CN113073711A - Secondary water supply system and method based on big data - Google Patents

Abstract

The invention relates to a water supply system, in particular to a secondary water supply system and a secondary water supply method based on big data, wherein the secondary water supply method based on big data comprises the following steps of S1: injecting water into the water storage tank I, wherein when the water storage tank I is injected with water, the air duct is opened, and the water outlet duct I is closed; s2: after water is injected into the water storage tank I to a certain degree, the pushing column is inserted into the one-way mechanism III, the one-way mechanism III is opened, and the connecting pipeline II and the connecting pipeline I are communicated with the water storage tank II for water injection; s3: after the water storage tank I and the water storage tank I are filled, starting an air pump to pressurize the water storage tank I and the water storage tank I, and opening a one-way mechanism IV and the one-way mechanism I to drain water; the pressurizing mechanism extrudes the auxiliary water storage mechanism and the water storage mechanism, so that water in the auxiliary water storage mechanism and the water storage mechanism is discharged under certain pressure, and the control mechanism controls the water yield and the water storage amount according to the supply time and the water consumption of water every day.

Description

Secondary water supply system and method based on big data

Technical Field

The invention relates to a water supply system, in particular to a secondary water supply system and a secondary water supply method based on big data.

Background

A water supply system is known at present, which comprises a control unit and a plurality of sub water supply systems, wherein the plurality of sub water supply systems are connected in sequence; the sub-water supply system comprises a water inlet pool and a water suction pump, the water suction pump comprises a water inlet end and a water outlet end, and the water inlet end is connected with the water inlet pool; the connection of the sub water supply system and the sub water supply system is as follows: the water outlet end of the water suction pump of the sub-water supply system is connected with the water inlet pool of the other sub-water supply system; the water suction pump is connected with the control unit; the disadvantage of this water supply system is that the water storage tank cannot be pressurized.

Disclosure of Invention

The invention aims to provide a secondary water supply system and a secondary water supply method based on big data, which can pressurize a water storage tank.

The purpose of the invention is realized by the following technical scheme:

a secondary water supply system based on big data comprises a water storage mechanism, a pressurizing mechanism, a mounting bracket, a moving mechanism, an auxiliary water storage mechanism and a control mechanism, wherein the water storage mechanism comprises a water storage tank I and a connecting pipeline I, the water injection device comprises a water injection pipeline, a water injection pump, a water outlet pipeline I, a one-way mechanism I, a suction block I and an electromagnet I, wherein the water storage tank I is fixedly connected with a connecting pipeline I, the connecting pipeline I is communicated with the water storage tank I, the water storage tank I is fixedly connected with the water injection pipeline, the water injection pipeline is communicated with the water storage tank I, the water injection pump is connected onto the water injection pipeline, the bottom of the water storage tank I is fixedly connected with the water outlet pipeline I, the water outlet pipeline I is communicated with the water storage tank I, the one-way mechanism I is arranged in the water outlet pipeline I, the suction block I is fixedly connected onto the one-way mechanism I, the suction block I can be adsorbed onto the electromagnet I, the;

the pressurizing mechanism comprises a one-way mechanism II, a suction block II, an electromagnet II, a pressurizing pipeline and an air pump, the upper end of the water storage tank I is provided with a vent pipeline, the vent pipeline is internally provided with the one-way mechanism II, the suction block II is fixedly connected to the one-way mechanism II and can be adsorbed on the electromagnet II, the electromagnet II is fixedly connected to the water injection pipeline, the water storage tank I is fixedly connected with the pressurizing pipeline, the pressurizing pipeline is connected with the air pump, and the pressurizing pipeline is communicated with the water storage tank I;

the moving mechanism comprises a telescopic mechanism I, a moving support and moving wheels, the telescopic mechanism I is fixedly connected to the water storage tank I, the telescopic end of the telescopic mechanism I is fixedly connected with the moving support, and the lower end of the moving support is provided with four moving wheels;

the auxiliary water storage mechanism comprises a water storage tank II, a connecting pipeline II, a push column, a one-way mechanism III, a water outlet pipeline II, a one-way mechanism IV, a suction block III and an electromagnet III, the water storage tank II is fixedly connected to the movable support, the connecting pipeline II is fixedly connected to the water storage tank II and is communicated with the water storage tank II, the push column is fixedly connected to the inside of the connecting pipeline II, the one-way mechanism III is arranged in the connecting pipeline I, the connecting pipeline II is slidably connected to the inside of the connecting pipeline I, the push column is abutted to the one-way mechanism III, the lower end of the water storage tank II is fixedly connected with the water outlet pipeline II, the water outlet pipeline II is connected with the water outlet pipeline I through a hose, the one-way mechanism IV is arranged in the water outlet pipeline II, the suction block III is fixedly connected to the one-way mechanism IV;

control mechanism includes the support ring, the axis of rotation, telescopic machanism II, a sensor, circular arc board and locking screw, the support ring is provided with six, the equal fixed connection of six support rings is on the installing support, it is connected with the axis of rotation to rotate on the installing support, it can drive the axis of rotation and carry out pivoted power unit to be provided with in the axis of rotation, six telescopic machanism II of fixedly connected with in the axis of rotation, equal fixedly connected with sensor on the flexible end of six telescopic machanism II, equal sliding connection has two circular arc boards on six support rings, all there is locking screw through threaded connection on every circular arc board, the sensor can contact with two circular arc boards that correspond, the water injection pump, the air pump, electro-magnet I, electro-magnet.

A secondary water supply method based on big data comprises the following steps:

s1: injecting water into the water storage tank I, wherein when the water storage tank I is injected with water, the air duct is opened, and the water outlet duct I is closed;

s2: after water is injected into the water storage tank I to a certain degree, the pushing column is inserted into the one-way mechanism III, the one-way mechanism III is opened, and the connecting pipeline II and the connecting pipeline I are communicated with the water storage tank II for water injection;

s3: after water storage tank I and water storage tank I were all annotated, start the air pump and pressurize water storage tank I and water storage tank I, open I drainage of unidirectional mechanism IV and unidirectional mechanism.

The secondary water supply system and method based on big data have the beneficial effects that:

the invention relates to a big data based secondary water supply system and a method, which can store water through a water storage mechanism, when the water in the water storage mechanism is stored to a certain degree, the auxiliary water storage mechanism is communicated with the water storage mechanism to start water storage, after the storage of the auxiliary water storage mechanism and the water storage mechanism is finished, and when the water in the auxiliary water storage mechanism and the water storage mechanism needs to be used, a pressurizing mechanism extrudes the auxiliary water storage mechanism and the water storage mechanism to discharge the water in the auxiliary water storage mechanism and the water storage mechanism under a certain pressure, and meanwhile, a control mechanism which controls a device to work circularly according to big data is also arranged, and the control mechanism controls the water yield and the water storage quantity according to the supply time and the water consumption of water in each day.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

FIG. 1 is a schematic view of the connection structure of a water storage mechanism and a pressurizing mechanism of the present invention;

FIG. 2 is a schematic view showing a sectional structure of the water storage mechanism and the pressurizing mechanism according to the present invention;

FIG. 3 is a schematic view of the connection structure of the water storage mechanism and the mounting bracket of the present invention;

FIG. 4 is a schematic view of a cross-sectional view of the water storage mechanism and mounting bracket of the present invention;

FIG. 5 is a schematic view of the connection structure of the water storage mechanism and the moving mechanism of the present invention;

FIG. 6 is a schematic view of the connection structure of the water storage mechanism, the moving mechanism and the auxiliary water storage mechanism of the present invention;

FIG. 7 is a schematic view showing a cross-sectional structure of the connection of the water storage mechanism, the moving mechanism and the sub water storage mechanism according to the present invention;

FIG. 8 is a schematic view of the connection between the secondary water storage mechanism and the hose of the present invention;

FIG. 9 is a schematic view of a cross-sectional view of the connection between the secondary water storage mechanism and the hose of the present invention;

FIG. 10 is a schematic view of the connection of the water storage mechanism, mounting bracket and control mechanism of the present invention;

FIG. 11 is a schematic view of the connection of the water storage mechanism, mounting bracket and control mechanism of the present invention;

FIG. 12 is a schematic view of the control mechanism of the present invention;

FIG. 13 is a schematic view of the connection structure of the one-way mechanism II and the adsorption block II.

In the figure:

a water storage tank I11;

a connecting pipeline I12;

a water injection pipe 13;

a water injection pump 14;

a water outlet pipeline I15;

a one-way mechanism I16;

a suction block I17;

an electromagnet I18;

a one-way mechanism II 21;

a one-way plate I211;

a one-way plate II 212;

sliding 213;

a tapered block 214;

a suction block II 22;

an electromagnet II 23;

a pressurized conduit 24;

an air pump 25;

a mounting bracket 30;

a telescoping mechanism I41;

the moving bracket 42;

a moving wheel 43;

a water storage tank II 51;

a connecting pipe II 52;

a push post 53;

a one-way mechanism III 54;

a water outlet pipeline II 55;

a one-way mechanism IV 56;

a suction block III 57;

an electromagnet III 58;

a hose 60;

a support ring 71;

a rotating shaft 72;

a telescoping mechanism II 73;

a sensor 74;

an arc plate 75;

the screws 76 are locked.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The embodiment is described below with reference to fig. 1 to 9, and a secondary water supply system based on big data comprises a water storage mechanism, a pressurizing mechanism, a mounting bracket 30, a moving mechanism, a secondary water storage mechanism and a control mechanism, wherein the water storage mechanism comprises a water storage tank I11, a connecting pipeline I12, a water injection pipeline 13, a water injection pump 14, a water outlet pipeline I15, a one-way mechanism I16, a suction block I17 and an electromagnet I18, the water storage tank I11 is fixedly connected with the connecting pipeline I12, the connecting pipeline I12 is communicated with the water storage tank I11, the water storage tank I11 is fixedly connected with the water injection pipeline 13, the water injection pipeline 13 is communicated with the water storage tank I11, the water injection pipeline 13 is connected with the water injection pump 14, the bottom of the water storage tank I11 is fixedly connected with the water outlet pipeline I15, the water outlet pipeline I15 is communicated with the water storage tank I11, the one-way mechanism I16 is arranged, the suction block I17 can be adsorbed on the electromagnet I18, the electromagnet I18 is fixedly connected to the mounting bracket 30, and the water storage tank I11 is fixedly connected to the mounting bracket 30;

the pressurizing mechanism comprises a one-way mechanism II 21, a suction block II 22, an electromagnet II 23, a pressurizing pipeline 24 and an air pump 25, a vent pipeline is arranged at the upper end of the water storage tank I11, the one-way mechanism II 21 is arranged in the vent pipeline, the suction block II 22 is fixedly connected to the one-way mechanism II 21, the suction block II 22 can be adsorbed on the electromagnet II 23, the electromagnet II 23 is fixedly connected to the water injection pipeline 13, the pressurizing pipeline 24 is fixedly connected to the water storage tank I11, the pressurizing pipeline 24 is connected to the pressurizing pipeline 24, and the pressurizing pipeline 24 is communicated with the water storage tank I11;

the moving mechanism comprises a telescopic mechanism I41, a moving support 42 and moving wheels 43, the telescopic mechanism I41 is fixedly connected to the water storage tank I11, the telescopic end of the telescopic mechanism I41 is fixedly connected with the moving support 42, and the lower end of the moving support 42 is provided with the four moving wheels 43;

the auxiliary water storage mechanism comprises a water storage tank II 51, a connecting pipeline II 52, a push column 53, a one-way mechanism III 54, a water outlet pipeline II 55, a one-way mechanism IV 56, a suction block III 57 and an electromagnet III 58, the water storage tank II 51 is fixedly connected to the movable support 42, the connecting pipeline II 52 is fixedly connected to the water storage tank II 51, the connecting pipeline II 52 is communicated with the water storage tank II 51, the push column 53 is fixedly connected to the inside of the connecting pipeline II 52, the one-way mechanism III 54 is arranged in the connecting pipeline I12, the connecting pipeline II 52 is slidably connected to the inside of the connecting pipeline I12, the push column 53 is abutted against the one-way mechanism III 54, the water outlet pipeline II 55 is fixedly connected to the lower end of the water storage tank II 51, the water outlet pipeline II 55 is connected to the water outlet pipeline I15 through a hose, the one-way mechanism IV 56 is arranged in the water outlet pipeline II 55, the suction block III 57 is, the electromagnet III 58 is fixedly connected to the movable bracket 42;

when in use, the water injection pipeline 13 is connected with the water supply pipeline, the electromagnet I18 is electrified, the electromagnet I18 adsorbs the suction block I17, the suction block I17 drives the one-way mechanism I16 to move, the one-way mechanism I16 is closed, the water outlet pipeline I15 is closed, the electromagnet II 23 is disconnected, the electromagnet II 23 is not electrified, the structure of the one-way mechanism II 21 is illustrated by using the drawing 13, the structure of the one-way mechanism II 21 is the same as that of the one-way mechanism I21, the one-way mechanism I16, the one-way mechanism III 54 and the one-way mechanism IV 56, the one-way mechanism II 21 comprises a one-way plate I211, a one-way plate II 212, a sliding block 213 and a conical block 214, a plurality of through holes are arranged on the one-way plate I211, a conical hole is arranged on the one-way plate II 212, the sliding block I211 is connected with the sliding block 213 in a, when the electromagnet II 23 does not attract the attraction block II 22, the extension spring pulls the conical block 214 to move downwards, the conical block 214 does not abut against the one-way plate II 212 to be arranged in a conical hole, when the electromagnet II 23 is electrified, the electromagnet II 23 generates certain magnetic force, the electromagnet II 23 adsorbs the attraction block II 22, the attraction block II 22 drives the conical block 214 to move upwards, the conical block 214 abuts against the one-way plate II 212 to be arranged in the conical hole, the one-way mechanism II 21 is further closed, the one-way mechanism I16, the one-way mechanism III 54 and the one-way mechanism IV 56 are also similar, and the attraction block I17, the attraction block II 22 and the attraction block III 57 can be iron objects;

an air duct is arranged at the upper end of the water storage tank I11, an one-way mechanism II 21 is arranged in the air duct, an one-way mechanism I16 is closed, an one-way mechanism II 21 is opened, a water outlet duct I15 is closed, the air duct is opened, a water injection pump 14 is started, the water injection pump 14 pumps water into a water injection duct 13, the water injection duct 13 pumps water into the water storage tank I11, when the water in the water storage tank I11 reaches a certain degree, a telescopic mechanism I41 is started, the telescopic mechanism I41 and a telescopic mechanism II 73 can be hydraulic cylinders or electric push rods, the telescopic end of the telescopic mechanism I41 drives a movable support 42 to move, the movable support 42 drives a movable wheel 43 to move, the movable wheel 43 reduces the resistance of the movement of the movable support 42, the movable support 42 drives an auxiliary water storage mechanism to move, the movable support 42 drives a water storage tank II 51 to move, the water storage tank II 51, the connecting pipeline II 52 drives the pushing column 53 to move, the pushing column 53 abuts against the one-way mechanism III 54, the one-way mechanism III 54 is opened, the connecting pipeline II 52 is communicated with the connecting pipeline I12, water in the connecting pipeline I12 is introduced into the water storage tank II 51 through the connecting pipeline II 52, the electromagnet III 58 is started in advance, the electromagnet III 58 is electrified, the electromagnet III 58 adsorbs the suction block III 57, the suction block III 57 closes the one-way mechanism IV 56, the water outlet pipeline II 55 is closed, and water is stored in the water storage tank I11 and the water storage tank II 51;

when needing to use the water in I11 of water storage tank and the II 51 of water storage tank, the circular telegram of II 23 of electro-magnet, II 23 of electro-magnet adsorbs piece II 22, II 21 closure of unidirectional mechanism, the breather pipe is closed, start air pump 25, air pump 25 is with in the air suction I11 of water storage tank, I11 of water storage tank and II 51 of water storage tank communicate, the pressure increase in I11 of water storage tank and the II 51 of water storage tank, when the pressure in I11 of water storage tank and the II 51 of water storage tank increases to appointed degree, disconnection electro-magnet I18 and electro-magnet III 58 for I16 of unidirectional mechanism and unidirectional mechanism IV 56 open, outlet conduit I15 and outlet conduit II 55 open, outside carries out the drainage.

Referring to fig. 1 to 13, the control mechanism includes six support rings 71, six rotation shafts 72, six telescoping mechanisms ii 73, sensors 74, arc plates 75 and locking screws 76, the support rings 71 are all fixedly connected to the mounting bracket 30, the mounting bracket 30 is rotatably connected to the rotation shafts 72, the rotation shafts 72 are provided with power mechanisms capable of driving the rotation shafts 72 to rotate, the rotation shafts 72 are fixedly connected to the six telescoping mechanisms ii 73, the sensors 74 are all fixedly connected to the telescoping ends of the six telescoping mechanisms ii 73, the six support rings 71 are all slidably connected to the two arc plates 75, each arc plate 75 is connected to a locking screw 76 through a thread, the sensors 74 can contact with the corresponding two arc plates 75, the water injection pump 14, the air pump 25, the electromagnet I18, the electromagnet II 23, the telescopic mechanism I41 and the electromagnet III 58 are respectively connected with six sensors 74;

the water supply device is further provided with a control mechanism, the rotating shaft 72 is provided with a power mechanism capable of driving the rotating shaft 72 to rotate, the power mechanism can be a motor or a servo motor, it needs to be noted that the power mechanism is connected with the rotating shaft 72 through a speed reducing mechanism, so that in the time of one water supply cycle, the rotating shaft 72 does not rotate for one circle and is correspondingly connected with one water supply cycle, the rotating speed of the rotating shaft 72 needs to be reasonably set, the corresponding power mechanism needs to be reasonably set to be connected with the transmission ratio between the rotating shafts 72 through the speed reducing mechanism, and the technical personnel in the field can set the power mechanism according to the use requirements;

the water injection pump 14, the air pump 25, the electromagnet I18, the electromagnet II 23, the telescopic mechanism I41 and the electromagnet III 58 are connected with six sensors 74 respectively in advance, the sensors 74 can be contact sensors or extrusion sensors, the water injection pump 14 is started when the sensor 74 corresponding to the water injection pump 14 is extruded, the air pump 25 is started when the sensor 74 corresponding to the air pump 25 is extruded, the electromagnet I18 is electrified when the sensor 74 corresponding to the electromagnet I18 is extruded, the electromagnet II 23 is electrified when the sensor 74 corresponding to the electromagnet II 23 is extruded, the electromagnet III 58 is electrified when the sensor 74 corresponding to the electromagnet III 58 is extruded, the telescopic end of the telescopic mechanism I41 is retracted when the sensor 74 corresponding to the telescopic mechanism I41 is extruded, and the technical personnel in the field can set and connect the sensors according to an electric control means in the prior art;

the positions of the two arc plates 75 on each support ring 71 are adjusted in advance according to use requirements, the positions of the two arc plates 75 on each support ring 71 are adjusted according to different use requirements, the two arc plates 75 on each support ring 71 can extrude the corresponding sensor 74, and then the corresponding water injection pump 14, air pump 25, electromagnet I18, electromagnet II 23, telescopic mechanism I41 and electromagnet III 58 are controlled, and further the water injection pump 14, air pump 25, electromagnet I18, electromagnet II 23, telescopic mechanism I41 and electromagnet III 58 are adjusted according to the starting time of the water injection pump 14, air pump 25, electromagnet I18, electromagnet II 23, telescopic mechanism I41 and electromagnet III 58, the starting time of the two arc plates 75 on the whole can be adjusted by adjusting the positions of the two arc plates 75 on the whole to adjust the starting time of the water injection pump 14, air pump 25, electromagnet I18, electromagnet II 23, telescopic mechanism I41 and electromagnet III, the time for starting the water injection pump 14, the air pump 25, the electromagnet I18, the electromagnet II 23, the telescopic mechanism I41 and the electromagnet III 58 each time can be adjusted, the positions of the two arc plates 75 on each support ring 71 are adjusted according to the starting sequence and the use requirements of the water injection pump 14, the air pump 25, the electromagnet I18, the electromagnet II 23, the telescopic mechanism I41 and the electromagnet III 58 in the previous embodiment, and the positions of the arc plates 75 can be fixed by rotating the locking screws 76;

analyzing according to the big data, analyzing the time for supplying water, the amount of water supplied and discharged each time, the pressure required for supplying water, and the time for communicating the water storage mechanism with the auxiliary water storage mechanism, adjusting the positions of the two arc plates 75 on each support ring 71, and further completing the specified setting of water supply to meet different environments and use requirements;

when the rotating shaft 72 rotates, the second telescopic mechanism 73 starts to rotate, the second telescopic mechanism 73 drives the sensor 74 to move, the six sensors 74 respectively pass through the two corresponding arc plates 75, the arc plates 75 extrude the sensor 74 at different positions and at different time, meanwhile, the arc plates 75 can be set to be different types, or two arc plates 75 can form a path for extruding the sensor 74, so that the time for extruding the sensor 74 can be adjusted according to the use requirement, the starting sequence and the starting time of the water injection pump 14, the air pump 25, the electromagnet I18, the electromagnet II 23, the first telescopic mechanism I41 and the electromagnet III 58 are controlled, the big data specialization of water supply is completed, and different environments and use requirements are met; every time the axis of rotation 72 rotates the circulation that once supplies water, start II 73 telescopic machanism simultaneously and can adjust that sensor 74 not receive the extrusion, and then can be applicable to more applicable demands, if do not need vice water storage mechanism and water storage mechanism intercommunication, then start II 73 telescopic machanism that I41 of telescopic machanism corresponds sensor 74 for sensor 74 does not receive the extrusion, and then makes and does not have vice water storage mechanism and water storage mechanism intercommunication in whole water supply circulation.

A secondary water supply method based on big data comprises the following steps:

s1: injecting water into the water storage tank I11, wherein when the water storage tank I11 is injected with water, the air duct is opened, and the water outlet duct I15 is closed;

s2: after water is injected into the water storage tank I11 to a certain degree, the push column 53 is inserted into the one-way mechanism III 54, the one-way mechanism III 54 is opened, and the connecting pipeline II 52 and the connecting pipeline I12 are communicated with the water storage tank II 51 for water injection;

s3: after I11 and I11 equal notes of water storage tank were filled, start air pump 25 and pressurize I11 and I11 of water storage tank, open the drainage of isolator mechanism IV 56 and isolator mechanism I16.

Claims (10)

1. The utility model provides a based on big data secondary water supply system, includes water storage tank I (11), pressurization pipeline (24) and air pump (25), its characterized in that: be connected with on water storage tank I (11) and be used for carrying out the pressurized pipeline (24) to water storage tank I (11), be connected with air pump (25) on pressurized pipeline (24).

2. The big data based secondary water supply system according to claim 1, wherein: the water storage tank I (11) is characterized by further comprising a mounting bracket (30) used for supporting the water storage tank I (11).

3. The big data based secondary water supply system according to claim 1, wherein: fixedly connected with water injection pipeline (13) on water storage tank I (11), be connected with water injection pump (14) on water injection pipeline (13).

4. The big data based secondary water supply system according to claim 3, wherein: the bottom fixedly connected with outlet conduit I (15) of water storage tank I (11), be provided with one-way mechanism I (16) in outlet conduit I (15), fixedly connected with inhales piece I (17) on one-way mechanism I (16), fixedly connected with is used for adsorbing I (18) electro-magnet of inhaling piece I (17) on installing support (30).

5. The big data based secondary water supply system according to claim 4, wherein: the upper end of water storage tank I (11) is provided with the air duct, is provided with one-way mechanism II (21) in the air duct, and fixedly connected with inhales piece II (22) on one-way mechanism II (21), and fixedly connected with is used for adsorbing and inhales electro-magnet II (23) of piece II (22) on water injection pipeline (13).

6. The big data based secondary water supply system according to claim 5, wherein: fixedly connected with telescopic machanism I (41) on water storage tank I (11), fixedly connected with movable support (42) are served in the flexible of telescopic machanism I (41), and the lower extreme of movable support (42) is provided with four and removes wheel (43).

7. The big data based secondary water supply system according to claim 6, wherein: fixedly connected with connecting tube I (12) on water storage tank I (11), sliding connection has vice water storage mechanism on connecting tube I (12), and vice water storage mechanism fixed connection is on removing support (42).

8. The big data based secondary water supply system according to claim 7, wherein: the auxiliary water storage mechanism comprises a water storage tank II (51), a connecting pipeline II (52) is fixedly connected onto the water storage tank II (51), a pushing column (53) is fixedly connected into the connecting pipeline II (52), a one-way mechanism III (54) is arranged in the connecting pipeline I (12), the connecting pipeline II (52) is slidably connected into the connecting pipeline I (12), and the pushing column (53) is pushed against the one-way mechanism III (54).

9. The big data based secondary water supply system according to claim 8, wherein: the lower extreme fixedly connected with outlet conduit II (55) of water storage tank II (51), be provided with one-way mechanism IV (56) in outlet conduit II (55), fixedly connected with inhales piece III (57) on one-way mechanism IV (56), and fixedly connected with is used for adsorbing electromagnet III (58) of inhaling piece III (57) on movable support (42).

10. The method for supplying water based on big data secondary water supply system according to claim 9, wherein: the method comprises the following steps:

s1: injecting water into the water storage tank I (11), wherein when the water storage tank I (11) is injected with water, the air duct is opened, and the water outlet duct I (15) is closed;

s2: after water is injected into the water storage tank I (11) to a certain degree, the push column (53) is inserted into the one-way mechanism III (54), the one-way mechanism III (54) is opened, and the connecting pipeline II (52) and the connecting pipeline I (12) are communicated with the water storage tank II (51) for water injection;

s3: after the water storage tank I (11) and the water storage tank I (11) are filled, the air pump (25) is started to pressurize the water storage tank I (11) and the water storage tank I (11), and the one-way mechanism IV (56) and the one-way mechanism I (16) are opened to drain.

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