CN217535636U - Nano high-efficiency filter material - Google Patents

Abstract

The utility model discloses a high-efficient filter media of nanometer relates to and filters the filter media field, including top net, end net, dust filter otter board, carbon sponge layer and absorption net, the mesh has all been seted up to the top of top net and the bottom of end net, the middle part of top net and end net is equipped with the zip fastener net, the positive swing joint of zip fastener net has zipper head, the contained side has all been seted up to the both sides of top net, the front on contained side is equipped with the protective layer, the positive threaded connection on contained side has the bolt, the positive swing joint of bolt has the bolt head, the one end of bolt runs through the contained side, the one end joint that the bolt runs through the contained side has the board, and this high-efficient filter media of nanometer mainly filters the sewage spot through the three-layer filtration, and the last water purification that obtains can be followed the filtration pore of absorption net bottom and dripped out, and this high-efficient filter media of nanometer has the dismantlement convenience, easy clearance and advantage that filtration efficiency is high more has the practicality.

Description

High-efficient filter media of nanometer

Technical Field

The utility model relates to a filter media field especially relates to a high-efficient filter media of nanometer.

Background

The fiber diameter of common filter materials (such as filter paper, non-woven fabric, melt-blown fabric, activated carbon, glass fiber and the like, and their laminated composite filter materials) is mostly larger than 1 micron, so that it is difficult to meet the requirement of high filtration standard, such as the F9 grade of EN779, and the industry is exploring the method of using electrostatic spinning today: the fiber coating is formed on the base material by using a high-voltage electrostatic field to pull the polymer solution for batch drawing and the like, so that various indexes of the common filter material are improved.

But because the material of filter media all is comparatively frivolous, so lead to the dust holding capacity of filter media lower, also should not clear up simultaneously, prior art has inefficiency, with high costs and the relatively poor problem of practicality moreover, so need a novel high-efficient filter media of nanometer to solve above-mentioned problem.

SUMMERY OF THE UTILITY MODEL

To the above problem, the utility model provides a high-efficient filter media of nanometer.

The technical scheme of the utility model is that: the utility model provides a high-efficient filter media of nanometer, this high-efficient filter media of nanometer mainly filters sewage spot through the three-layer filtration, sewage can at first get into from top net 1, come to filter on the dirt otter board 18 earlier, the dirt otter board 18 mainly is used for filtering the dust granule, the dust granule can be kept apart on the dirt otter board 18, then sewage can continue to fall, the dust granule can be along with the inclination of dirt otter board 18 toward middle part slope, the dust granule can drop in the dust box 20 along with the slope from middle part gap, with this improvement hold the dirt volume, it is also very convenient to take off the clearance after using a period, sewage comes to carbon sponge layer 15 afterwards, carbon sponge layer 15 has the non-absorbent characteristic of oil absorption, can absorb the greasy dirt that probably contains in the sewage, then water can continue to fall in the adsorption net 8, then the active carbon in the adsorption net 8 can adsorb the noxious material and the peculiar smell that contain in the aquatic, the effect of purifying water source has been had been obtained at last, just so all steps of dripping can be accomplished from the filtration pore 12 of adsorption net 8 bottom.

In a further technical scheme, a high-efficient filter media of nanometer, including top net, end net, dust filtration otter board, carbon sponge layer and absorption net, the mesh has all been seted up to the top of top net and the bottom of end net, the middle part of top net and end net is equipped with the zip fastener net, the front swing joint of zip fastener net has the zipper head, the contained side has all been seted up to the both sides of top net, the front of contained side is equipped with the protective layer, the front threaded connection of contained side has the bolt, the front swing joint of bolt has the bolt head, the contained side is run through to the one end of bolt, the one end joint that the bolt runs through contained side has the support board.

In a further technical scheme, both sides the inboard equal joint of contained side has the filter dust sideboard, the equal screwed connection in both sides of filter dust otter board has the filter dust sideboard, the filter dust hole has been seted up at the top of filter dust otter board, the top of filter dust otter board is by both sides toward middle slope, the middle part of filter dust otter board is seted up a five micron gap, the bottom of filter dust otter board is close to screwed connection and is connect the ash pan, connect the gap at ash pan and filter dust otter board middle part to align each other.

In a further technical scheme, a carbon sponge plate is clamped on the front surface of the inner part of the clamping edge, which is close to the dust filtering edge plate, and the two sides of the carbon sponge layer are connected with the carbon sponge plate through screws.

In a further technical scheme, the adsorption edge blocks are clamped in the clamping edges and close to the front surface of the carbon cotton plate, and the adsorption edge blocks are arranged on two sides of the adsorption net.

In a further technical scheme, activated carbon particles are filled in the adsorption net, filter holes are formed in the top of the adsorption net, and the pore diameter of each filter hole is 0.5 micrometer.

In a further technical scheme, a placing opening is formed in one side of the adsorption edge block, a gap is formed in the middle of the adsorption net, the placing opening is communicated with the gap in the middle of the adsorption net, and the aperture of the filter hole is smaller than that of the activated carbon particles.

Through the design of the nano high-efficiency filter material, the technical problems of low dust holding capacity, low efficiency and poor practicability of the existing filter material are solved.

The beneficial effects of the utility model are that:

1. this high-efficient filter media of nanometer mainly filters sewage spot through the three-layer filtration, sewage can at first get into from the top net, come earlier on the filter dust otter board, the filter dust otter board is mainly used for filtering the dust granule, the dust granule can be kept apart on the filter dust otter board, then sewage can continue the whereabouts, the dust granule can be along with the inclination of filter dust otter board toward the middle part slope, the dust granule can be along with the slope in the dust collecting box that drops from the middle part gap, with this improvement hold the dirt volume, it is also very convenient to take off the clearance after using a period, sewage comes on the carbon sponge layer afterwards, the carbon sponge layer has the not absorbent characteristic of oil absorption, can absorb the greasy dirt that probably contains in the sewage, then water can continue to fall to adsorb the interior toxic material and the peculiar smell that contain of aquatic, the effect that has the water purification source, the water purification that obtains at last can be followed the filtration pore drip of adsorption net bottom, all steps have just so completed, this high-efficient installation of nanometer is dismantled conveniently, easy clearance and the filter media is high in the filtration efficiency, more has the practicality.

Drawings

FIG. 1 is a schematic view of the overall structure of a nano high-efficiency filter material according to embodiment 1 of the present invention;

FIG. 2 is a schematic view of the internal structure of a nano high-efficiency filter material according to embodiment 1 of the present invention;

FIG. 3 is a top net structure diagram of a nano high-efficiency filter material according to embodiment 1 of the present invention;

fig. 4 is a block diagram of a nano high-efficiency filter material according to embodiment 1 of the present invention.

Description of reference numerals:

1-top net; 2, mesh; 3-bottom net; 4-zipper net; 5, zipper head; 6, edge clamping; 7-a protective layer; 8-an adsorption net; 9-a resisting plate; 10-bolt head; 11-bolt; 12-filtration pore; 13-adsorption of edge blocks; 14-placing port; 15-a carbon sponge layer; 16-carbon cotton board; 17-dust filtering side plate; 18-a dust filter screen plate; 19-dust filtration holes; 20-ash receiving box.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings.

Example 1:

as shown in figures 1-4, a nanometer high-efficiency filter material comprises a top net 1, a bottom net 3, a dust filtering screen 18, a carbon sponge layer 15 and an adsorption net 8, wherein the top of the top net 1 and the bottom of the bottom net 3 are both provided with meshes 2, the middle parts of the top net 1 and the bottom net 3 are provided with zipper nets 4, the front surfaces of the zipper nets 4 are movably connected with zipper heads 5, both sides of the top net 1 are both provided with clamping edges 6, the front surfaces of the clamping edges 6 are provided with protective layers 7, the front surfaces of the clamping edges 6 are in threaded connection with bolts 11, the front surfaces of the bolts 11 are movably connected with bolt heads 10, one ends of the bolts 11 penetrate through the clamping edges 6, one ends of the bolts 11 penetrating through the clamping edges 6 are clamped with a resisting plate 9, the inner sides of the clamping edges 6 at both sides are clamped with dust filtering side plates 17, both sides of the dust filtering screen 18 are in threaded connection with dust filtering side plates 17, the top of the dust filtering screen 18 is provided with dust filtering holes 19, the top of the dust filtering screen 18 inclines from both sides to the middle part, a gap of five micrometers is formed in the middle part of the dust filtering screen 18, the bottom of the dust filter screen plate 18 is connected with an ash receiving box 20 close to a screw, gaps in the middle parts of the ash receiving box 20 and the dust filter screen plate 18 are aligned with each other, a carbon sponge plate 16 is clamped in the front of the clamping edge 6 close to a dust filter edge plate 17, carbon sponge plates 16 are screwed in both sides of a carbon sponge layer 15, an adsorption edge block 13 is clamped in the front of the carbon sponge plate 16 in the clamping edge 6, adsorption edge blocks 13 are arranged on both sides of an adsorption net 8, activated carbon particles are arranged in the adsorption net 8, filter holes 12 are arranged on the top of the adsorption net 8, the pore diameter of each filter hole 12 is 0.5 micrometer, a placing opening 14 is formed in one side of each adsorption edge block 13, a gap is formed in the middle part of the adsorption net 8, the placing opening 14 is communicated with the gap in the middle part of the adsorption net 8, the pore diameter of each filter hole 12 is smaller than that of the activated carbon particles, and the zipper net 4 and zipper head 5 which need to be explained are made of non-metal materials and are not easy to rust, contain the dirt otter board 18 of straining in the top net 1, carbon sponge layer 15 and adsorption net 8, carbon sponge layer 15 mainly has the concatenation of carbon sponge to form, the oil absorption and not absorb water, be equipped with the active carbon granule mainly used in the adsorption net 8 and adsorb the peculiar smell, the dirt otter board 18 of straining simultaneously, carbon sponge layer 15 and adsorption net 8 are respectively through straining dirt sideboard 17, carbon sponge board 16 and adsorption sideboard 13 joint are in contained limit 6, make bolt 11 rotate at contained limit 6 outside through twisting bolt head 10, the connected mode is threaded connection, clockwise rotation bolt 11 can be along with rotating forward, bolt 11 can drive and support board 9 forward, support board 9 can extrude dirt sideboard 17 forward, carbon sponge board 16 and adsorption sideboard 13, strengthen with this, dirt otter board 18, carbon sponge layer 15 and adsorption net 8 all adopt nanotechnology, dirt filtration hole 19 is 0.2 micron, can effectually filter the dust in the sewage.

The above-mentioned embodiments only express the specific implementation manner of the present invention, and the description thereof is specific and detailed, but not to be understood as the limitation of the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention.

Claims (5)

1. The utility model provides a high-efficient filter media of nanometer, its characterized in that, includes top net and end net, the mesh has all been seted up to the top of top net and the bottom of end net, the middle part of top net and end net is equipped with the zip fastener net, the front swing joint of zip fastener net has the zipper head, the contained side has all been seted up to the both sides of top net, the front on contained side is equipped with the protective layer, the front threaded connection on contained side has the bolt, the front swing joint of bolt has the bolt head, the one end of bolt runs through the contained side, the one end joint that the bolt runs through the contained side has the offset plate, including top net, end net, dust filtration otter board, carbon sponge layer and adsorption net.

2. The nano high-efficiency filter material as claimed in claim 1, wherein the inside of the clamping edges at both sides are clamped with dust filter edge plates, the both sides of the dust filter screen plate are screwed with the dust filter edge plates, the top of the dust filter screen plate is provided with dust filter holes, the top of the dust filter screen plate is inclined from both sides to the middle, the middle of the dust filter screen plate is provided with a five-micron gap, the bottom of the dust filter screen plate is screwed with a dust collecting box near the screws, and the gaps at the middle parts of the dust collecting box and the dust filter screen plate are aligned with each other.

3. The nano high-efficiency filter material as claimed in claim 1, wherein the inside of the clamping edge is clamped with a carbon sponge plate near the front surface of the dust filtering edge plate, and both sides of the carbon sponge layer are connected with the carbon sponge plate by screws.

4. The nano high-efficiency filter material as claimed in claim 1, wherein the inside of the clamping edge is clamped with an adsorption edge block near the front surface of the carbon cotton plate, and both sides of the adsorption net are provided with adsorption edge blocks.

5. The nano high-efficiency filter material as claimed in claim 1, wherein the inside of the adsorption net is filled with activated carbon particles, the top of the adsorption net is provided with filtration pores, and the pore size of the filtration pores is 0.5 μm.

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