157053A
Application number: CN202010096320.7A
Authority: CN
Inventors: 朱秧
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-02-17
Filing date: 2020-02-17
Publication date: 2020-05-15

Abstract

The invention discloses an intelligent water supply and drainage monitoring device based on the Internet of things, which monitors water supply and drainage and transmits data to equipment connected with the Internet of things through the Internet of things.

Description

Intelligent water supply and drainage monitoring device based on Internet of things

Technical Field

The invention belongs to the technical field of water supply and drainage monitoring equipment; in particular to an intelligent water supply and drainage monitoring device based on the Internet of things.

Background

In recent years, along with the increase of population, the rapid development of industrial and agricultural production and urban construction, the waste amount of each river basin is continuously increased year by year, and the water quality exceeding rate of the provincial section of the river basin is also in an increasing trend; the basin water pollution and the water pollution in the middle and lower reaches are getting worse, and particularly, with the development of economy, the discharge amount of waste water of a plurality of industrial cities is larger, so that the surface water of the cities is seriously polluted, and great hidden troubles are brought to the life health of people. In the emission of plumbing, lead to the water pipe to block up because the rubbish of aquatic is too much to can not carry out effective detection to quality of water, along with the development of thing networking, the thing networking is connected in the plumbing monitoring devices beginning, and current thing networking plumbing monitoring devices nevertheless needs external power supply, and then leads to the bulk consumption of resource.

Disclosure of Invention

The invention aims to provide an intelligent water supply and drainage monitoring device based on the Internet of things, which comprises a water outlet, an impurity storage tank, an Internet of things connecting box, a micro generator, a transmission device, a side cover, a water guide channel, a multi-stage filter screen, an electronic flowmeter, a water inlet, a shell, an impurity screening device and a water quality monitoring tank, wherein the side cover is fixed on one side of the shell, the water guide channel is fixed in the shell, the water inlet is fixed at the upper end of the outer side wall of the shell, the water inlet is communicated with the inner part of the shell, the electronic flowmeter is fixedly arranged on the water inlet, the multi-stage filter screen is arranged on the water guide channel, the multi-stage filter screen is connected with the shell in a sliding fit manner, one part of the transmission device is arranged on the water guide channel, the other part, impurity sieving mechanism and transmission fixed connection, the impurity storage tank is embedded in the casing lower extreme, and impurity storage tank is located impurity sieving mechanism end, the impurity storage tank is connected with casing sliding fit, water quality monitoring groove fixed casing lower extreme, and the water quality monitoring trench is located impurity sieving mechanism and impurity storage tank downside, fixed mounting has the delivery port on the water quality monitoring lateral wall, the delivery port link up with water quality monitoring inslot portion mutually, microgenerator is fixed in on the casing lateral wall, and microgenerator and transmission fixed connection, the thing networking connecting box is fixed in on the casing lateral wall, and thing networking connecting box is located the microgenerator lower extreme, thing networking connecting box and microgenerator, electronic flowmeter and water quality monitoring groove electric connection.

Further, the impurity storage tank is drawer-shaped, the bottom of the impurity storage tank is 400 filter screens, and the impurity storage tank is matched with the shell through a drawer structure.

Further, thing networking connecting box includes microprocessor, signal receiver, signal transmitter, circuit board, battery and connects the box, the circuit board is fixed in inside the connection box, the battery is fixed in inside and battery and the circuit board electric connection of connecting the box, microprocessor, signal receiver, signal transmitter all install in the circuit board, circuit board and microgenerator, electron flowmeter and water quality monitoring groove electric connection.

Further, transmission includes first chain, driven chain gear, first chain gear, drive chain gear, water wheels, second chain and second chain gear, inside water wheels rotated through the water wheel pivot and is fixed in the casing, water wheel pivot one end is embedded on the casing lateral wall, and the other end pierces through the casing lateral wall and installs first chain gear and drive chain gear, the second chain gear is fixed in the microgenerator axis of rotation, driven chain gear rotates and is fixed in on the impurity sieving mechanism, the drive chain gear is connected with driven chain gear transmission through first chain, first chain gear passes through the second chain and is connected with second chain gear transmission.

Furthermore, the water guide channel comprises a first water guide channel and a second water guide channel, the first water guide channel and the second water guide channel are fixed on the inner side wall of the shell, the first water guide channel is arranged at the upper end of the second water guide channel, the first water guide channel and the second water guide channel are inclined, the inclination directions of the first water guide channel and the second water guide channel are opposite, and a water wheel is arranged between the lower end of the first water guide channel and the high end of the second water guide channel.

Further, multistage filter screen forms for a plurality of filter screen combinations, and is a plurality of the filter screen is evenly arranged on first water guide way up end, and is a plurality of the filter screen is 30 meshes, 50 meshes, 80 meshes and 100 meshes filter screen along the rivers direction in proper order.

Further, the impurity screening device comprises a fixing plate, an extension spring, a driving shaft, a driven shaft, a screening transmission chain, a screening driven chain gear, a screening driving chain gear, eccentric cams and a screen plate, wherein the extension spring is fixed on the lower end face of the screen plate, a fixing plate is fixed at the lower end of the extension spring, the fixing plate is fixed on the inner side wall of the shell, the screen plate is movably fixed on the inner side of the shell through the extension spring and the fixing plate, a plurality of eccentric cams are uniformly distributed at the lower side of the screen plate, two eccentric cams are sleeved on the driving shaft and respectively arranged at the left side and the right side of the lower end of the screen plate, one end of the driving shaft is embedded in the side cover, the other end penetrates through the shell and is fixedly connected with the screening driving chain gear and the driven chain gear, a plurality of the driven, the two eccentric cams are respectively arranged on the left side and the right side of the lower end of the screen plate, one end of the driven shaft is embedded in the side cover, the other end of the driven shaft penetrates through the shell to be fixedly connected with the screening driven chain gear, and the screening driving chain gear is in transmission connection with the screening driven chain gear through a screening transmission chain;

the screen plate is a 300-mesh screen.

Further, the water quality monitoring groove includes water quality monitoring probe, first groove, second groove and tank bottom, the first groove is fixed in on the second groove lateral wall, the sieve net board downside is located to the first groove, impurity storage tank downside is located to the second groove, first groove and second groove pass through tank bottom through connection, the tank bottom is the slope tank bottom, and the tank bottom least significant end is located first inslot, the water quality monitoring probe is fixed in on the first groove lateral wall, the delivery port is fixed in on the first groove lateral wall, and delivery port and first inslot side link up mutually.

Further, the working steps and the principle of the invention are as follows:

1) connecting a water inlet to a water outlet pipeline, and connecting a water outlet to a water inlet pipeline;

2) the water body enters the equipment from the water inlet, the water flow is read through the electronic flowmeter, the data are transmitted to the Internet of things connecting box, and the data are fed back to the Internet of things connecting equipment through the Internet of things connecting box;

3) the water body flows through the water guide channel, and when the water body passes through the multi-stage filter screens, the multi-stage filter screens filter sundries in the water body, so that the phenomenon that a water inlet pipeline is blocked due to the outflow of large sundries is avoided;

4) the water flow drives the water wheel to rotate, the water wheel drives the micro generator to rotate through the chain, the micro generator generates electricity and transmits the electric energy into the Internet of things connecting box, and the screening driving chain gear and the screening driven chain gear are driven to rotate and drive the eccentric cam to rotate, so that the screen plate is bumped up and down, and screening capacity is generated;

5) the water body flows into the screen plate, passes through the screen of the screen plate, penetrates through the screen plate and enters the first groove, and impurities are filtered on the screen plate;

6) impurities on the screen plate are shaken into the impurity storage tank through the bumping of the screen plate, a small amount of water entering the impurity storage tank flows into the second tank through a filter screen at the lower end of the impurity storage tank, flows into the first tank through the bottom of the tank, detects the water quality through the water quality monitoring probe, transmits the detected data to the Internet of things connecting box, and feeds the detected data back to the Internet of things connecting equipment through the Internet of things connecting box;

7) the water in the first groove is discharged into the water inlet pipeline from the water outlet.

The invention has the beneficial effects that: the invention not only has the capability of water quality detection and flow detection, but also can filter water with impurities, so as to prevent the impurities from entering a pipeline to cause the pipeline to be blocked, and a water supply and drainage system to be in fault.

Drawings

In order to facilitate understanding for those skilled in the art, the present invention will be further described with reference to the accompanying drawings.

FIG. 1 is a schematic diagram of the general structure of an intelligent water supply and drainage monitoring device based on the Internet of things;

FIG. 2 is a schematic structural diagram of an Internet of things connection box of the intelligent water supply and drainage monitoring device based on the Internet of things;

FIG. 3 is a schematic structural diagram of a transmission device of an intelligent water supply and drainage monitoring device based on the Internet of things;

FIG. 4 is a schematic structural diagram of a water guide channel of the intelligent water supply and drainage monitoring device based on the Internet of things;

FIG. 5 is a schematic structural diagram of an impurity screening device of the intelligent water supply and drainage monitoring device based on the Internet of things;

fig. 6 is a schematic structural diagram of a water quality monitoring tank of the intelligent water supply and drainage monitoring device based on the internet of things.

Detailed Description

Referring to fig. 1-6, an intelligent water supply and drainage monitoring device based on the internet of things comprises a water outlet 1, an impurity storage tank 2, an internet of things connection box 3, a micro generator 4, a transmission device 5, a side cover 6, a water guide channel 7, a multi-stage filter screen 8, an electronic flowmeter 9, a water inlet 10, a shell 11, an impurity screening device 12 and a water quality monitoring tank 13, wherein the side cover 6 is fixed on one side of the shell 11, the water guide channel 7 is fixed inside the shell 11, the water inlet 10 is fixed on the upper end of the outer side wall of the shell 11, the water inlet 10 is communicated with the inside of the shell 11, the electronic flowmeter 9 is fixedly installed on the water inlet 10, the multi-stage filter screen 8 is arranged on the water guide channel 7, the multi-stage filter screen 8 is connected with the shell 11 in a sliding fit manner, one part of the transmission device 5 is arranged on, and the impurity screening device 12 is positioned at the lower end of the water guide channel 7, the impurity screening device 12 is fixedly connected with the transmission device 5, the impurity storage groove 2 is embedded at the lower end of the shell 11, the impurity storage tank 2 is positioned at the tail end of the impurity screening device 12, the impurity storage tank 2 is connected with the shell 11 in a sliding fit manner, the water quality monitoring tank 13 is fixed at the lower end of the shell 11, the water quality monitoring groove 13 is positioned at the lower side of the impurity screening device 12 and the impurity storage groove 2, the outer side wall of the water quality monitoring groove 13 is fixedly provided with a water outlet 1, the water outlet 1 is communicated with the inside of the water quality monitoring groove 13, the micro-generator 4 is fixed on the outer side wall of the shell 11, the micro generator 4 is fixedly connected with the transmission device 5, the internet of things connecting box 3 is fixed on the outer side wall of the shell 11, and thing networking connecting box 3 is located microgenerator 4 lower extreme, thing networking connecting box 3 and microgenerator 4, electron flowmeter 9 and water quality monitoring groove 13 electric connection.

Impurity storage tank 2 is drawer form, and the bottom of impurity storage tank 2 is 400 filter screens, and impurity storage tank 2 passes through drawer structure cooperation with casing 11.

As shown in fig. 2, the internet of things connection box 3 includes a microprocessor 31, a signal receiver 32, a signal transmitter 33, a circuit board 34, a storage battery 35 and a connection box 36, the circuit board 34 is fixed inside the connection box 36, the storage battery 35 is electrically connected to the circuit board 34, the microprocessor 31, the signal receiver 32 and the signal transmitter 33 are all mounted on the circuit board 34, and the circuit board 34 is electrically connected to the micro-generator 4, the electronic flowmeter 9 and the water quality monitoring tank 13.

As shown in fig. 3, the transmission device 5 includes a first chain 51, a driven chain gear 52, a first chain gear 53, a driving chain gear 54, a water wheel 55, a second chain 56 and a second chain gear 57, the water wheel 55 is fixed inside the housing 11 through the rotation of the water wheel shaft, one end of the water wheel shaft is embedded on the side wall of the housing 11, the other end penetrates through the side wall of the housing 11 to be installed with the first chain gear 53 and the driving chain gear 54, the second chain gear 57 is fixed on the rotation shaft of the micro-generator 4, the driven chain gear 52 is fixed on the impurity screening device 12 through the rotation, the driving chain gear 54 is connected with the driven chain gear 52 through the first chain 51 in a transmission manner, and the first chain gear 53 is connected with the second chain gear 57 through the second chain 56.

As shown in fig. 4, the water guide channel 7 includes a first water guide channel 71 and a second water guide channel 72, the first water guide channel 71 and the second water guide channel 72 are both fixed on the inner side wall of the housing 11, the first water guide channel 71 is disposed at the upper end of the second water guide channel 72, the first water guide channel 71 and the second water guide channel 72 are both inclined, the inclination directions of the first water guide channel 71 and the second water guide channel 72 are opposite, and a water wheel 55 is disposed between the lower end of the first water guide channel 71 and the high end of the second water guide channel 72.

The multi-stage filter screen 8 is formed by combining a plurality of filter screens, the filter screens are uniformly distributed on the upper end surface of the first water guide channel 71, and the filter screens are 30-mesh, 50-mesh, 80-mesh and 100-mesh filter screens in sequence along the water flow direction.

As shown in fig. 5, the impurity screening apparatus 12 includes a fixing plate 121, an extension spring 122, a driving shaft 123, a driven shaft 124, a screening transmission chain 125, a screening driven chain gear 126, a screening driving chain gear 127, an eccentric cam 128 and a screen plate 129, wherein the extension spring 122 is fixed on the lower end surface of the screen plate 129, the fixing plate 121 is fixed on the lower end of the extension spring 122, the fixing plate 121 is fixed on the inner side wall of the housing 11, the screen plate 129 is movably fixed on the inner side of the housing 11 through the extension spring 122 and the fixing plate 121, a plurality of eccentric cams 128 are uniformly distributed on the lower side of the screen plate 129, two eccentric cams 128 are sleeved on the driving shaft 123, the two eccentric cams 128 are respectively arranged on the left and right sides of the lower end of the screen plate 129, one end of the driving shaft 123 is embedded in the side cover 6, the other end, the driven shafts 124 are respectively sleeved with two eccentric cams 128, the two eccentric cams 128 are respectively arranged on the left side and the right side of the lower end of the screen plate 129, one end of each driven shaft 124 is embedded in the side cover 6, the other end of each driven shaft penetrates through the shell 11 to be fixedly connected with the screening driven chain gear 126, and the screening driving chain gear 127 and the screening driven chain gear 126 are in transmission connection through the screening driving chain 125.

The screen panel 129 is a 300 mesh screen.

As shown in fig. 6, the water quality monitoring tank 13 includes a water quality monitoring probe 131, a first tank 132, a second tank 133 and a tank bottom 134, the first tank 132 is fixed on the side wall of the second tank 133, the first tank 132 is disposed under the screen plate 129, the second tank 133 is disposed under the impurity storage tank 2, the first tank 132 and the second tank 133 are connected through the tank bottom 134, the tank bottom 134 is an inclined tank bottom, the lowest end of the tank bottom 134 is located in the first tank 132, the water quality monitoring probe 131 is fixed on the side wall of the first tank 132, the water outlet 1 is fixed on the outer side wall of the first tank 132, and the water outlet 1 is communicated with the inner side of the first tank 132.

The working steps and the principle of the invention are as follows:

1) the water inlet 10 is connected with a water outlet pipeline, and the water outlet 1 is connected with a water inlet pipeline;

2) a water body enters the equipment from a water inlet 10, the water flow is read through an electronic flowmeter 9, data are transmitted to the Internet of things connecting box 3, and the data are fed back to the Internet of things connecting equipment through the Internet of things connecting box 3;

3) the water body flows through the water guide channel 7, and when the water body passes through the multistage filter screens 8, the multistage filter screens 8 filter sundries in the water body, so that the phenomenon that a water inlet pipeline is blocked due to the fact that large sundries flow out is avoided;

4) the water body flows to drive the water wheel 55 to rotate, the water wheel 55 drives the micro generator 4 to rotate through a chain, so that the micro generator 4 generates electricity and transmits the electric energy into the internet of things connecting box 3, and on the other hand, the screening driving chain gear 127 and the screening driven chain gear 126 are driven to rotate, and the screening driving chain gear 127 and the screening driven chain gear 126 drive the eccentric cam 128 to rotate, so that the screen plate 129 jolts up and down to generate screening capacity;

5) the water body flows into the screen plate 129, passes through the screen of the screen plate 129, penetrates through the screen plate 129 and enters the first groove 132, and impurities are filtered on the screen plate 129;

6) through the bumping of the screen plate 129, impurities on the screen plate 129 are shaken into the impurity storage tank 2, a small amount of water entering the impurity storage tank 2 flows into the second tank 133 through a filter screen at the lower end of the impurity storage tank 2, and flows into the first tank 132 through the tank bottom 134, at the moment, the water quality monitoring probe 131 detects the water quality, transmits the detected data to the internet of things connecting box 3, and feeds the detected data back to the internet of things connecting equipment through the internet of things connecting box 3;

7) the water in the first groove 132 is discharged from the water outlet 1 into the water inlet pipe.

The foregoing is merely exemplary and illustrative of the present invention and various modifications, additions and substitutions may be made by those skilled in the art to the specific embodiments described without departing from the scope of the invention as defined in the following claims.

Claims

1. An intelligent water supply and drainage monitoring device based on the Internet of things comprises a water outlet (1), an impurity storage tank (2), an Internet of things connecting box (3), a micro generator (4), a transmission device (5), a side cover (6), a water guide channel (7), a multi-stage filter screen (8), an electronic flowmeter (9), a water inlet (10), a shell (11), an impurity screening device (12) and a water quality monitoring tank (13), and is characterized in that the side cover (6) is fixed on one side of the shell (11), the water guide channel (7) is fixed inside the shell (11), the water inlet (10) is fixed at the upper end of the outer side wall of the shell (11), the water inlet (10) is communicated with the inside of the shell (11), the electronic flowmeter (9) is fixedly installed on the water inlet (10), and the multi-stage filter screen (8) is arranged on the water guide channel (7, the multi-stage filter screen (8) is connected with the shell (11) in a sliding fit manner, one part of the transmission device (5) is arranged on the water guide channel (7), the other part of the transmission device is fixed on the outer side wall of the shell (11), the impurity screening device (12) is arranged on the inner side of the shell (11), the impurity screening device (12) is positioned at the lower end of the water guide channel (7), the impurity screening device (12) is fixedly connected with the transmission device (5), the impurity storage tank (2) is embedded at the lower end of the shell (11), the impurity storage tank (2) is positioned at the tail end of the impurity screening device (12), the impurity storage tank (2) is connected with the shell (11) in a sliding fit manner, the water quality monitoring tank (13) is fixed at the lower end of the shell (11), the water quality monitoring tank (13) is positioned at the lower side of the impurity screening device (12) and the impurity storage tank (2), and a water outlet (1) is fixedly arranged, delivery port (1) link up with water quality monitoring groove (13) inside mutually, on miniature generator (4) were fixed in casing (11) lateral wall, and miniature generator (4) and transmission (5) fixed connection, thing networking connecting box (3) were fixed in on casing (11) lateral wall, and thing networking connecting box (3) were located miniature generator (4) lower extreme, thing networking connecting box (3) and miniature generator (4), electron flowmeter (9) and water quality monitoring groove (13) electric connection.

2. The intelligent water supply and drainage monitoring device based on the Internet of things is characterized in that the impurity storage tank (2) is drawer-shaped, a 400-filter screen is arranged at the bottom of the impurity storage tank (2), and the impurity storage tank (2) is matched with the shell (11) through a drawer structure.

3. The intelligent water supply and drainage monitoring device based on the Internet of things is according to claim 1, wherein the Internet of things connecting box (3) comprises a microprocessor (31), a signal receiver (32), a signal transmitter (33), a circuit board (34), a storage battery (35) and a connecting box body (36), the circuit board (34) is fixed inside the connecting box body (36), the storage battery (35) is fixed inside the connecting box body (36) and the storage battery (35) is electrically connected with the circuit board (34), the microprocessor (31), the signal receiver (32) and the signal transmitter (33) are all installed on the circuit board (34), and the circuit board (34) is electrically connected with the micro generator (4), the electronic flowmeter (9) and the water quality monitoring groove (13).

4. The intelligent water supply and drainage monitoring device based on the Internet of things is characterized in that the transmission device (5) comprises a first chain (51), a driven chain gear (52), a first chain gear (53), a driving chain gear (54), a water wheel (55), a second chain (56) and a second chain gear (57), the water wheel (55) is rotationally fixed inside the shell (11) through a water wheel rotating shaft, one end of the water wheel rotating shaft is embedded in the side wall of the shell (11), the other end of the water wheel rotating shaft penetrates through the side wall of the shell (11) and is provided with the first chain gear (53) and the driving chain gear (54), the second chain gear (57) is fixed on a rotating shaft of the micro-generator (4), the driven chain gear (52) is rotationally fixed on the impurity screening device (12), and the driving chain gear (54) is in transmission connection with the driven chain gear (52) through the first chain (51), the first chain gear (53) is in transmission connection with the second chain gear (57) through a second chain (56).

5. The intelligent water supply and drainage monitoring device based on the internet of things as claimed in claim 1, wherein the water guide channel (7) comprises a first water guide channel (71) and a second water guide channel (72), the first water guide channel (71) and the second water guide channel (72) are fixed on the inner side wall of the shell (11), the first water guide channel (71) is arranged at the upper end of the second water guide channel (72), the first water guide channel (71) and the second water guide channel (72) are inclined, the inclination directions of the first water guide channel (71) and the second water guide channel (72) are opposite, and a water wheel (55) is arranged between the lower end of the first water guide channel (71) and the high end of the second water guide channel (72).

6. The intelligent water supply and drainage monitoring device based on the Internet of things as claimed in claim 1, wherein the multi-stage filter screens (8) are formed by combining a plurality of filter screens, the filter screens are uniformly distributed on the upper end surface of the first water guide channel (71), and the filter screens are 30-mesh, 50-mesh, 80-mesh and 100-mesh filter screens in sequence along the water flow direction.

7. The intelligent water supply and drainage monitoring device based on the Internet of things is characterized in that the impurity screening device (12) comprises a fixing plate (121), an extension spring (122), a driving shaft (123), a driven shaft (124), a screening transmission chain (125), a screening driven chain gear (126), a screening driving chain gear (127), an eccentric cam (128) and a screen plate (129), the extension spring (122) is fixed on the lower end face of the screen plate (129), the lower end of the extension spring (122) is fixed with the fixing plate (121), the fixing plate (121) is fixed on the inner side wall of the shell (11), the screen plate (129) is movably fixed on the inner side of the shell (11) through the extension spring (122) and the fixing plate (121), a plurality of eccentric cams (128) are uniformly distributed on the lower side of the screen plate (129), and two eccentric cams (128) are sleeved on the driving shaft (123), the two eccentric cams (128) are respectively arranged on the left side and the right side of the lower end of the screen plate (129), one end of the driving shaft (123) is embedded in the side cover (6), the other end of the driving shaft penetrates through the shell (11) to be fixedly connected with the screening driving chain gear (127) and the driven chain gear (52), a plurality of driven shafts (124) are arranged, the driven shafts (124) are respectively sleeved with the two eccentric cams (128), the two eccentric cams (128) are respectively arranged on the left side and the right side of the lower end of the screen plate (129), one end of each driven shaft (124) is embedded in the side cover (6), the other end of each driven shaft penetrates through the shell (11) to be fixedly connected with the screening driven chain gear (126), and the screening driving chain gear (127) is in transmission connection with the screening driven chain gear (126) through the screening;

the screen plate (129) is a 300-mesh screen.

8. The intelligent water supply and drainage monitoring device based on the Internet of things as claimed in claim 1, the water quality monitoring tank (13) comprises a water quality monitoring probe (131), a first tank (132), a second tank (133) and a tank bottom (134), the first groove (132) is fixed on the side wall of the second groove (133), the first groove (132) is arranged at the lower side of the screen plate (129), the second groove (133) is arranged at the lower side of the impurity storage groove (2), the first groove (132) and the second groove (133) are communicated through a groove bottom (134), the groove bottom (134) is an inclined groove bottom, and the lowest end of the groove bottom (134) is positioned in the first groove (132), the water quality monitoring probe (131) is fixed on the side wall of the first groove (132), the water outlet (1) is fixed on the outer side wall of the first groove (132), and the water outlet (1) is communicated with the inner side of the first groove (132).