CN117180826A

CN117180826A - Glass production wastewater filtering device

Info

Publication number: CN117180826A
Application number: CN202311452094.1A
Authority: CN
Inventors: 马素珍
Original assignee: Nantong Xinlong Glass Products Co ltd
Current assignee: Nantong Xinlong Glass Products Co ltd
Priority date: 2023-11-03
Filing date: 2023-11-03
Publication date: 2023-12-08
Anticipated expiration: 2043-11-03
Also published as: CN117180826B

Abstract

The invention relates to the field of filter devices, in particular to a glass production wastewater filter device. A glass production wastewater filtering device comprises a shell, a filtering component, two driving components and two collecting bins. The filter assembly comprises a filter screen, two lifting shafts, a deflection shaft, a plurality of baffle plates and a telescopic frame. The two lifting shafts are symmetrical, can rotate and can be arranged on the shell in a vertical sliding mode, and the position of the lifting shaft in the initial state is lower than that of the deflection shaft. The filter screen drives the filter screen to rotate when the lifting shaft rotates. The baffle plates are circumferentially and uniformly distributed on the filter screen, the telescopic frame can be folded in half along the middle hinge point, and the hinge point of the telescopic frame is provided with a torsion spring, so that the two ends of the telescopic frame have upward trend. Each driving component is arranged below one lifting shaft and used for driving the lifting shaft to rotate. Each aggregate bin is arranged below one lifting shaft and is used for receiving materials on the filter screen and dredging the blocked filter screen so as to achieve the effect of improving the filtering efficiency.

Description

Glass production wastewater filtering device

Technical Field

The invention relates to the field of filter devices, in particular to a glass production wastewater filter device.

Background

At present, in the glass manufacturing industry, the glass is inevitably damaged in the process of processing or cutting the glass, a large amount of glass slag remains in the production and manufacturing processing wastewater, the glass slag needs to be filtered before the wastewater is purified, and when the glass slag is filtered by the filter screen, the filter screen is easily blocked by the glass slag, so that the filtering efficiency is low.

Disclosure of Invention

The invention provides a glass production wastewater filtering device, which aims to solve the problem of low filtering efficiency of the conventional filtering device.

The invention relates to a glass production wastewater filtering device which adopts the following technical scheme:

the glass production wastewater filtering device comprises a shell, a filtering component, two driving components and two collecting bins; the filtering component comprises a filter screen, two lifting shafts, a deflection shaft, a plurality of baffle plates and a telescopic frame; the deflection shaft is horizontally arranged along the front-back direction and can be installed in the shell in a left-right sliding manner; the two lifting shafts are symmetrically arranged at the left side and the right side of the deflection shaft, are parallel to the deflection shaft, are rotatably arranged on the shell in a vertically sliding manner, and are positioned lower than the deflection shaft in the initial state; the filter screen is in a conveying belt shape and is sleeved on the lifting shaft and the deflection shaft so as to drive the filter screen to rotate when the lifting shaft rotates; the baffle plates are circumferentially and uniformly distributed on the filter screen, and each baffle plate extends along the front-back direction and can be contacted with the left side wall and the right side wall of the shell; the expansion bracket is annular and can expand and contract along the left-right direction; the middle part of the expansion bracket is provided with a hinge point, so that the expansion bracket can be folded in half along the hinge point at the middle part; the telescopic frame is sleeved on the filter screen, and torsion springs are arranged at the hinging points of the telescopic frame so that two ends of the telescopic frame have upward trend; each driving component is arranged below one lifting shaft and is used for driving the lifting shaft to rotate; the driving component on one side is configured to drive the lifting shaft above the lifting shaft to rotate when the lifting shaft on the other side moves upwards to the same height as the deflection shaft, so that the material is conveyed to the other side; each aggregate bin is arranged below one lifting shaft and is used for receiving materials on the filter screen.

Further, the driving assembly comprises a driving impeller, a driving vertical rod and a transmission mechanism; the driving impeller comprises an upper driving ring, a lower driving ring and a plurality of elastic blades; the lower driving ring is rotatably arranged at the bottom of the shell; the axis of the upper driving ring is provided with a plug hole which is coaxially arranged with the lower driving ring; the elastic blades are uniformly distributed along the axial direction of the upper driving ring; the upper end of the elastic blade is connected with the upper driving ring, the lower end of the elastic blade is connected with the lower driving ring, and the initial state of the elastic blade has a certain inclination so that the elastic blade is spirally deformed when the upper driving ring moves downwards; the driving vertical rod is vertically arranged and connected with the lifting shaft through a transmission mechanism, and is slidably inserted in the inserting hole, and the driving vertical rod is provided with a synchronous component, so that when the lifting shaft at the other side moves to the same height as the deflection shaft in the upward direction, the synchronous component drives the driving vertical rod to deform the elastic blade.

Further, the synchronizing assembly includes a lower press ring; the lower pressing ring is fixedly sleeved on the driving vertical rod so that the lower pressing ring is contacted with the upper driving ring when the driving vertical rod is driven downwards to a preset height.

Further, the transmission mechanism comprises a driving cross rod, a transmission belt, a first bevel gear and a second bevel gear; the first bevel gear is arranged above the fixed vertical rod; the driving cross rod is horizontally arranged below one lifting shaft; the second bevel gear is fixedly sleeved on the driving cross rod and meshed with the first bevel gear; the transmission belt is used for connecting the driving cross rod and the lifting shaft.

Further, a driving wheel is arranged on the lifting shaft; the driving wheel is fixedly sleeved on the lifting shaft and is in friction contact with the inner wall of the filter screen.

Further, the aggregate bin is in a rectangular grid shape; the aggregate bin consists of a filter screen, is horizontally arranged and is inserted on the driving vertical rod; the side wall of the aggregate bin is contacted with the side surface of the shell.

Further, a horizontal groove and two vertical grooves are respectively arranged at the front and the rear of the shell; the horizontal grooves are horizontally arranged, and the front end and the rear end of the deflection shaft can be respectively inserted into the corresponding horizontal grooves; the vertical grooves are vertically arranged, and two ends of each lifting shaft can be inserted into the corresponding vertical grooves respectively.

Further, two springs are arranged in each horizontal groove; the two springs are respectively and horizontally arranged at two sides of the deflection shaft; one end of the spring is connected with the deflection shaft, and the other end of the spring is connected with the horizontal groove.

Further, the number of the telescopic frames is two, and the telescopic frames are respectively sleeved on the front side and the rear side of the filter screen.

The beneficial effects of the invention are as follows: the invention relates to a glass production wastewater filtering device, which is provided with a shell, a filtering component, two driving components and two collecting bins. When the right side of the filter screen filters wastewater, materials are piled up on the filter screen on the right side, and the right side of the filter screen descends and the left side ascends. The driving mechanism on the right side drives the lifting shaft to rotate against the potential needle, materials are transported to the left side and conveyed into the collecting bin on the left side, the impact force of water flow on the filter screen on the right side is reduced, and meanwhile the filter screen on the right side is dredged, so that the effect of improving the filtering efficiency is achieved.

Drawings

In order to more clearly illustrate the embodiments of the invention or the technical solutions of the prior art, the drawings which are used in the description of the embodiments or the prior art will be briefly described, it being obvious that the drawings in the description below are only some embodiments of the invention, and that other drawings can be obtained according to these drawings without inventive faculty for a person skilled in the art.

FIG. 1 is a schematic view showing the structure of an embodiment of a glass production wastewater filtering device of the present invention;

FIG. 2 is an enlarged view of a portion of FIG. 1 at A;

FIG. 3 is an isometric front view of an embodiment of a glass manufacturing wastewater filtration device of the present invention;

FIG. 4 is a schematic view showing the structure of a driving assembly of an embodiment of a glass wastewater filtering apparatus according to the present invention;

FIG. 5 is a schematic view showing the operation of a driving impeller of an embodiment of a glass wastewater filtering apparatus according to the present invention;

FIG. 6 is a schematic view showing the internal structure of a housing of an embodiment of a glass wastewater filtering apparatus according to the present invention;

in the figure: 1. a housing; 11. a horizontal slot; 12. a vertical slot; 2. a filter screen; 21. a telescopic frame; 22. a striker plate; 23. a torsion spring; 3. a deflection shaft; 31. a lifting shaft; 311. a driving wheel; 32. a transmission belt; 33. a drive rail; 34. a collecting bin; 35. a spring; 36. a fixed connection ring; 37. a fixing frame; 4. driving the impeller; 41. driving a vertical rod; 42. a limiting ring; 43. a lower pressing ring; 44. an elastic blade; 45. a first bevel gear; 46. and a second bevel gear.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

An embodiment of a glass production wastewater filtering apparatus of the present invention, as shown in fig. 1 to 6, includes a housing 1, a filtering assembly, two driving assemblies, and two collecting bins 34. The casing 1 is the cuboid tube-shape, and the front and back of casing 1 all is equipped with a horizontal groove 11 and two vertical grooves 12, and horizontal groove 11 level sets up, and vertical groove 12 is vertical to be set up.

The filter assembly comprises a filter screen 2, two lifting shafts 31, a deflection shaft 3, a plurality of baffle plates 22 and telescopic frames 21, and two ends of each lifting shaft 31 are respectively inserted into corresponding vertical grooves 12. The deflection shaft 3 is horizontally arranged along the front-rear direction and is installed in the shell 1 in a left-right sliding manner, the front end and the rear end of the deflection shaft 3 are respectively inserted into corresponding horizontal grooves 11, so that the deflection shaft 3 can only slide along the horizontal direction, and two springs 35 are arranged in each horizontal groove 11. Two springs 35 are respectively and horizontally arranged at two sides of the deflection shaft 3; one end of the spring 35 is connected with the deflection shaft 3, the other end is connected with the horizontal groove 11, in an initial state, the spring 35 is in a compressed state, so that when the deflection shaft 3 slides to one side, the spring 35 on the side is compressed and accumulated, and when the spring 35 is released, the deflection shaft 3 is driven to restore to the initial state. The two lifting shafts 31 are symmetrically arranged at the left side and the right side of the deflection shaft 3, the lifting shafts 31 are parallel to the deflection shaft 3, are rotatably and vertically slidably arranged on the shell 1, the position of the lifting shaft 31 in the initial state is lower than that of the deflection shaft 3, and two ends of each lifting shaft 31 can be inserted into corresponding vertical grooves 12 respectively, so that the lifting shafts can only slide up and down. The filter screen 2 is in a conveying belt shape and is sleeved on the lifting shaft 31 and the deflection shaft 3 so as to drive the filter screen 2 to rotate when the lifting shaft 31 rotates, and a driving wheel 311 is arranged on the lifting shaft 31. The driving wheel 311 is fixedly sleeved on the lifting shaft 31 and is in friction contact with the inner wall of the filter screen so as to drive the filter screen 2 to rotate when the lifting shaft 31 rotates. Meanwhile, when the lifting shaft 31 slides downwards, the distance between the corresponding lifting shaft 31 and the deflection shaft 3 gradually increases, and when the filter screen 2 is in the horizontal position, the height of the lifting shaft 31 is consistent with the height of the deflection shaft 3, and at the moment, the distance between the deflection shaft 3 and the lifting shaft 31 is shortest. Since the filter screen 2 has no elasticity, the lifting shaft 31 can only slide up and down along the vertical groove 12, so that when the lifting shaft 31 on one side drives the corresponding filter screen 2 on one side to slide down, the lifting shaft 31 on the other side and the corresponding filter screen 2 on the corresponding side slide up along the vertical groove 12. The plurality of striker plates 22 are circumferentially and uniformly distributed on the filter screen 2, each striker plate 22 extends along the front-rear direction and can contact with the left and right side walls of the shell 1 so that materials drop downwards from the lower side of the filter screen 2, and the striker plates 22 are used for conveying glass residues when the filter screen 2 rotates. The telescopic frame 21 is annular, specifically, the upper telescopic rod and the lower telescopic rod of the telescopic frame 21 are linear rods, and the left side and the right side of the telescopic frame are semicircular and can stretch in the left-right direction; a hinge point is arranged in the middle of the expansion bracket 21, so that the expansion bracket 21 can be folded in half along the hinge point in the middle; the telescopic frame 21 is sleeved on the filter screen 2, the filter screen 2 can slide relative to the lifting shaft 31, and a torsion spring 23 is arranged at a hinge point of the telescopic frame 21 so that when the distance between the lifting shaft 31 and the deflection shaft 3 on one side is increased, the telescopic rod on the telescopic frame 21 on the corresponding side is extended, and when the distance between the lifting shaft 31 and the deflection shaft 3 on one side is decreased, the telescopic rod on the telescopic frame 21 on the corresponding side is shortened. Specifically, the hinge points on the upper side and the lower side are all provided with torsion springs 23, the torsion springs 23 are connected with the hinge frames on the two sides of the hinge points, and the initial lower torsion springs 23 store force so that the two ends of the telescopic frame 21 have upward trend. The two telescopic frames 21 are respectively sleeved on the front side and the rear side of the filter screen 2.

The driving components are arranged below the two lifting shafts 31 and used for driving the lifting shafts 31 to rotate. The driving assembly is configured to drive the lifting shaft 31 above the lifting shaft 31 to rotate when the lifting shaft 31 on the other side moves upwards to be at the same height as the deflection shaft 3, so that the material is conveyed to the other side, and the material is conveyed from the lower side to the higher side, so that the damage caused by the overlarge pressure on one side of the filter screen 2 is prevented. The below at two lift axles 31 all is provided with aggregate bin 34 for receive the material on the filter screen 2, the aggregate bin 34 on left side collects the material that the right side filter screen 2 produced, and the aggregate bin 34 on right side collects the material that the left side filter screen 2 produced. The collecting bin 34 is composed of a filter screen and is horizontally arranged; the side wall of the aggregate bin 34 is in contact with the side face of the housing 1.

In this embodiment, as shown in fig. 1 to 5, the driving assembly includes a driving impeller 4, a driving vertical rod 41, and a transmission mechanism. The drive impeller 4 includes an upper drive ring, a lower drive ring, and a plurality of resilient blades 44. The lower driving ring is rotatably arranged at the bottom of the shell 1, a mounting plate is arranged at the bottom of the shell 1, and the lower driving ring is rotatably mounted on the mounting plate. The axle center of the upper driving ring is provided with a plug hole which is coaxially arranged with the lower driving ring and is positioned above the lower driving ring. The plurality of elastic blades 44 are uniformly distributed along the axial direction of the upper driving ring. The elastic blades 44 are of an elastic plate-shaped structure, the upper ends of the elastic blades 44 are connected with the upper driving ring, the lower ends of the elastic blades 44 are connected with the lower driving ring, the initial state of the elastic blades 44 is inclined to a certain degree, the inclination angle is small, the elastic blades 44 are spirally deformed when the upper driving ring moves downwards, when water flow falls from the upper side, impact force is generated on the elastic blades 44, so that the driving impeller 4 rotates, and when the deformation amount of the elastic blades 44 is large, the rotating speed of the driving impeller 4 is higher. The driving vertical rod 41 is vertically arranged and is connected with the lifting shaft 31 through a transmission mechanism, the driving vertical rod 41 is slidably inserted in the inserting hole, and the driving vertical rod 41 is provided with a synchronous component, so that when the lifting shaft 31 at the other side moves upwards to be at the same height as the deflection shaft 3, the synchronous component drives the driving vertical rod 41 to deform the elastic blade 44, and then the driving impeller 4 rotates. The right driving impeller 4 rotates to drive the lifting shaft 31 to rotate anticlockwise through the transmission mechanism, and the left driving impeller 4 rotates to drive the lifting shaft 31 to rotate clockwise through the transmission mechanism. The driving vertical rod 41 is fixedly sleeved with a limiting ring 42, the collecting bin 34 is sleeved on the driving vertical rod 41 and is contacted with the limiting ring 42, and the limiting ring 42 limits the position of the collecting bin 34 on the driving vertical rod 41. The synchronizing assembly includes a lower press ring 43. The lower pressing ring 43 is fixedly sleeved on the driving vertical rod 41, so that when the driving vertical rod 41 moves downwards to a preset height, the lower pressing ring 43 is contacted with the upper driving ring. The transmission mechanism includes a drive rail 33, a drive belt 32, a first bevel gear 45 and a second bevel gear 46. The first bevel gear 45 is disposed above the driving vertical bar 41. The driving cross bar 33 is horizontally arranged below one lifting shaft 31, and both ends of the driving cross bar 33 and both ends of the lifting shaft 31 are provided with fixed connecting rings 36. Meanwhile, a fixing frame 37 is arranged at the upper end of the driving vertical rod 41, and the driving cross rod 33 is rotatably arranged on the driving frame. The second bevel gear 46 is fixedly sleeved on the driving cross bar 33 and is meshed with the first bevel gear 45. The belt 32 is used to connect the drive rail 33 and the lifting shaft 31.

When the filter screen 2 works, the wastewater containing glass slag is discharged into the shell 1, and when the flow rate of water flow on the right side of the filter screen 2 is large, the filter screen 2 on the right side filters the wastewater. When the flow rate of the water flow on the left side of the filter screen 2 is large, the filter screen 2 on the left side filters the wastewater.

When the flow of the water flow on the right side of the filter screen 2 is large, the water flow generated by the wastewater continuously impacts the right side of the filter screen 2, so that the filter screen 2 on the right side filters the wastewater, and glass residues are accumulated on the right side of the filter screen 2. The accumulated glass slag is gradually increased, so that the right side of the filter screen 2 moves downwards under the action of gravity, the lifting shaft 31 on the right side slides downwards along the vertical groove 12, and meanwhile, the lifting shaft 31 on the left side is driven to move upwards. The angle of the right end downward inclination of the expansion bracket 21 increases, and the left end tends to be in a horizontal state, so that the right end of the expansion bracket 21 is lengthened, and the left end is shortened. Meanwhile, in the process of descending the right lifting shaft 31, the driving vertical rod 41 is driven to move downwards relative to the upper driving ring, and when the left lifting shaft 31 ascends to be at the same height as the deflection shaft 3, namely, the left filter screen 2 is in a horizontal state, and the right lower pressing ring 43 is in contact with the right upper driving ring.

The lower pressing ring 43 moves downwards to deform the right elastic blade 44, and as the material is accumulated on the right side of the filter screen 2, the bending angle of the right elastic blade 44 becomes larger. The water flow drives the right driving impeller 4 to rotate from top to bottom, and the larger the bending angle of the elastic blades 44 is, the faster the water flow drives the corresponding driving impeller 4 to rotate.

The impeller 4 is driven to rotate to drive the vertical rod 41 to rotate, the first bevel gear 45 is driven to rotate to drive the second bevel gear 46 to rotate, the driving cross rod 33 is driven to rotate to drive the transmission belt 32 to rotate, the right lifting shaft 31 is driven to rotate anticlockwise, the right lifting shaft 31 is driven to move glass residues to the left, and the glass residues are collected in the collecting bin 34 on the left under the action of the baffle plate 22 so as to relieve the water flow impact force of the right filter screen 2. Meanwhile, when the glass slag attached to the filter screen 2 is brought to the back by the rotation of the filter screen 2, the glass slag attached to the filter screen 2 is flushed away under the flushing of water flow from top to bottom, so that the problem that the glass slag cannot fall off due to the adsorption on the filter screen 2 is solved.

When the flow rate of the water flow on the left side of the filter screen 2 is large, the water flow impacts the left side of the filter screen 2, glass slag gathers on the left side of the filter screen 2, and the working process is the same as above.

The foregoing description of the preferred embodiments of the invention is not intended to be limiting, but rather is intended to cover all modifications, equivalents, alternatives, and improvements that fall within the spirit and scope of the invention.

Claims

1. The utility model provides a glass production wastewater filter equipment which characterized in that: comprising the following steps:

a housing;

the filtering assembly comprises a filter screen, two lifting shafts, a deflection shaft, a plurality of baffle plates and a telescopic frame; the deflection shaft is horizontally arranged along the front-back direction and can be installed in the shell in a left-right sliding manner; the two lifting shafts are symmetrically arranged at the left side and the right side of the deflection shaft, are parallel to the deflection shaft, are rotatably arranged on the shell in a vertically sliding manner, and are positioned lower than the deflection shaft in the initial state; the filter screen is in a conveying belt shape and is sleeved on the lifting shaft and the deflection shaft so as to drive the filter screen to rotate when the lifting shaft rotates; the baffle plates are circumferentially and uniformly distributed on the filter screen, and each baffle plate extends along the front-back direction and can be contacted with the left side wall and the right side wall of the shell; the expansion bracket is annular and can expand and contract along the left-right direction; the middle part of the expansion bracket is provided with a hinge point, so that the expansion bracket can be folded in half along the hinge point at the middle part; the telescopic frame is sleeved on the filter screen, and torsion springs are arranged at the hinging points of the telescopic frame so that two ends of the telescopic frame have upward trend;

the two driving assemblies are arranged below one lifting shaft and are used for driving the lifting shaft to rotate; the driving component on one side is configured to drive the lifting shaft above the lifting shaft to rotate when the lifting shaft on the other side moves upwards to the same height as the deflection shaft, so that the material is conveyed to the other side;

and the two collecting bins are arranged below one lifting shaft and are used for receiving materials on the filter screen.

2. The glass production wastewater filtering device according to claim 1, wherein:

the driving assembly comprises a driving impeller, a driving vertical rod and a transmission mechanism; the driving impeller comprises an upper driving ring, a lower driving ring and a plurality of elastic blades; the lower driving ring is rotatably arranged at the bottom of the shell; the axis of the upper driving ring is provided with a plug hole which is coaxially arranged with the lower driving ring; the elastic blades are uniformly distributed along the axial direction of the upper driving ring; the upper end of the elastic blade is connected with the upper driving ring, the lower end of the elastic blade is connected with the lower driving ring, and the initial state of the elastic blade has a certain inclination so that the elastic blade is spirally deformed when the upper driving ring moves downwards; the driving vertical rod is vertically arranged and connected with the lifting shaft through a transmission mechanism, and is slidably inserted in the inserting hole, and the driving vertical rod is provided with a synchronous component, so that when the lifting shaft at the other side moves to the same height as the deflection shaft in the upward direction, the synchronous component drives the driving vertical rod to deform the elastic blade.

3. The glass production wastewater filtering device according to claim 2, wherein:

the synchronous assembly comprises a lower pressing ring; the lower pressing ring is fixedly sleeved on the driving vertical rod so that the lower pressing ring is contacted with the upper driving ring when the driving vertical rod is driven downwards to a preset height.

4. The glass production wastewater filtering device according to claim 2, wherein:

the transmission mechanism comprises a driving cross rod, a transmission belt, a first bevel gear and a second bevel gear; the first bevel gear is arranged above the fixed vertical rod; the driving cross rod is horizontally arranged below one lifting shaft; the second bevel gear is fixedly sleeved on the driving cross rod and meshed with the first bevel gear; the transmission belt is used for connecting the driving cross rod and the lifting shaft.

5. The glass production wastewater filtering device according to claim 1, wherein:

the lifting shaft is provided with a driving wheel; the driving wheel is fixedly sleeved on the lifting shaft and is in friction contact with the inner wall of the filter screen.

6. The glass production wastewater filtering device according to claim 2, wherein:

the collecting bin is in a rectangular basket shape; the aggregate bin consists of a filter screen, is horizontally arranged and is inserted on the driving vertical rod; the side wall of the aggregate bin is contacted with the side surface of the shell.

7. The glass production wastewater filtering device according to claim 1, wherein:

the front and the back of the shell are respectively provided with a horizontal groove and two vertical grooves; the horizontal grooves are horizontally arranged, and the front end and the rear end of the deflection shaft can be respectively inserted into the corresponding horizontal grooves; the vertical grooves are vertically arranged, and two ends of each lifting shaft can be inserted into the corresponding vertical grooves respectively.

8. The glass production wastewater filtering device according to claim 7, wherein:

two springs are arranged in each horizontal groove; the two springs are respectively and horizontally arranged at two sides of the deflection shaft; one end of the spring is connected with the deflection shaft, and the other end of the spring is connected with the horizontal groove.

9. The glass production wastewater filtering device according to claim 1, wherein:

the two telescopic frames are respectively sleeved on the front side and the rear side of the filter screen.