CN113134260A

CN113134260A - Multifunctional intelligent purification system and method for secondary water supply

Info

Publication number: CN113134260A
Application number: CN202110441140.2A
Authority: CN
Inventors: 张志蓉
Original assignee: Individual
Current assignee: Shanghai Taipuke Technology Co ltd
Priority date: 2021-04-23
Filing date: 2021-04-23
Publication date: 2021-07-20
Anticipated expiration: 2041-04-23
Also published as: CN113134260B

Abstract

The invention relates to a purification system, in particular to a multifunctional intelligent purification system and a method for secondary water supply, which comprises a purification mechanism, a mounting bracket, a sensor A, a sensor B, a ventilation mechanism, a water outlet mechanism, a water supply mechanism, an inflating mechanism and a control mechanism, wherein the multifunctional intelligent purification method for secondary water supply comprises the following steps: s1: when the control mechanism is contacted with the sensor A, the control mechanism is contacted with the stop bracket, and the sensor A controls the water supply mechanism to introduce a specified amount of water into the purification mechanism; s2: when the control mechanism moves and contacts with the sensor B, the control mechanism contacts with the one-way sliding block I, and the sensor B controls the inflating mechanism to introduce a specified amount of air into the purifying mechanism twice; s3: the air pressure in the purification mechanism is increased, the water outlet mechanism is opened, and the water in the purification mechanism is filtered and discharged through the filter plate twice.

Description

Multifunctional intelligent purification system and method for secondary water supply

Technical Field

The invention relates to a purification system, in particular to a multifunctional intelligent purification system and method for secondary water supply.

Background

The currently known comprehensive wastewater purification system comprises a purification tower, an atomizer and an ozone machine, wherein a wastewater inlet is formed in the side wall of the upper part of the purification tower, and a slow flow layer, a diversion layer and an adsorption layer are sequentially arranged inside the purification tower from top to bottom; the slow flow layer is of a single-layer flat plate structure and is positioned below the wastewater inlet; a plurality of through holes are formed in one end, far away from the wastewater inlet, of the single-layer flat plate structure; the flow guide layer consists of a plurality of layers of inclined guide plates; the surface of the flow guide plate is provided with a grating structure; the surface of the grating structure is provided with a porous membrane; the nozzle of the atomizer is positioned in the purification tower and below the flow guide layer; the adsorption layer consists of two layers of quartz sand filter screens; an ozone inlet connected with an ozone machine is arranged between the two quartz sand filter screens; the bottom end of the purifying tower is provided with a fluid outlet; the disadvantage of this invention is that it is inconvenient to replace the filter plate.

Disclosure of Invention

The invention aims to provide a multifunctional intelligent purification system and method for secondary water supply, which can be used for conveniently replacing a filter plate.

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

a multifunctional intelligent purification system for secondary water supply comprises a purification mechanism, a mounting bracket, a sensor A, a sensor B, a ventilation mechanism, a water outlet mechanism, a water supply mechanism, an inflating mechanism and a control mechanism, wherein the purification mechanism comprises a filter cylinder, feeding pipelines, connecting pipelines, a mounting box and a filter plate;

the ventilation mechanism comprises a ventilation cover plate, a ventilation pipeline, a ventilation plate I, a one-way sliding block I and a ventilation plate II, wherein the ventilation pipeline is fixedly connected to the ventilation cover plate, the ventilation cover plate is fixedly connected to the installation box, the ventilation cover plate covers the filter cartridge, the ventilation pipeline is communicated with the filter cartridge, the ventilation plate I is fixedly connected to the inside of the ventilation pipeline, a conical hole I is formed in the ventilation plate I, the ventilation plate II is fixedly connected to the inside of the ventilation pipeline, the one-way sliding block I is connected to the upper side of the ventilation plate II in a sliding mode, the one-way sliding block I is supported in the conical hole I in the ventilation plate I, and a compression spring I is fixedly connected between the one-way sliding block I and the ventilation plate II;

the water outlet mechanism comprises a water outlet bottom plate, a one-way sliding block II and a stop support, the water outlet bottom plate is fixedly connected in the filter cylinder, a round through hole is formed in the water bottom plate, the one-way sliding block II is connected to the water bottom plate in a sliding mode, a compression spring II is fixedly connected between the one-way sliding block II and the water bottom plate, the lower end of the one-way sliding block II is in contact with the stop support, the stop support is connected to the mounting support in a sliding mode, a compression spring III is fixedly connected between the stop support and the mounting support, a conical hole II is formed in the bottom of the mounting box, and the upper end of the one-way sliding block II abuts against the inside of the conical hole II;

the water supply mechanism comprises a telescopic mechanism I, a pushing plate I, a one-way mechanism I and a one-way mechanism II, the telescopic mechanism I is fixedly connected to the feeding pipeline on the right side, the telescopic end of the telescopic mechanism I is fixedly connected with the pushing plate I, the pushing plate I is slidably connected into the feeding pipeline on the right side, the one-way mechanism II is arranged in the feeding pipeline on the right side, and the one-way mechanism I is arranged in the connecting pipeline on the right side;

the inflating mechanism comprises a telescopic mechanism II, a pushing plate II, a one-way mechanism III and a one-way mechanism IV, the telescopic mechanism II is fixedly connected to the left feeding pipeline, the telescopic end of the telescopic mechanism II is fixedly connected with the pushing plate II, the pushing plate II is slidably connected into the left feeding pipeline, the one-way mechanism IV is arranged in the left feeding pipeline, and the one-way mechanism III is arranged in the left connecting pipeline;

the control mechanism comprises a stop cam I, a stop cam II, a transmission shaft I, an arc cam I, a transmission shaft II and an arc cam II, wherein the stop cam I is rotatably connected to the upper side of the mounting bracket, the stop cam II is rotatably connected to the lower side of the mounting bracket, half-ring bulges are respectively arranged on the stop cam I and the stop cam II, the bulges on the stop cam I can be contacted with a one-way sliding block I, the bulges on the stop cam II can be contacted with the stop bracket, the left side of the mounting bracket is rotatably connected with the transmission shaft I, the transmission shaft I is rotatably connected with two arc cams I, the two arc cams I are respectively connected with a positioning nail I through threads, the two arc cams I can be contacted with a sensor A, the right side of the mounting bracket is rotatably connected with the transmission shaft II, the transmission shaft II is rotatably connected with two arc cams II, and the two arc cams II are provided with different models, the two arc cams II are different in model, the two arc cams II are connected with positioning nails II through threads, the two arc cams II can be contacted with a sensor B, the stop cam I, the stop cam II, the transmission shaft I and the transmission shaft II are in transmission connection, and the transmission ratio among the stop cam I, the stop cam II, the transmission shaft I and the transmission shaft II is one;

the sensor A is connected with the telescopic mechanism I, the sensor B is connected with the telescopic mechanism II, and the telescopic end movement speeds of the telescopic mechanism I and the telescopic mechanism II are the same.

A multifunctional intelligent purification method for secondary water supply comprises the following steps:

s1: when the control mechanism is contacted with the sensor A, the control mechanism is contacted with the stop bracket, and the sensor A controls the water supply mechanism to introduce a specified amount of water into the purification mechanism;

s2: when the control mechanism moves and contacts with the sensor B, the control mechanism contacts with the one-way sliding block I, and the sensor B controls the inflating mechanism to introduce a specified amount of air into the purifying mechanism twice;

s3: the air pressure in the purification mechanism is increased, the water outlet mechanism is opened, and the water in the purification mechanism is filtered and discharged through the filter plate twice.

The multifunctional intelligent purification system and method for secondary water supply have the beneficial effects that:

the invention relates to a multifunctional intelligent purification system and a method for secondary water supply, which can contact a control mechanism and a sensor A, and simultaneously contact the control mechanism and a stop bracket, wherein the sensor A controls a water supply mechanism to introduce a specified amount of water into a purification mechanism; when control mechanism motion and sensor B contact, control mechanism and I contact of one-way slider, sensor B control mechanism of inflating divides twice to let in appointed volume gas in the purification mechanism: the air pressure in the purification mechanism is increased, the water outlet mechanism is opened, and the water in the purification mechanism is filtered and discharged through the filter plate twice.

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 purification mechanism of the present invention;

FIG. 2 is a schematic view of the connection structure of the purification mechanism, the mounting bracket, the sensor A and the sensor B of the present invention;

FIG. 3 is a schematic view of the connection structure of the purification mechanism, the aeration mechanism and the water outlet mechanism of the present invention;

FIG. 4 is a schematic structural view of a cross-sectional view of the purification mechanism, the ventilation mechanism and the water outlet mechanism of the present invention;

FIG. 5 is a schematic view of the venting mechanism of the present invention;

FIG. 6 is a schematic view of the connection structure of the purification mechanism, the water supply mechanism and the pumping mechanism of the present invention;

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

FIG. 8 is a first schematic view of the mounting bracket, sensor A, sensor B and control mechanism connection configuration of the present invention;

FIG. 9 is a schematic view of the control mechanism of the present invention;

FIG. 10 is a second schematic view of the mounting bracket, sensor A, sensor B and control mechanism connection configuration of the present invention;

FIG. 11 is a schematic view of the connection structure of the purification mechanism, the aeration mechanism, the water outlet mechanism, the water supply mechanism and the inflating mechanism of the present invention.

In the figure: a filter cartridge 11; a supply conduit 12; a connecting pipe 13; an installation case 14; a filter plate 15; a mounting bracket 20; sensor a 30; sensor B40; an aeration cover plate 51; an air duct 52; a vent plate I53; a one-way sliding block I54; a vent plate II 55; a water outlet bottom plate 61; a one-way sliding block II 62; a stopper bracket 63; a telescoping mechanism I71; a push plate I72; a one-way mechanism I73; a one-way mechanism II 74; a telescoping mechanism II 81; a pushing plate II 82; a one-way mechanism III 83; a one-way mechanism IV 84; a stop cam I91; a stop cam II 92; a transmission shaft I93; the arc cam I94; a transmission shaft II 95; and an arc cam II 96.

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 7, and a multifunctional intelligent purification system for secondary water supply comprises a purification mechanism, a mounting bracket 20, a sensor a30, a sensor B40, an aeration mechanism and a water outlet mechanism, the water supply mechanism, the mechanism of inflating and the control mechanism, the purification mechanism includes the cartridge filter 11, supply the pipeline 12, the connecting line 13, the installation box 14 and the filter 15, the left and right sides of the cartridge filter 11 are fixedly connected with the supply pipeline 12, two supply pipelines 12 are both communicated with the cartridge filter 11, two supply pipelines 12 are both fixedly connected with the connecting line 13, two connecting lines 13 are respectively communicated with two supply pipelines 12, the installation box 14 is placed in the cartridge filter 11, the filter 15 is placed in the installation box 14, the cartridge filter 11 is fixedly connected to the installation support 20, the left and right sides of the installation support 20 are respectively fixedly connected with the sensor B40 and the sensor A30; other water purifying agents can be placed on the filter plate 15;

the ventilation mechanism comprises a ventilation cover plate 51, a ventilation pipeline 52, a ventilation plate I53, a one-way sliding block I54 and a ventilation plate II 55, the ventilation pipeline 52 is fixedly connected to the ventilation cover plate 51, the ventilation cover plate 51 is fixedly connected to the installation box 14, the ventilation cover plate 51 covers the filter cartridge 11, the ventilation pipeline 52 is communicated with the filter cartridge 11, the ventilation plate I53 is fixedly connected to the ventilation pipeline 52, a conical hole I is formed in the ventilation plate I53, the ventilation plate II 55 is fixedly connected to the ventilation pipeline 52, the one-way sliding block I54 is slidably connected to the ventilation plate II 55, the one-way sliding block I54 is supported in the conical hole I in the ventilation plate I53, and a compression spring I is fixedly connected between the one-way sliding block I54 and the ventilation plate II 55;

the water outlet mechanism comprises a water outlet bottom plate 61, a one-way sliding block II 62 and a stopping support 63, the water outlet bottom plate 61 is fixedly connected in the filter cartridge 11, a round through hole is formed in the water bottom plate 61, the one-way sliding block II 62 is connected on the water bottom plate 61 in a sliding mode, a compression spring II is fixedly connected between the one-way sliding block II 62 and the water bottom plate 61, the lower end of the one-way sliding block II 62 is in contact with the stopping support 63, the stopping support 63 is connected on the mounting support 20 in a sliding mode, a compression spring III is fixedly connected between the stopping support 63 and the mounting support 20, a conical hole II is formed in the bottom of the mounting box 14, and the upper end of the one-way sliding block II 62 abuts against the conical hole II;

the water supply mechanism comprises a telescopic mechanism I71, a push plate I72, a one-way mechanism I73 and a one-way mechanism II 74, the telescopic mechanism I71 is fixedly connected to the right feeding pipeline 12, the telescopic end of the telescopic mechanism I71 is fixedly connected with the push plate I72, the push plate I72 is slidably connected into the right feeding pipeline 12, the one-way mechanism II 74 is arranged in the right feeding pipeline 12, and the one-way mechanism I73 is arranged in the right connecting pipeline 13;

the inflating mechanism comprises a telescopic mechanism II 81, a pushing plate II 82, a one-way mechanism III 83 and a one-way mechanism IV 84, the telescopic mechanism II 81 is fixedly connected to the left feeding pipeline 12, the telescopic end of the telescopic mechanism II 81 is fixedly connected with the pushing plate II 82, the pushing plate II 82 is connected to the left feeding pipeline 12 in a sliding mode, the one-way mechanism IV 84 is arranged in the left feeding pipeline 12, and the one-way mechanism III 83 is arranged in the left connecting pipeline 13;

when the water purifier is used, water to be purified is introduced into the filter cartridge 11, the mounting box 14 is placed in the filter cartridge 11, the filter plate 15 is placed in the mounting box 14, the water is purified through the filter plate 15, the filter plate 15 can be set to be a filter material in the prior art according to the use requirement in the prior art, and the mounting box 14 is placed in the filter cartridge 11, so that the mounting box 14 can be conveniently taken out of the filter cartridge 11, and the filter plate 15 is convenient to replace;

the invention is further provided with a ventilation mechanism, a water outlet mechanism, a water supply mechanism and an inflating mechanism, wherein water is required to be supplied into the filter cartridge 11, the stop bracket 63 is pushed to move upwards in advance, so that the stop bracket 63 supports the one-way sliding block II 62, the one-way sliding block II 62 is abutted against the lower side of the installation box 14 and is provided with a tapered hole II, the lower end of the installation box 14 is sealed, no water flows out through the installation box 14, a water pipeline is connected to the connecting pipeline 13 on the right side in advance, the telescopic mechanism I71 is started, the telescopic mechanism I71 and the telescopic mechanism II 81 can be hydraulic cylinders or electric push rods, the telescopic end of the telescopic mechanism I71 starts to move, the telescopic end of the telescopic mechanism I71 drives the push plate I72 to slide in the feed pipeline 12, as shown in figure 7, when the push plate I72 moves towards the side of the one-way mechanism II 74, the one-way mechanism II 74 is opened, when water is introduced into the filter cartridge 11, the air pressure in the filter cartridge 11 is increased to push the one-way sliding block I54 to move upwards, the one-way sliding block I54 is not pushed against the tapered hole I arranged on the air vent plate I53, and air is exhausted from the tapered hole I arranged on the air vent plate I53;

when drainage is needed, the one-way sliding block I54 is pushed downwards, the one-way sliding block I54 is enabled to be propped against the tapered hole I arranged on the ventilation plate I53, the tapered hole I is blocked, gas cannot be discharged through the ventilation mechanism, the telescopic mechanism II 81 is started, the telescopic end of the telescopic mechanism II 81 drives the push plate II 82 to slide in the left supply pipeline 12, when the push plate II 82 moves towards the one-way mechanism IV 84 side, the one-way mechanism IV 84 is opened, the one-way mechanism III 83 is closed, the gas in the supply pipeline 12 enters the filter cylinder 11 through the one-way mechanism IV 84, the air pressure in the filter cylinder 11 is increased, water is pushed downwards to move, the one-way sliding block II 62 is not propped against the tapered hole II arranged on the installation box 14 any more, the water passes through the filter plate 15 under the pushing of the air pressure, the filter plate 15 filters the passing water and discharges the filter cylinder 11, the telescopic end of the telescopic mechanism II 81 performs two movements, so that the water in the filter cylinder 11 is discharged twice.

The embodiment is described below with reference to fig. 1 to 11, the control mechanism includes a stop cam i 91, a stop cam ii 92, a transmission shaft i 93, an arc cam i 94, a transmission shaft ii 95 and an arc cam ii 96, the stop cam i 91 is rotatably connected to the upper side of the mounting bracket 20, the stop cam ii 92 is rotatably connected to the lower side of the mounting bracket 20, the stop cam i 91 and the stop cam ii 92 are both provided with a half-circle protrusion, the protrusion on the stop cam i 91 can be contacted with the one-way slider i 54, the protrusion on the stop cam ii 92 can be contacted with the stop bracket 63, the left side of the mounting bracket 20 is rotatably connected with the transmission shaft i 93, the transmission shaft i 93 is rotatably connected with two arc cams i 94, the two arc cams i 94 are both connected with a positioning pin i through threads, the two arc cams i 94 can be contacted with a sensor a30, the right side of the mounting bracket 20 is rotatably connected with the transmission shaft ii 95, the two arc cams II 96 are rotatably connected to the transmission shaft II 95, the two arc cams II 96 are provided with different models, the two arc cams II 96 are different in model, the two arc cams II 96 are both connected with the positioning nail II through threads, the two arc cams II 96 can be contacted with the sensor B40, the stop cam I91, the stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 are in transmission connection, and the transmission ratio among the stop cam I91, the stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 is one;

the sensor A30 is connected with the telescopic mechanism I71, the sensor B40 is connected with the telescopic mechanism II 81, and the telescopic ends of the telescopic mechanism I71 and the telescopic mechanism II 81 have the same movement speed;

the device is further provided with a control mechanism, the control mechanism can enable the device to work repeatedly and quickly, the stop cam I91, the stop cam II 92, the transmission shaft I93 or the transmission shaft II 95 are rotated, or a power device is arranged on the stop cam I91, the stop cam II 92, the transmission shaft I93 or the transmission shaft II 95 and can be a motor or an internal combustion engine, the power device drives the stop cam I91, the stop cam II 92, the transmission shaft I93 or the transmission shaft II 95 to rotate, as shown in fig. 9, the stop cam I91, the stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 are in transmission connection, the transmission ratio between the stop cam I91, the stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 is one, when any one of the stop cam I91, the stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 rotates, the stop cam I91, the stop cam II 92 and the transmission shaft II 95 rotate, The stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 rotate together, for example, the stop cam I91 is driven to rotate, the stop cam II 92, the transmission shaft I93 and the transmission shaft II 95 rotate together when the stop cam I91 rotates, as shown in FIG. 9, half-circle protrusions are arranged on the stop cam I91 and the stop cam II 92, the stop cam II 92 presses the stop support 63 in a path, the stop cam I91 does not press the one-way slider I54, the stop cam I91 presses the one-way slider I54 in a path, the stop cam II 92 does not press the stop support 63, the stop cam II 92 presses the stop support 63, the stop support 63 supports the one-way slider II 62, the bottom of the installation box 14 is closed, and the stop cam II 92 presses the stop support 63 in a path, the two circular arc cams I94 extrude the sensor A30, the sensor A30 and the sensor B40 can be extrusion sensors or contact sensors, the sensor A30 is connected to a telescopic mechanism I71 through an electric control means commonly used in the field, when the sensor A30 is extruded, a telescopic end of the telescopic mechanism I71 extends out, the telescopic end of the telescopic mechanism I71 drives a push plate I72 to slide in a feeding pipeline 12, the push plate I72 feeds water into a filter cylinder 11, when the sensor A30 is not extruded, the telescopic end of the telescopic mechanism I71 retracts, the angle of the circular arc formed by dislocation of the two circular arc cams I94 is adjusted according to use requirements, the extrusion time of the sensor A30 is controlled, the movement time of a water supply mechanism is controlled, the water supply amount is controlled, and meanwhile, the maximum angle formed by the two circular arc cams I94 cannot exceed 180 degrees, namely, water supply is ensured in the closing period of the water outlet mechanism, the two arc cams I94 are both connected with positioning nails I through threads, and the opening angles of the two arc cams I94 are fixed through the positioning nails I;

when the stop cam II 92 does not press the one-way sliding block II 62 any more, the stop cam I91 contacts with the one-way sliding block I54 and presses the one-way sliding block I54, the two arc cams II 96 contact with the sensor B40 in a path of the stop cam I91 pressing the one-way sliding block I54, the sensor B40 is connected with the telescopic mechanism II 81 through an electric control means commonly used in the field, when the sensor B40 is pressed, the sensor B40 controls the telescopic end of the telescopic mechanism II 81 to extend out, the telescopic end of the telescopic mechanism II 81 drives the pushing plate II 82 to move, the pushing plate II 82 pushes gas into the filter cartridge 11, the gas pressure in the filter cartridge 11 is increased, water is discharged through the water outlet mechanism under the action of the pressure, as shown in figure 9, the two arc cams II 96 can be set to be of different models, namely, the two arc cams II 96 can be set to be different radian according to different use requirements, the water supply amount of each arc cam II 96 when contacting with the sensor B40 is further adjusted, and different use requirements are further met;

meanwhile, the position between the two arc cams II 96 can also be adjusted, so that the water supply time of the two arc cams II 96 during movement is adjusted, the interval time between two times of water supply is adjusted, the two arc cams II 96 are connected with positioning nails II through threads, and the positions of the two arc cams II 96 are fixed through the positioning nails II.

s1: when the control mechanism is contacted with the sensor A30, the control mechanism is contacted with the stop bracket 63, and the sensor A30 controls the water supply mechanism to feed a specified amount of water into the purification mechanism;

s2: when the control mechanism moves and contacts with the sensor B40, the control mechanism contacts with the one-way slider I54, and the sensor B40 controls the inflating mechanism to introduce air with the specified amount into the purifying mechanism twice;

s3: the air pressure in the purification mechanism is increased, the water outlet mechanism is opened, and the moisture in the purification mechanism is filtered and discharged out of the purification mechanism through the filter plate 15 twice.

It should be noted that the above embodiments may be spliced with each other or all may be combined together for use.

It is to be understood that the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and that various changes, modifications, additions and substitutions which are within the spirit and scope of the present invention and which may be made by those skilled in the art are also within the scope of the present invention.

Claims

1. The utility model provides a be used for multi-functional intelligent clean system of secondary water supply, includes cartridge filter (11), install bin (14) and filter (15), its characterized in that: an installation box (14) is arranged in the filter cartridge (11), and a filter plate (15) is arranged in the installation box (14).

2. The multifunctional intelligent purification system for secondary water supply as claimed in claim 1, wherein: the equal fixedly connected with in the left and right sides of cartridge filter (11) supplies pipeline (12), all fixedly connected with connecting tube (13) on two supply pipeline (12).

3. The multifunctional intelligent purification system for secondary water supply as claimed in claim 2, wherein: a water supply mechanism is arranged in the feeding pipeline (12) and the connecting pipeline (13) at one side, and an inflating mechanism is arranged in the feeding pipeline (12) and the connecting pipeline (13) at the other side.

4. The multifunctional intelligent purification system for secondary water supply as claimed in claim 3, wherein: water supply mechanism includes telescopic machanism I (71), catch plate I (72), I (73) of one-way mechanism and II (74) of one-way mechanism, telescopic machanism I (71) fixed connection is on feeding pipeline (12) on right side, fixedly connected with catch plate I (72) are served in the flexible of telescopic machanism I (71), in catch plate I (72) sliding connection is in feeding pipeline (12) on right side, be provided with II (74) of one-way mechanism in feeding pipeline (12) on right side, be provided with I (73) of one-way mechanism in connecting tube (13) on right side.

5. The multifunctional intelligent purification system for secondary water supply as claimed in claim 4, wherein: the inflating mechanism comprises a telescopic mechanism II (81), a push plate II (82), a one-way mechanism III (83) and a one-way mechanism IV (84), the telescopic mechanism II (81) is fixedly connected to the left feeding pipeline (12), the telescopic end of the telescopic mechanism II (81) is fixedly connected with the push plate II (82), the push plate II (82) is slidably connected to the left feeding pipeline (12), the one-way mechanism IV (84) is arranged in the left feeding pipeline (12), and the one-way mechanism III (83) is arranged in the left connecting pipeline (13).

6. The multifunctional intelligent purification system for secondary water supply as claimed in claim 5, wherein: the telescopic end movement speeds of the telescopic mechanism I (71) and the telescopic mechanism II (81) are the same.

7. The multifunctional intelligent purification system for secondary water supply as claimed in claim 5, wherein: still including installing support (20) that is used for fixed connection cartridge filter (11), fixedly connected with sensor A (30) and sensor B (40) on installing support (20), sensor A (30) and telescopic machanism I (71) are connected, and sensor B (40) and telescopic machanism II (81) are connected.

8. The multifunctional intelligent purification system for secondary water supply as claimed in claim 7, wherein: the upper end of the filter cylinder (11) is provided with a ventilation mechanism for ventilation, and the lower end of the filter cylinder (11) is provided with a water outlet mechanism for drainage.

9. The multifunctional intelligent purification system for secondary water supply as claimed in claim 8, wherein: the device also comprises a control mechanism for controlling the sensor A (30), the sensor B (40), the ventilation mechanism, the water outlet mechanism, the water supply mechanism and the inflating mechanism to work circularly.

10. The method for secondary intelligent water supply of the multifunctional intelligent secondary water supply purification system as claimed in claim 9, wherein the method comprises the following steps: the method comprises the following steps:

s1: when the control mechanism is contacted with the sensor A (30), the control mechanism is contacted with the stop bracket (63), and the sensor A (30) controls the water supply mechanism to introduce a specified amount of water into the purification mechanism;

s2: when the control mechanism moves and contacts with the sensor B (40), the control mechanism contacts with the one-way sliding block I (54), and the sensor B (40) controls the inflating mechanism to introduce air with a specified amount into the purifying mechanism twice;

s3: the air pressure in the purification mechanism is increased, the water outlet mechanism is opened, and the moisture in the purification mechanism is filtered and discharged out of the purification mechanism through the filter plate (15) twice.