CN219871279U - Comprehensive detection device for water quantity and water quality - Google Patents

Abstract

The utility model discloses a comprehensive water quantity and water quality detection device which comprises a device body, a collecting mechanism, an aerator, an oxygen supply pipe, a contact sensor and a supporting rod, wherein the oxygen supply pipe is arranged at the central position of the bottom of the device body, a base is arranged at the bottom of the device body on one side of the oxygen supply pipe, a kinetic energy motor is fixed at the central position of the top end of the base, a wireless transceiver is fixed on the inner wall of the device body above the kinetic energy motor, a GPRS (general packet radio service) module is arranged at one end of the wireless transceiver, and a data acquisition module is arranged below the device body. The utility model can not only sample and detect different water areas at different positions and recover toxic substances, solid particles and household garbage, but also provide sufficient oxygen to quickly repair the detected anoxic source.

Description

Comprehensive detection device for water quantity and water quality

Technical Field

The utility model relates to the technical field of detection devices, in particular to a comprehensive detection device for water quantity and water quality.

Background

With rapid development of economy, large-scale production of chemical industry and the like, urban sewage discharge is more and more, river pollution is serious, water resources are protected from being sustained, real-time detection is needed, abnormal conditions in water can be found in time through online detection of conventional characteristic parameters of the water, and early warning and self-treatment are carried out in time.

The detection devices on the market today are various, and can basically meet the use requirements of people, but certain problems still exist, and the specific problems include the following points:

(1) The traditional detection device is generally inconvenient to sample and detect the fluid with different water levels at different positions when in use, thereby seriously affecting the accuracy of the detection device when in use;

(2) The traditional detection device can only detect when in use, is inconvenient to self-regulate and repair water resources, thereby greatly influencing the limitation of detection when the detection device is in use;

(3) The traditional detection device generally detects toxic substances, solid particles and household garbage when in use, and is inconvenient to collect and destroy pollution sources, so that great trouble is brought to the convenience of the detection device.

Disclosure of Invention

The utility model aims to provide a comprehensive water quantity and water quality detection device, which solves the problems that in the background technology, the detection device is provided, sampling detection of fluids with different water levels at different positions is inconvenient, self-adjusting and repairing of water resources are difficult, and recovery of pollution sources is inconvenient for household garbage.

In order to achieve the above purpose, the present utility model provides the following technical solutions: the utility model provides a comprehensive water yield and quality of water detection device, including the device body, collection mechanism, the oxygen-increasing device, the oxygen supply tube, the contact sensor, the oxygen supply tube is installed to the central point department of device body bottom, the bottom of oxygen supply tube extends to the outside of device body, and oxygen-spraying head of equidistant is fixed with below the oxygen supply tube, device body bottom in oxygen supply tube one side is equipped with the base, the central point department of base top is fixed with kinetic energy motor, kinetic energy motor's output is installed the third pivot through the shaft coupling, the third pivot stretches out to the device body outside, the screw is installed on the top, be fixed with wireless transceiver on the device body inner wall of kinetic energy motor top, the GPRS module is installed to wireless transceiver's one end, the battery is installed at the device body top of wireless transceiver top, device body outside top central point department installs the oxygen-increasing device, device body top of oxygen-increasing device side is equipped with collection mechanism, device body outside top of collection mechanism one side is equipped with solar panel, the device body outside top of oxygen supply tube is kept away from base one side is equipped with the analysis appearance through photovoltaic controller and the input electrical connection of battery, device body bottom of device body one side is equipped with the analysis meter, device body bottom of analysis meter one side is equipped with the inside the device of analysis device, device body bottom of analysis meter is equipped with the contact sensor on the inside of the device, device is equipped with the inside of the protection shell.

And both outer side walls of the data acquisition module are provided with a pH value probe, a residual chlorine probe and a dissolved oxygen detection probe, and data acquired by the data acquisition module are uploaded to the analyzer.

Two groups of support rods are arranged on two outer side walls of the contact sensor, the other ends of the support rods are fixedly connected with the inner wall of the protective shell, a floating probe is arranged at the central position inside the contact sensor, and the bottom ends of the floating probes extend to the outer parts of the support rods.

The collecting mechanism comprises a collecting drum, a first rotating shaft, a rotating motor and a recovery box, wherein the top of the recovery box is open, the rotating motor is embedded in the top end of the device body, the inner wall of one side of the recovery box is provided with the rotating motor, the rotating motor is provided with the first rotating shaft through a coupling, one end of the first rotating shaft, which is far away from the rotating motor, is provided with the collecting drum, one end of the collecting drum is hinged with the inner wall of the recovery box, and the collecting drum is provided with a plurality of hooks.

The telescopic machanism includes lift case, rack bar, gear, asynchronous motor, second pivot and limiting plate, and the device body bottom of analysis appearance side of keeping away from the oxygen supply tube is equipped with the lift case, articulates on the inner wall of lift case one side has the gear, is equipped with asynchronous motor on the lift case inner wall of gear one side.

The output of asynchronous machine installs the second pivot through the shaft coupling, and the one end of second pivot and the outer wall fixed connection of gear, and the hoist box internally mounted of gear one side has the rack pole, and the bottom of rack pole extends to the outside of device body, rack pole and gear intermeshing are equipped with the limiting plate on the outer wall of rack pole one side, the top of limiting plate and the top fixed connection of hoist box.

The output end inside the singlechip is in bidirectional telecommunication connection with the GPRS module and the wireless transceiver, the singlechip is in electric connection with the input ends of the kinetic energy motor, the rotating motor, the asynchronous motor and the aerator, and the input end of the singlechip is also in electric connection with the output ends of the analyzer and the contact sensor.

Compared with the prior art, the utility model has the beneficial effects that: not only can sample and detect different waters in different positions, retrieve toxic substance, solid particle, domestic waste, but also can provide sufficient oxygen, carry out quick restoration to detecting the hypoxia source.

Drawings

FIG. 1 is a schematic cross-sectional elevation view of the present utility model;

FIG. 2 is a schematic side sectional view of the present utility model;

FIG. 3 is an enlarged schematic cross-sectional view of the collection mechanism of the present utility model;

FIG. 4 is an enlarged schematic cross-sectional view of the telescopic mechanism of the present utility model;

fig. 5 is a schematic diagram of a system frame structure according to the present utility model.

In the figure: 1. a device body; 2. a collection mechanism; 201. winding up a winding drum; 202. a first rotating shaft; 203. a rotating electric machine; 204. a recovery box; 3. an aerator; 4. a solar panel; 5. a storage battery; 6. a GPRS module; 7. a wireless transceiver; 8. a third rotating shaft; 9. a propeller; 10. a kinetic energy motor; 11. a base; 12. an oxygen spraying head; 13. an oxygen supply pipe; 14. a resolver; 15. a data acquisition module; 16. a dissolved oxygen detection probe; 17. a pH value probe; 18. residual chlorine probe; 19. a telescoping mechanism; 1901. a lifting box; 1902. a rack bar; 1903. a gear; 1904. an asynchronous motor; 1905. a second rotating shaft; 1906. a limiting plate; 20. a single chip microcomputer; 21. a protective shell; 22. a floating probe; 23. a contact sensor; 24. and (5) supporting the rod.

Detailed Description

The technical solutions in the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model; it is apparent that the described embodiments are only some embodiments of the present utility model, not all embodiments, and that all other embodiments obtained by persons of ordinary skill in the art without making creative efforts based on the embodiments in the present utility model are within the protection scope of the present utility model.

In the description of the present utility model, it should be noted that the positional or positional relationship indicated by the terms such as "upper", "lower", "inner", "outer", "top/bottom", etc. are based on the positional or positional relationship shown in the drawings, are merely for convenience of describing the present utility model and simplifying the description, and do not indicate or imply that the apparatus or elements referred to must have a specific orientation, be constructed and operated in a specific orientation, and thus should not be construed as limiting the present utility model. Furthermore, the terms "first," "second," and the like, are used for descriptive purposes only and are not to be construed as indicating or implying relative importance.

In the description of the present utility model, it should be noted that, unless explicitly specified and limited otherwise, the terms "mounted," "configured to," "engaged with," "connected to," and the like are to be construed broadly, and may be either fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; can be directly connected or indirectly connected through an intermediate medium, and can be communication between two elements. The specific meaning of the above terms in the present utility model will be understood in specific cases by those of ordinary skill in the art.

As shown in fig. 1-4, the comprehensive water quantity and water quality detection device comprises a device body 1, a collecting mechanism 2, an aerator 3, an oxygen supply pipe 13 and a contact sensor 23, wherein the oxygen supply pipe 13 is arranged at the central position of the bottom of the device body 1, the bottom end of the oxygen supply pipe 13 extends to the outside of the device body 1, an equidistant oxygen spraying head 12 is fixed below the oxygen supply pipe 13, a base 11 is arranged at the bottom of the device body 1 on one side of the oxygen supply pipe 13, a kinetic energy motor 10 is fixed at the central position of the top end of the base 11, the model number of the kinetic energy motor 10 is WHP-4, the output end of a single-chip microcomputer 20 is electrically connected with the input end of the kinetic energy motor 10, a third rotating shaft 8 is arranged through a coupler, the third rotating shaft 8 extends out of the device body 1, a propeller 9 is arranged at the top end of the kinetic energy motor 10, a wireless transceiver 7 is fixed on the inner wall of the device body 1, the model number ZM-4 of the wireless transceiver 7 is fixed below the oxygen supply pipe 13, the output end of the single-chip microcomputer 20 is electrically connected with the input end of the wireless transceiver 7 in a bidirectional manner, one end of the wireless transceiver 7 is provided with a GPRS (general packet radio service (GPRS) 6) and one end of the GPRS 6) module 6 is electrically connected with the input end of the single-chip microcomputer 1, the input end of the device 3 is electrically connected with the device 1, the input end of the aerator 3 is provided with the input end of the device 3, the single-chip microcomputer 3 is electrically connected with the input end of the device 1, and the device 3 is provided with the input end of the device 3 is provided with the oxygen amplifier 3, and has the input end of the device 3 is electrically connected with the device 3, and has the device 3 has the device 3;

the inside of the collecting mechanism 2 is provided with a winding drum 201, a first rotating shaft 202, a rotating motor 203 and a recovery box 204, the top of the recovery box 204 is open, the top of the device body 1 is embedded with the rotating motor 203, the inner wall of one side of the recovery box 204 is provided with the rotating motor 203, the model of the rotating motor 203 is Y112M-3, the output end of the singlechip 20 is electrically connected with the input end of the rotating motor 203, the rotating motor 203 is provided with the first rotating shaft 202 through a coupling, one end of the first rotating shaft 202, which is far away from the rotating motor 203, is provided with the winding drum 201, and one end of the winding drum 201 is hinged with the inner wall of the recovery box 204; the take-up reel 201 is provided with a plurality of hooks.

The rotating motor 203 is turned on through the singlechip 20, the rotating motor 203 drives the first rotating shaft 202 to rotate, so that the winding drum 201 rotates, toxic substances, body particles and household garbage are rotationally crushed and wound on the surface of the winding drum 201 to be collected, and convenience is brought to the detection device in real-time detection;

the top of the outer side of the device body 1 at one side of the collecting mechanism 2 is provided with a solar panel 4, the output end of the solar panel 4 is electrically connected with the input end of the storage battery 5 through a photovoltaic controller, the bottom of the device body 1 at one side of the oxygen supply pipe 13, which is far away from the base 11, is fixedly provided with a resolver 14, the model of the resolver 14 is CSR-30, the input end of the singlechip 20 is electrically connected with the output end of the resolver 14, and the bottom of the device body 1 at one side of the resolver 14, which is far away from the oxygen supply pipe 13, is provided with a telescopic mechanism 19;

the inside of the telescopic mechanism 19 is provided with a lifting box 1901, a rack bar 1902, a gear 1903, an asynchronous motor 1904, a second rotating shaft 1905 and a limiting plate 1906, the bottom of the device body 1, which is far away from the oxygen supply pipe 13, of the analyzer 14 is provided with the lifting box 1901, the inner wall of one side of the lifting box 1901 is hinged with the gear 1903, the inner wall of one side of the gear 1903 is provided with the asynchronous motor 1904, the model of the asynchronous motor 1904 is DWT-1, the output end of the singlechip 20 is electrically connected with the input end of the asynchronous motor 1904, the output end of the asynchronous motor 1904 is provided with the second rotating shaft 1905 through a coupler, one end of the second rotating shaft 1905 is fixedly connected with the outer wall of the gear 1903, the lifting box 1901 on one side of the gear 1903 is internally provided with the rack bar 1902, the bottom end of the rack bar 1902 extends to the outside the device body 1, the rack bar 1902 is meshed with the gear 1903, the outer wall on one side of the rack bar is provided with the limiting plate 1906, and the top end of the limiting plate 1906 is fixedly connected with the top of the lifting box 1;

the single-chip microcomputer 20 is used for opening the kinetic energy motor 10, the kinetic energy motor 10 drives the third rotating shaft 8 to rotate, so that the propeller 9 is driven to rotate, then the single-chip microcomputer 20 is used for opening the asynchronous motor 1904, the asynchronous motor 1904 drives the second rotating shaft 1905 to rotate, so that the gear 1903 is driven to rotate, the rack bar 1902 is driven to move up and down, the data acquisition module 15 is driven to move along with the rack bar 1902 synchronously, the dissolved oxygen detection probe 16, the pH value probe 17 and the residual chlorine probe 18 are realized, the up-down movement of the probe detects the positions of different water areas, an analog signal is transmitted to the inside of the analyzer 14 to be analyzed, and the analyzer 14 feeds the data signal back to the inside of the single-chip microcomputer 20 to be analyzed, so that sampling detection is carried out on different water areas at different positions, and more accurate detection parameters are obtained;

the device comprises a device body 1, wherein a data acquisition module 15 is arranged below the device body 1, pH value probes 17 are arranged on two outer side walls of the data acquisition module 15, the type of each pH value probe 17 is XKT-40, the input end of a resolver 14 is electrically connected with the output end of each pH value probe 17, residual chlorine probes 18 are arranged on the outer walls of the data acquisition module 15 above the pH value probes 17, signals of the residual chlorine probes 18 are MC-10, the input end of the resolver 14 is electrically connected with the output end of the residual chlorine probes 18, dissolved oxygen detection probes 16 are arranged on the outer walls of the data acquisition module 15 below the pH value probes 17, the type of each dissolved oxygen detection probe 16 is XN-TX1, and the input end of the resolver 14 is electrically connected with the output end of each dissolved oxygen detection probe 16;

the parameters are detected by the dissolved oxygen detection probe 16, an analog signal is fed back to the analyzer 14, the analyzer 14 performs analysis and comparison, a data signal is transmitted to the singlechip 20, then the aerator 3 is opened by the singlechip 20, air is absorbed by the upper end of the aerator 3, oxygen is generated by the aerator 3, the oxygen is transmitted to the oxygen spraying head 12 by the oxygen supply pipe 13, sufficient oxygen is provided in the device body 1 by the oxygen spraying head 12, and the detected oxygen lack source is quickly repaired;

the outer wall of one side of the device body 1 is provided with a protective shell 21, the center position of the inner part of the protective shell 21 is provided with a contact sensor 23, the model of the contact sensor 23 is ZWY-0, the input end of the single chip microcomputer 20 is electrically connected with the output end of the contact sensor 23, the center position of the inner part of the contact sensor 23 is provided with a floating probe 22, the bottom end of the floating probe 22 extends to the outer part of the supporting rod 24, two groups of supporting rods 24 are arranged on the two outer side walls of the contact sensor 23, one end of the supporting rod 24 is fixedly connected with the inner wall of the protective shell 21, the inner wall of the device body 1 below the collecting mechanism 2 is provided with a single chip microcomputer 20, the model of the single chip microcomputer 20 is LHZ-5, the output end of the inner part of the single chip microcomputer 20 is electrically connected with the input ends of the GPRS module 6 and the kinetic energy motor 10, and the single chip microcomputer 20 is in bidirectional electrical connection with the wireless transceiver 7 and the GPRS module 6.

As shown in fig. 5, the output end inside the single-chip microcomputer 20 is in bidirectional telecommunication connection with the GPRS module 6 and the wireless transceiver 7, the single-chip microcomputer 20 is electrically connected with the input ends of the kinetic energy motor 10, the rotating motor 203, the asynchronous motor 1904 and the aerator 3, and the input end of the single-chip microcomputer 20 is also electrically connected with the output ends of the analyzer 14 and the contact sensor 23.

Working principle: when in use, the device is put into water by manpower, the solar panel 4 converts light energy into electric energy through solar irradiation, the electric energy is stored in the storage battery 5, the wireless transceiver 7 carries out remote receiving and transmission on external signals, the wireless transceiver 7 feeds back the signals to the inside of the single chip microcomputer 20 for analysis, the third rotating shaft 8 carries out real-time positioning on the device, the single chip microcomputer 20 turns on the kinetic energy motor 10, the kinetic energy motor 10 drives the third rotating shaft 8 to rotate, thereby driving the propeller 9 to rotate, then the single chip microcomputer 20 turns on the asynchronous motor 1904, the asynchronous motor 1904 drives the second rotating shaft 1905 to rotate, thereby driving the gear 1903 to rotate, and driving the rack bar 1902 to carry out up-down motion, the data acquisition module 15 carries out synchronous motion along with the rack bar 1902, thus realizing the up-down motion of the dissolved oxygen detection probe 16, the pH value probe 17 and the residual chlorine probe 18 to detect different water area positions, the analog signal is transmitted to the inside of the analyzer 14 for analysis, the analyzer 14 feeds back the data signal to the inside of the single chip microcomputer 20 for analysis, thus realizing sampling detection on different water areas at different positions, the single chip microcomputer 20 opens the rotary motor 203, the rotary motor 203 drives the first rotary shaft 202 to rotate, the winding drum 201 rotates, toxic substances, solid particles and household garbage are rotationally crushed and wound on the surface of the winding drum 201 for collection, the parameters are detected by the dissolved oxygen detection probe 16, the analog signal is fed back to the analyzer 14 and analyzed and compared by the analyzer 14, the data signal is transmitted to the single chip microcomputer 20, the aerator 3 is opened, the air is absorbed by the upper end of the aerator 3, oxygen is generated by the aerator 3, the oxygen is transmitted to the oxygen spraying head 12 by the oxygen supply pipe 13, the oxygen-spraying head 12 provides sufficient oxygen for the inside of the device body 1, the detected anoxic source is quickly repaired, the contact sensor 23 contacts the parameter change through the up-and-down floating of the floating probe 22, the analog signal is transmitted to the inside of the analyzer 14 for analysis, and the solar panel 4 feeds data back to the singlechip 20 for parameter comparison so as to monitor the water quantity and the water level in real time, thereby completing the use of the water quality comprehensive detection device.

The utility model brings the following effects:

(1) Through being provided with lift case, rack bar, gear, asynchronous motor, second pivot and limiting plate, open kinetic energy motor through the singlechip, it rotates to drive the screw rotation by kinetic energy motor drive third pivot, afterwards open asynchronous motor through the singlechip, it rotates to drive the second pivot by asynchronous motor, thereby drive the gear rotation, and drive the rack bar and carry out up-and-down motion, make data acquisition module follow the rack bar and carry out synchronous motion, realize dissolving oxygen detection probe, pH value probe, the up-and-down motion of residual chlorine probe detects different waters positions, and analyze with analog signal transmission to the inside of analysis appearance, with data signal feedback to the inside analysis of singlechip by the analysis appearance, thereby realize carrying out sample detection to different waters of different positions, obtain more accurate detection parameters.

(2) Through being provided with receipts reel, first pivot, rotating electrical machines and collection box, open the rotating electrical machines through the singlechip, drive first pivot by the rotating electrical machines and rotate, make a winding section of thick bamboo rotatory, rotatory stirring garrulous to toxic material, body granule, domestic waste, twine to a winding section of thick bamboo surface and collect to brought the convenience when real-time detection for detection device.

(3) The parameters are detected through the dissolved oxygen detection probe, the analog signals are fed back to the analyzer, the analyzer is used for analyzing and comparing, the data signals are transmitted to the singlechip, then the aerator is opened through the singlechip, air is absorbed by the upper end of the aerator, oxygen is generated through the aerator, the oxygen is transmitted to the oxygen spraying head through the oxygen supply pipe, sufficient oxygen is provided for the inside of the device body through the oxygen spraying head, and the detected anoxic source is quickly repaired.

The above-described embodiments are only for illustrating the technical spirit and features of the present utility model, and it is intended to enable those skilled in the art to understand the content of the present utility model and to implement it accordingly, and the scope of the present utility model is not limited to the embodiments, i.e. equivalent changes or modifications to the spirit of the present utility model are still within the scope of the present utility model.

Claims (7)

1. The utility model provides a comprehensive water yield and quality of water detection device, including device body (1), collection mechanism (2), oxygenation ware (3), oxygen supply tube (13), contact sensor (23), a serial communication port, install oxygen supply tube (13) in the central point department of device body (1) bottom, the bottom of oxygen supply tube (13) extends to the outside of device body (1), and be fixed with equidistant oxygen spraying head (12) below oxygen supply tube (13), device body (1) bottom in oxygen supply tube (13) one side is equipped with base (11), the central point department on base (11) top is fixed with kinetic energy motor (10), the output of kinetic energy motor (10) is installed third pivot (8) through the shaft coupling, outside device body (1) is stretched to third pivot (8), screw (9) are installed on the top, be fixed with wireless transceiver (7) on the device body (1) inner wall of kinetic energy motor (10) top, GPRS module (6) are installed to the one end of wireless transceiver (7), device body (1) top installation battery body (5) top above wireless transceiver (7), device body (1) top (5) are installed on top, oxygenation ware (3) one side is installed on top of device body (3) one side is installed to device (3), the device body (1) outside top of collection mechanism (2) one side is equipped with solar panel (4), the output of solar panel (4) is through the input electric connection of photovoltaic controller and battery (5), device body (1) bottom that base (11) one side was kept away from to oxygen supply tube (13) is fixed with analysis appearance (14), device body (1) bottom that oxygen supply tube (13) one side was kept away from to analysis appearance (14) is equipped with telescopic machanism (19), the below in device body (1) outside is equipped with data acquisition module (15), be equipped with protective housing (21) on the outer wall of device body (1) one side, the inside central point of protective housing (21) puts and is equipped with contact inductor (23), be equipped with singlechip (20) on the device body (1) inner wall of collection mechanism (2) below.

2. The comprehensive water quantity and water quality detection device according to claim 1, wherein the two outer side walls of the data acquisition module (15) are respectively provided with a pH value probe (17), a residual chlorine probe (18) and a dissolved oxygen detection probe (16), and data acquired by the data acquisition module (15) are uploaded to the analyzer (14).

3. The comprehensive water quantity and water quality detection device according to claim 1, wherein two groups of support rods (24) are arranged on two outer side walls of the contact sensor (23), the other ends of the support rods (24) are fixedly connected with the inner wall of the protective shell (21), a floating probe (22) is arranged at the central position inside the contact sensor (23), and the bottom ends of the floating probes (22) extend to the outside of the support rods (24).

4. The comprehensive water quantity and water quality detection device according to claim 1, wherein the collection mechanism (2) comprises a winding drum (201), a first rotating shaft (202), a rotating motor (203) and a recovery box (204), the top of the recovery box (204) is open, the top of the device body (1) is embedded, the rotating motor (203) is arranged on the inner wall of one side of the recovery box (204), the rotating motor (203) is provided with the first rotating shaft (202) through a coupling, one end, far away from the rotating motor (203), of the first rotating shaft (202) is provided with the winding drum (201), one end of the winding drum (201) is hinged with the inner wall of the recovery box (204), and the winding drum (201) is provided with a plurality of hooks.

5. The comprehensive water quantity and water quality detection device according to claim 1, wherein the telescopic mechanism (19) comprises a lifting box (1901), a rack bar (1902), a gear (1903), an asynchronous motor (1904), a second rotating shaft (1905) and a limiting plate (1906), the lifting box (1901) is arranged at the bottom of the device body (1) on one side, far away from the oxygen supply pipe (13), of the analyzer (14), the gear (1903) is hinged on the inner wall on one side of the lifting box (1901), and the asynchronous motor (1904) is arranged on the inner wall of the lifting box (1901) on one side of the gear (1903).

6. The comprehensive water quantity and water quality detection device according to claim 5, wherein the output end of the asynchronous motor (1904) is provided with a second rotating shaft (1905) through a coupler, one end of the second rotating shaft (1905) is fixedly connected with the outer wall of the gear (1903), a rack bar (1902) is arranged in a lifting box (1901) on one side of the gear (1903), the bottom end of the rack bar (1902) extends to the outside of the device body (1), the rack bar (1902) is meshed with the gear (1903), a limiting plate (1906) is arranged on the outer wall on one side of the rack bar (1902), and the top end of the limiting plate (1906) is fixedly connected with the top of the lifting box (1901).

7. The water quantity and water quality comprehensive detection device according to any one of claims 1-6, wherein an output end inside the single chip microcomputer (20) is electrically connected with the GPRS module (6) and the wireless transceiver (7) in a bidirectional manner, the single chip microcomputer (20) is electrically connected with input ends of the kinetic energy motor (10), the rotating motor (203), the asynchronous motor (1904) and the aerator (3), and an input end of the single chip microcomputer (20) is also electrically connected with output ends of the analyzer (14) and the contact sensor (23).