CN118384569A - A water-saving recoil device for quartz sand filter - Google Patents

Abstract

The present invention relates to the technical field of water-saving backwashing of quartz sand filters, and discloses a water-saving backwashing device for quartz sand filters, comprising a quartz sand filtering processing unit, a stirring and spraying unit, and a rotating stirring unit. The quartz sand filtering processing unit comprises a shell, a first water inlet pipe and a sewage pipe are installed above the shell, a water outlet pipe and a second water inlet pipe are installed at the bottom of the shell, the first water inlet pipe and the sewage pipe are symmetrical to each other, and the water outlet pipe and the second water inlet pipe are symmetrical to each other. The present invention drives the rotating rod to rotate through an asynchronous motor to rotate the built-in installation barrel, and when the built-in installation barrel rotates, it can drive the stirring barrel to rotate, and when the stirring barrel rotates, it can deliver quartz sand, and when the rotating rod rotates, it can also drive the transmission mechanism and the spraying mechanism to rotate, so that the quartz sand can be sprayed through the spraying mechanism, so that when the quartz sand is sprayed, the spraying efficiency is higher, so it can achieve the effect of water saving.

Description

A water-saving recoil device for quartz sand filter

Technical Field

The invention belongs to the technical field of water-saving recoil flushing of quartz sand filters, and in particular relates to a water-saving recoil flushing device for a quartz sand filter.

Background technique

Quartz sand filters can be widely used in electronics and power, petrochemicals, metallurgy and electroplating, paper and textile, pharmaceutical dialysis, food and beverage, drinking water, factory and enterprise water, swimming pools, etc., and can meet the liquid filtration needs of various industries. Quartz sand filtration is one of the most effective means to remove suspended matter in water, and is an important unit in sewage deep treatment, sewage reuse and water supply treatment.

In the prior art, when backwashing quartz sand, in order to ensure the flushing efficiency, the quartz sand is often flushed by conveying water resources. In order to make the quartz sand flushed more cleanly, it is often necessary to flush for a long time, which easily leads to a waste of water resources in the process of flushing the quartz sand.

In view of this, the present invention is proposed.

Summary of the invention

In order to solve the above-mentioned existing problem that when backwashing quartz sand, in order to ensure the flushing efficiency, the quartz sand is often flushed by conveying water resources, and in order to make the quartz sand flushed more cleanly, it is often necessary to flush for a long time, which leads to the problem that water resources are easily wasted in the process of flushing the quartz sand. The basic concept of the technical solution adopted by the present invention is:

A quartz sand filter water-saving backwash device, comprising a quartz sand filtering processing unit, a stirring and spraying unit and a rotating stirring unit, the quartz sand filtering processing unit comprising a shell, a first water inlet pipe and a sewage pipe are installed on the top of the shell, a water outlet pipe and a second water inlet pipe are installed at the bottom of the shell, the first water inlet pipe and the sewage pipe are symmetrical to each other, the water outlet pipe and the second water inlet pipe are symmetrical to each other, four supporting legs are installed at the bottom of the shell, the four supporting legs are symmetrical to each other, and a blocking plate is installed at the bottom of the inner cavity of the shell;

The stirring and spraying unit comprises a built-in mounting cylinder and four stirring cylinders, wherein the built-in mounting cylinder is mounted in the inner cavity of the shell, and four stirring cylinders are rotatably mounted on the side wall of the built-in mounting cylinder, and the four stirring cylinders are symmetrical to each other and are equidistantly distributed, and placement holes are provided on the opposite side walls of the four stirring cylinders, and a water spray assembly is provided in the inner cavity of each placement hole, and a transmission mechanism and a spraying mechanism are provided in the inner cavity of the built-in mounting cylinder, wherein the transmission mechanism is used to drive the built-in mounting cylinder to drive the stirring cylinder to rotate, and the spraying mechanism is used to drive water to spray out from the water spray assembly provided on each stirring cylinder;

The rotating stirring unit comprises a floating plate, which is arranged above the built-in mounting cylinder, and the two opposite side walls of the floating plate are both provided with sliding mechanisms, and the bottom of the floating plate is provided with a rotating mechanism, which is used to drive the stirring cylinder to rotate independently.

As a preferred embodiment of the present invention, the first water inlet pipe, the sewage pipe, the water outlet pipe and the second water inlet pipe are respectively installed with a first valve, a second valve, a third valve and a fourth valve.

As a preferred embodiment of the present invention, the transmission mechanism includes an asynchronous motor, which is installed above the housing. A rotating rod is fixedly installed at the output end of the asynchronous motor, and a bearing is provided at the other end of the rotating rod, and the bearing is installed above the blocking plate.

As a preferred embodiment of the present invention, two sealing boxes are fixedly installed on the rotating rod, and the rotating rod is fixedly installed with a first bevel gear in the inner cavities of the two sealing boxes, and the second bevel gear and the third bevel gear are respectively installed on the opposite side walls of the two first bevel gears in a vertical meshing manner, and a rotating rod is fixedly installed on the side wall opposite to each of the second bevel gear and the third bevel gear, and the other end of each rotating rod is respectively located in the inner cavities of the four mixing drums, and each rotating rod is movably sealed and passes through the two sealing boxes, and each rotating rod is installed with a mounting bearing in the inner cavity of the sealing box, and a limiting rod is installed on each mounting bearing, and the other end of each limiting rod is fixedly connected to the inner wall of the sealing box, and a guide groove is slidably installed on each rotating rod, and a sliding block is provided on each rotating rod, and the sliding block is slidably connected in the guide groove.

As a preferred embodiment of the present invention, the spraying mechanism includes a sleeve, each sleeve inner cavity is connected to a sliding block, each sleeve is fixedly mounted with a circular mounting plate, each circular mounting plate is sleeved with a first filter plate on a rotating rod on a side wall close to the mixing drum, and each of the first filter plate side walls is slidably connected to the inner wall of the mixing drum.

As a preferred embodiment of the present invention, each of the mixing drum inner cavities is provided with a guide rod, one end of each of the guide rods is fixedly connected to the side wall of the sealing box, and each of the guide rods is movably penetrated by a first filter plate and a circular mounting plate.

As a preferred embodiment of the present invention, each of the mixing drums is provided with a circular sealing plate on one side wall port opposite to each other, and each of the circular sealing plates is provided with a connecting rod on one side wall laterally symmetrical between the two circular sealing plates, and both ends of the two connecting rods are respectively fixedly connected to the opposite side walls of the two laterally symmetrical circular sealing plates, and a handle is installed at the bottom of each circular sealing plate.

As a preferred embodiment of the present invention, the sliding mechanism includes two sliding grooves, the two sliding grooves are opened on the side walls of the inner cavity of the built-in mounting tube, the two sliding grooves are symmetrical to each other, sliding blocks are slidably installed in the inner cavities of the two sliding grooves, and a floating plate is installed on the side wall opposite to the two sliding blocks.

As a preferred embodiment of the present invention, the rotating mechanism includes a first rack and a second rack, the first rack and the second rack are respectively installed at the bottom of the floating plate, the first rack and the second rack are staggered and symmetrical with each other, two first driving gears and two second driving gears are respectively meshed and installed on the first rack and the second rack, the two first driving gears are respectively installed on the side walls of the mixing drum on the opposite sides, the two second driving gears are respectively installed on the mixing drum on the opposite sides, and the two first driving gears and the two second driving gears are symmetrical with each other.

As a preferred embodiment of the present invention, a second filter plate is installed at the bottom of the built-in installation cylinder, a placement hole is opened in the middle of the second filter plate, and the placement hole runs through two sealing boxes, the built-in installation cylinder, the floating plate and the top of the shell.

Compared with the prior art, the present invention has the following beneficial effects:

The present invention drives the rotating rod to rotate by an asynchronous motor to rotate the built-in installation drum. When the built-in installation drum rotates, it can drive the mixing drum to rotate. When the mixing drum rotates, quartz sand can be delivered. When the rotating rod rotates, it can also drive the transmission mechanism and the spraying mechanism to rotate. Therefore, the quartz sand can be sprayed by the spraying mechanism. At the same time, when the spraying mechanism is reset, the floating plate can move with the assistance of the sliding mechanism to drive the rotating mechanism to rotate the mixing drum. Therefore, the spraying assembly arranged on the mixing drum can be rotated, and the spraying assembly can be used to spray different positions, so that when the quartz sand is sprayed, the spraying efficiency is higher, thereby achieving the effect of saving water.

The specific implementation modes of the present invention are further described in detail below in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

In the attached picture:

FIG1 is a schematic diagram of the three-dimensional structure of a water-saving backwash device for a quartz sand filter;

FIG2 is a schematic diagram of the structure of a water-saving recoil device for a quartz sand filter from a bottom view;

FIG3 is a schematic cross-sectional view of the shell structure of a quartz sand filter water-saving recoil device;

FIG4 is a schematic diagram of the inner structure of a shell of a water-saving backwashing device for a quartz sand filter;

FIG5 is a schematic diagram of the structure of a housing of a quartz sand filter water-saving recoil device when viewed from above;

FIG6 is a schematic diagram of the inner cavity structure of a built-in mounting cylinder of a water-saving backwash device for a quartz sand filter;

FIG7 is a schematic diagram of the inner structure of a sealing box of a water-saving backwashing device for a quartz sand filter;

FIG8 is a schematic diagram of the structure of a stirring and spraying unit of a water-saving backwashing device for a quartz sand filter;

FIG9 is a schematic cross-sectional view of a partially built-in mounting tube of a water-saving recoil device for a quartz sand filter;

FIG10 is a schematic diagram of a partial internal mounting cylinder structure of a water-saving backwash device for a quartz sand filter;

FIG11 is a schematic diagram of a partial installation cylinder of a water-saving recoil device for a quartz sand filter, viewed from above;

FIG. 12 is a schematic diagram of the partial structure of location A of a water-saving backwash device for a quartz sand filter.

In the figure:

100, quartz sand filtration treatment unit; 101, first water inlet pipe; 1011, sewage pipe; 1012, water outlet pipe; 1013, second water inlet pipe; 102, shell; 1021, support leg; 1022, blocking plate; 103, first valve; 1031, second valve; 1032, third valve; 1033, fourth valve

200, stirring and spraying unit; 201, asynchronous motor; 2011, rotating rod; 2012, built-in mounting cylinder; 2013, stirring cylinder; 2014, bearing; 2015, placement hole; 2016, water spray assembly; 202, sealing box; 2021, first bevel gear; 2022, second bevel gear; 2023, third bevel gear; 2024, rotating rod; 203, limiting rod; 2031, guide slide; 2032, sleeve; 2033, circular mounting plate; 2034, first filter plate; 2035, guide rod; 2036, mounting bearing; 204, circular sealing plate; 2041, handle; 2042, second filter plate; 2043, connecting rod;

300, rotating stirring unit; 301, floating plate; 3011, sliding block; 3012, sliding groove; 302, first rack; 3021, second rack; 3022, first driving gear; 3023, second driving gear.

Detailed ways

In order to make the purpose, technical solutions and advantages of the embodiments of the present invention clearer, the technical solutions in the embodiments will be clearly and completely described below in conjunction with the drawings in the embodiments of the present invention. The following embodiments are used to illustrate the present invention.

Example 1

As shown in FIGS. 1 to 12 , a quartz sand filter water-saving backwashing device comprises a quartz sand filtering treatment unit 100, a stirring and spraying unit 200 and a rotating stirring unit 300. The quartz sand filtering treatment unit 100 comprises a shell 102. A first water inlet pipe 101 and a sewage pipe 1011 are installed above the shell 102. A water outlet pipe 1012 and a second water inlet pipe 1013 are installed at the bottom of the shell 1. The first water inlet pipe 101 and the sewage pipe 1011 are symmetrical to each other, and the water outlet pipe 1012 and the second water inlet pipe 1013 are symmetrical to each other. Four supporting legs 1021 are installed at the bottom of the shell 102. The four supporting legs 1021 are symmetrical to each other. A blocking plate 1022 is installed at the bottom of the inner cavity of the shell 102.

The stirring and spraying unit 200 includes a built-in mounting cylinder 2012 and four stirring cylinders 2013. The built-in mounting cylinder 2012 is mounted in the inner cavity of the housing 1. Four stirring cylinders 2013 are rotatably mounted on the side wall of the built-in mounting cylinder 2012. The four stirring cylinders 2013 are symmetrical to each other and are equidistantly distributed. Placement holes 2015 are provided on the opposite side walls of the four stirring cylinders 2013. Each placement hole 215 is provided with a water spray assembly 2016 in the inner cavity. The inner cavity of the built-in mounting cylinder 2012 is provided with a transmission mechanism and a spraying mechanism. The transmission mechanism is used to drive the built-in installation cylinder 2012 to drive the mixing cylinder 2013 to rotate, and the spraying mechanism is used to drive water to spray out from the water spraying assembly 2016 set on each mixing cylinder 2013; the staff starts the asynchronous motor 201, and the asynchronous motor 201 will be able to drive the rotating rod 2011 to rotate. When the rotating rod 2011 rotates, it will be able to drive the first bevel gears 221 installed in the inner cavities of the two sealing boxes 202 to rotate respectively. When the two first bevel gears 2021 rotate, they will be able to The second bevel gear 2022 and the third bevel gear 2023 are driven to rotate. When the second bevel gear 2022 and the third bevel gear 2023 rotate, the rotating rod 2024 is driven to rotate. When the rotating rod 2024 rotates, the sleeve 2032 and the circular mounting plate 2033 are driven to move through the guide slot 2031. When the circular mounting plate 2033 moves, the sleeve 2032 can push the first filter plate 2034 to move horizontally with the assistance of the guide rod 2035 until the first filter plate 2034 is moved horizontally. When the first circular mounting plate 2033 enters the mixing drum 2013, it can squeeze the water in the mixing drum 2013, so that water can be sprayed from the water spray assembly 2016 provided on the mixing drum 2013, thereby spraying the quartz sand. At the same time, because the rotating rod 2011 can drive the built-in mounting drum 2012 and the mixing drum 2013 to rotate slowly when rotating, the quartz sand can be shaken, so that when spraying the quartz sand, the spraying efficiency is higher, thereby achieving the effect of water saving.

The rotating stirring unit comprises a floating plate 301 , which is arranged above the built-in mounting cylinder 2012 , and sliding mechanisms are arranged on opposite side walls of the floating plate 301 , and a rotating mechanism is arranged at the bottom of the floating plate 301 , which is used to drive the stirring cylinder 2013 to rotate independently. When the circular mounting plate 2033 performs the reset movement with the assistance of the guide slide groove 2031 and the sliding block, the water in the built-in mounting cylinder 2012 will be filled with water at this time, and because the bottom is continuing to be filled with water, the circular mounting plate 2033 will continue to have a squeezing effect when it moves back, so that the water in the built-in mounting cylinder 2012 can be reduced, so that the floating plate 301 arranged above can move horizontally downward with the assistance of the slider 3011 and the slide groove 3012 in the sliding mechanism. Therefore, when the floating plate 301 moves downward, it can drive the first rack 302 and the second rack 3021 to move downward, thereby driving the first driving gear 3022 and the second driving gear 3023 to rotate. When the first driving gear 3022 and the second driving gear 3023 rotate, they can respectively drive the mixing cylinder 2013 to rotate, so that the position of the water spraying assembly 2016 can be changed, so that water can be sprayed in different directions, so that the efficiency of quartz sand spraying is further improved, thereby reducing the water consumption.

As shown in Fig. 1 to Fig. 3, in a specific embodiment, the first water inlet pipe 101, the sewage pipe 1011, the water outlet pipe 1012 and the second water inlet pipe 1013 are respectively installed with a first valve 103, a second valve 1031, a third valve 1032 and a fourth valve 1033. When clean water enters the housing 102, the quartz sand can be washed. When water enters the inner cavity of the housing 102, it can also enter the inner cavity of the built-in installation cylinder 2012 through the circular hole opened on the second filter plate 2042 installed at the bottom of the built-in installation cylinder 2012. When water enters the built-in installation cylinder 2012, it will enter the inner cavities of the four mixing cylinders 2013.

As shown in Fig. 1 to Fig. 10, the transmission mechanism further comprises an asynchronous motor 201, which is mounted above the housing 102, and a rotating rod 2011 is fixedly mounted at the output end of the asynchronous motor 201, and a bearing 2014 is arranged at the other end of the rotating rod 2011, and the bearing 2014 is arranged above the blocking plate 1022. The staff opens the first valve 103 and the third valve 1032, so that the sewage inputted in the first water inlet pipe 101 can enter the inner cavity of the housing 102, and at this time, the quartz sand arranged in the inner cavity of the housing 102 can filter the sewage through the quartz sand, so that the filtered clean water can be discharged from the outlet pipe 1012, so that the effect of filtering the sewage can be achieved.

As shown in Figures 3 to 10, further, two sealing boxes 202 are fixedly installed on the rotating rod 2011, and the rotating rod 2011 is fixedly installed with a first bevel gear 2021 in the inner cavity of the two sealing boxes 202. The two side walls opposite to the two first bevel gears 2021 are respectively vertically meshed with a second bevel gear 2022 and a third bevel gear 2023. A rotating rod 2024 is fixedly installed on the side wall opposite to each second bevel gear 2022 and the third bevel gear 2023, and the other end of each rotating rod 2024 is respectively located at four In the inner cavity of the mixing drum 2013, each rotating rod 2024 is respectively movably sealed and penetrates the two sealing boxes 202, each rotating rod 2024 is installed with a mounting bearing 2036 in the inner cavity of the sealing box 202, each mounting bearing 2036 is installed with a limit rod 203, and the other end of each limit rod 203 is fixedly connected to the inner wall of the sealing box 202, each rotating rod 2024 is slidably installed with a guide slot 2031, and each rotating rod 2024 is provided with a sliding block, and the sliding block is slidably connected in the guide slot 2031. The staff starts the asynchronous motor 201, and the asynchronous motor 201 will be able to drive the rotating rod 2011 to rotate. When the rotating rod 2011 rotates, it can drive the built-in mounting drum 2012 and the mixing drum 2013 to rotate slowly, so that the quartz sand can be shaken, so that when the quartz sand is sprayed, the spraying efficiency is higher, so it can achieve the effect of saving water.

Example 2

Based on the above embodiment, the difference from this embodiment is: as shown in Figures 10 to 12, a quartz sand filter water-saving recoil device, the spraying mechanism includes a sleeve 2032, each sleeve 2032 inner cavity is connected to a sliding block, each sleeve 2032 is fixedly mounted with a circular mounting plate 2033, each circular mounting plate 2033 has a side wall close to the mixing drum 2013 and a first filter plate 2034 is sleeved on the rotating rod 2024, and each first filter plate 2034 side wall is slidably connected to the inner wall of the mixing drum 2013. The staff starts the asynchronous motor 201, and the asynchronous motor 201 can drive the rotating rod 2011 to rotate. When the rotating rod 2011 rotates, it can respectively drive the first bevel gears 2021 installed in the inner cavities of the two sealing boxes 202 to rotate. When the two first bevel gears 2021 rotate, they can respectively drive the second bevel gear 2022 and the third bevel gear 2023 to rotate. When the second bevel gear 2022 and the third bevel gear 2023 rotate, they can drive the rotating rod 2024 to rotate. When the rotating rod 2024 rotates, it can pass through the guide slot 20 31 drives the sleeve 2032 and the circular mounting plate 2033 to move. When the circular mounting plate 2033 moves, the sleeve 2032 can push the first filter plate 2034 to move horizontally with the assistance of the guide rod 2035 until the first circular mounting plate 2033 enters the mixing drum 2013 and squeezes the water in the mixing drum 2013, so that water can be sprayed from the water spraying assembly 2016 provided on the mixing drum 2013, thereby spraying the quartz sand, so that when spraying the quartz sand, the spraying efficiency is higher, thereby achieving the effect of saving water.

As shown in Fig. 3 to Fig. 10 and Fig. 12, in a specific embodiment, each mixing drum 2013 inner cavity is provided with a guide rod 2035, one end of each guide rod 2035 is respectively fixedly connected to the side wall of the sealing box 202, and each guide rod 2035 is movably penetrated by a first filter plate 2034 and a circular mounting plate 2033. It is ensured that the first filter plate 2034 and the circular mounting plate 2033 can move horizontally.

As shown in Fig. 3 to Fig. 10 and Fig. 12, further, each mixing drum 2013 is provided with a circular sealing plate 204 at a port on one side wall opposite to the other, and each circular sealing plate 204 is provided with a connecting rod 2043 at a side wall symmetrically disposed between the two circular sealing plates 204, and the two ends of the two connecting rods 2043 are respectively fixedly connected to the opposite side walls of the two horizontally symmetrical circular sealing plates 204, and a handle 2041 is installed at the bottom of each circular sealing plate 204. It is ensured that when cleaning the inner cavity of the mixing drum 2013, the staff can take out the sealing plate 204 through the handle 2040.

Example 3

The difference between the above embodiment and the present embodiment is that: as shown in FIG. 4 to FIG. 10, a water-saving recoil device for a quartz sand filter, the sliding mechanism includes two slide grooves 3012, the two slide grooves 3012 are opened on the side wall of the inner cavity of the built-in installation cylinder 2012, the two slide grooves 3012 are symmetrical to each other, the inner cavity of the two slide grooves 3012 is slidably installed with a slider 3011, and the side wall opposite to the two sliders 3011 is installed with a floating plate 301. When the circular mounting plate 2033 performs a reset movement with the assistance of the guide slide groove 2031 and the sliding block, the water in the built-in installation cylinder 2012 will be in a full state at this time, and because the bottom is still being filled with water, the circular mounting plate 2033 will continue to play a squeezing effect when moving back, so that the water in the built-in installation cylinder 2012 can be reduced, so that the floating plate 301 arranged above can move horizontally downward with the assistance of the slider 3011 and the slide groove 3012 in the sliding mechanism.

As shown in Figures 4 to 12, in a specific embodiment, the rotating mechanism includes a first rack 302 and a second rack 3021, the first rack 302 and the second rack 3021 are respectively installed at the bottom of the floating plate 301, the first rack 302 and the second rack 3021 are staggered and symmetrical with each other, two first driving gears 3022 and two second driving gears 3023 are respectively meshed and installed on the first rack 302 and the second rack 3021, the two first driving gears 3022 are respectively installed on the side walls of the mixing drum 2013 on the opposite side, the two second driving gears 3023 are respectively installed on the mixing drum 2013 on the opposite side, and the two first driving gears 3022 and the two second driving gears 3023 are respectively installed on the mixing drum 2013 on the opposite side, and the two first driving gears 3022 and the two second driving gears 3023 are symmetrical with each other. When the floating plate 301 moves downward, it can drive the first rack 302 and the second rack 3021 to move downward, thereby driving the first driving gear 3022 and the second driving gear 3023 to rotate. When the first driving gear 3022 and the second driving gear 3023 rotate, they can respectively drive the mixing drum 2013 to rotate, so that the position of the water spraying component 2016 can be changed, so that water can be sprayed in different directions, so that the efficiency of the quartz sand spraying is further improved, thereby reducing the water consumption.

As shown in Fig. 1 to Fig. 12, further, a second filter plate 2042 is installed at the bottom of the built-in installation cylinder 2012, and a placement hole 2015 is opened in the middle of the second filter plate 2042. The placement hole 2015 runs through the two sealing boxes 202, the built-in installation cylinder 2012, the floating plate 301 and the upper part of the housing 102. In this configuration, the placement hole 2015 is opened.

The implementation principle of a water-saving recoil device for a quartz sand filter in this embodiment is as follows:

First, the staff opens the first valve 103 and the third valve 1032, so that the sewage input in the first water inlet pipe 101 can enter the inner cavity of the shell 102. At this time, the quartz sand set in the inner cavity of the shell 102 can filter the sewage through the quartz sand, so that the filtered clean water can be discharged from the outlet pipe 1012, so that the effect of filtering the sewage can be achieved;

When the quartz sand needs to be washed, the staff closes the first valve 103 and the third valve 1032, opens the second valve 1031 and the fourth valve 1033, and connects the second water inlet pipe 1013 through the water pipe, and then uses the water pump to deliver water, so that clean water can be output from the second water inlet pipe 1013 to the inner cavity of the shell 102;

When clean water enters the shell 102, it can wash the quartz sand (because the water pump can make the water flow faster, so that the quartz sand can be washed when entering the inner cavity of the shell 102). When water enters the inner cavity of the shell 102, it can also enter the inner cavity of the built-in installation cylinder 2012 through the circular hole opened on the second filter plate 2042 installed at the bottom of the built-in installation cylinder 2012 (the diameter of the circular hole opened on the second filter plate 2042 is smaller than the quartz sand). When water enters the built-in installation cylinder 2012, it will enter the inner cavities of the four mixing cylinders 2013.

At this time, the staff starts the asynchronous motor 201, and the asynchronous motor 201 will be able to drive the rotating rod 2011 to rotate. When the rotating rod 2011 rotates, it will be able to drive the first bevel gears 2021 installed in the inner cavities of the two sealing boxes 202 to rotate respectively. When the two first bevel gears 2021 rotate, they will be able to drive the second bevel gear 2022 and the third bevel gear 2023 to rotate respectively. When the second bevel gear 2022 and the third bevel gear 2023 rotate, they will be able to drive the rotating rod 2024 to rotate. When the rotating rod 2024 rotates, it will be able to drive the sleeve 2032 and the circular mounting plate 2033 to move through the guide slot 2031. When the circular When the circular mounting plate 2033 moves, the sleeve 2032 can push the first filter plate 2034 to move horizontally with the assistance of the guide rod 2035, until the first circular mounting plate 2033 enters the mixing drum 2013 and squeezes the water in the mixing drum 2013, so that water can be sprayed from the water spray assembly 2016 provided on the mixing drum 2013, thereby spraying the quartz sand. At the same time, because the rotating rod 2011 can drive the built-in mounting drum 2012 and the mixing drum 2013 to rotate slowly when rotating, the quartz sand can be shaken, so that when spraying the quartz sand, the spraying efficiency is higher, thereby achieving the effect of saving water.

When the circular mounting plate 2033 performs a reset movement with the assistance of the guide chute 2031 and the sliding block, the water in the built-in mounting cylinder 2012 will be filled with water at this time, and because the bottom is still being filled with water, the circular mounting plate 2033 will continue to squeeze when it moves back, so that the water in the built-in mounting cylinder 2012 can be reduced, so that the floating plate 301 arranged above can move horizontally downward with the assistance of the slider 3011 and the chute 3012 in the sliding mechanism. Therefore, when the floating plate 301 moves downward, it can drive the first rack 302 and the second rack 3021 to move downward, thereby driving the first driving gear 3022 and the second driving gear 3023 to rotate. When the first driving gear 3022 and the second driving gear 3023 rotate, they can respectively drive the mixing cylinder 2013 to rotate, so that the position of the water spraying component 2016 can be changed, so that water can be sprayed in different directions, so that the efficiency of quartz sand spraying is further improved, thereby reducing the water consumption;

The stains cleaned from the quartz sand will be able to flow into the sewage pipe 1011 along with the water flow and be discharged from the sewage pipe 1011.

Claims (10)

1. The utility model provides a quartz sand filter water conservation recoil device, includes quartz sand filtration processing unit (100), stirring jet unit (200) and rotates stirring unit (300), its characterized in that, quartz sand filtration processing unit (100) are including casing (102), first inlet tube (101) and blow off pipe (1011) are installed to casing (102) top, outlet pipe (1012) and second inlet tube (1013) are installed to casing (1) bottom, first inlet tube (101) and blow off pipe (1011) are symmetrical each other, outlet pipe (1012) and second inlet tube (1013) are symmetrical each other, four supporting leg (1021) are installed to casing (102) bottom, four between two are symmetrical each other supporting leg (1021), barrier plate (1022) are installed to casing (102) inner chamber bottom;

The stirring and spraying unit (200) comprises a built-in mounting cylinder (2012) and four stirring cylinders (2013), the built-in mounting cylinder (2012) is mounted in an inner cavity of the shell (1), the four stirring cylinders (2013) are rotatably mounted on the side walls of the built-in mounting cylinder (2012), the four stirring cylinders (2013) are symmetrical to each other and are distributed at equal intervals, two opposite side walls of the four stirring cylinders (2013) are respectively provided with a placement hole (2015), each inner cavity of the placement hole (2015) is provided with a water spraying component (2016), the inner cavity of the built-in mounting cylinder (2012) is provided with a transmission mechanism and a spraying mechanism, the transmission mechanism is used for driving the built-in mounting cylinder (2012) to drive the stirring cylinders (2013) to rotate, and the spraying mechanism is used for driving water to be sprayed out from the water spraying components (2016) arranged on each stirring cylinder (2013);

The rotary stirring unit comprises a floating plate (301), wherein the floating plate (301) is arranged above a built-in mounting cylinder (2012), sliding mechanisms are arranged on two opposite side walls of the floating plate (301), a rotating mechanism is arranged at the bottom of the floating plate (301), and the rotating mechanism is used for driving the stirring cylinders (2013) to rotate independently.

2. The water-saving backflushing device of a quartz sand filter according to claim 1, wherein the first water inlet pipe (101), the sewage discharge pipe (1011), the water outlet pipe (1012) and the second water inlet pipe (1013) are respectively provided with a first valve (103), a second valve (1031), a third valve (1032) and a fourth valve (1033).

3. The quartz sand filter water-saving backflushing device according to claim 1, wherein the transmission mechanism comprises an asynchronous motor (201), the asynchronous motor (201) is installed above the shell (102), a rotating rod (2011) is fixedly installed at the output end of the asynchronous motor (201), a bearing (2014) is arranged at the other end of the rotating rod (2011), and the bearing (2014) is installed above the blocking plate (1022).

4. The water-saving backflushing device of the quartz sand filter according to claim 3, wherein two sealing boxes (202) are fixedly installed on each rotating rod (2011), a first bevel gear (2021) is fixedly installed in each inner cavity of each sealing box (202), a second bevel gear (2022) and a third bevel gear (2023) are vertically meshed and installed on two opposite side walls of each first bevel gear (2021), a rotating rod (2024) is fixedly installed on one opposite side wall of each second bevel gear (2022) and one opposite side wall of each third bevel gear (2023), the other end of each rotating rod (2024) is respectively located in each inner cavity of each four stirring cylinders (2013), each rotating rod (2024) movably penetrates through each sealing box (202), a mounting bearing (2036) is installed in each inner cavity of each sealing box (202), a limit rod (203) is installed on each mounting bearing (2036), each other end of each limit rod (202203) is fixedly connected to each guide block (2034) in each sliding way, and each guide block (2031) is fixedly connected to each guide block (2024).

5. The water-saving backflushing device of a quartz sand filter according to claim 1, wherein the spraying mechanism comprises sleeves (2032), a sliding block is connected to an inner cavity of each sleeve (2032), a round mounting plate (2033) is fixedly mounted on each sleeve (2032), a first filter plate (2034) is sleeved on a rotating rod (2024) on one side wall of each round mounting plate (2033) close to a stirring cylinder (2013), and the side wall of each first filter plate (2034) is connected to the inner wall of the stirring cylinder (2013) in a sliding mode.

6. The water-saving backflushing device of the quartz sand filter according to claim 5, wherein a guide rod (2035) is arranged in the inner cavity of each stirring cylinder (2013), one end of each guide rod (2035) is fixedly connected to the side wall of the sealing box (202) respectively, and a first filter plate (2034) and a circular mounting plate (2033) are movably penetrated through each guide rod (2035).

7. The water-saving backflushing device of a quartz sand filter according to claim 1, wherein circular sealing plates (204) are arranged at opposite side wall ports of each stirring cylinder (2013), connecting rods (2043) are arranged at opposite side walls of each circular sealing plate (204), two ends of each connecting rod (2043) are fixedly connected to opposite side walls of each circular sealing plate (204), and handles (2041) are arranged at the bottoms of the circular sealing plates (204).

8. The water-saving backflushing device of the quartz sand filter according to claim 1, wherein the sliding mechanism comprises two sliding grooves (3012), the two sliding grooves (3012) are formed in the side wall of the inner cavity of the built-in mounting cylinder (2012), the two sliding grooves (3012) are symmetrical to each other, sliding blocks (3011) are slidably mounted in the inner cavities of the two sliding grooves (3012), and a floating plate (301) is mounted on the opposite side wall of the two sliding blocks (3011).

9. The water-saving backflushing device of a quartz sand filter according to claim 1, wherein the rotating mechanism comprises a first rack (302) and a second rack (3021), the first rack (302) and the second rack (3021) are respectively arranged at the bottom of the floating plate (301), the first rack (302) and the second rack (3021) are mutually staggered and symmetrical, two first driving gears (3022) and two second driving gears (3023) are respectively arranged on the first rack (302) and the second rack (3021) in a meshed mode, the two first driving gears (3022) are respectively arranged on the side wall of a stirring cylinder (2013) on the opposite side, the two second driving gears (3023) are respectively arranged on the stirring cylinder (2013) on the opposite side, and the two first driving gears (3022) and the two second driving gears (3023) are mutually symmetrical.

10. The water-saving backflushing device of the quartz sand filter according to claim 1, wherein a second filter plate (2042) is installed at the bottom of the built-in installation cylinder (2012), a placement hole (2015) is formed in the middle of the second filter plate (2042), and the placement hole (2015) penetrates through the two sealing boxes (202), the built-in installation cylinder (2012), the floating plate (301) and the shell (102).