CN211813966U

CN211813966U - Strong magnetic antiscale water purifier

Info

Publication number: CN211813966U
Application number: CN201922457733.9U
Authority: CN
Inventors: 殷现国; 耿彬华
Original assignee: Hebei Fried Environmental Technology Co ltd
Current assignee: Fred Environmental Technology Co.,Ltd.
Priority date: 2019-12-31
Filing date: 2019-12-31
Publication date: 2020-10-30
Anticipated expiration: 2029-12-31

Abstract

The utility model provides a strong magnetic antiscale water purifier, which comprises a shell, a PPF filter, a granular activated carbon filter, a sintered activated carbon filter, a strong magnetic processor, a reverse osmosis membrane filter and a T33 activated carbon filter, wherein a water inlet pipe is arranged at one side of the shell, and the water inlet pipe, the PPF filter, the granular activated carbon filter, the sintered activated carbon filter, the strong magnetic processor, the reverse osmosis membrane filter and the T33 activated carbon filter are sequentially connected according to the direction of water flow; a water storage barrel is communicated between the reverse osmosis membrane filter and the T33 activated carbon filter, and the outlet end of the T33 activated carbon filter is communicated with a water outlet pipe; the strong magnetic processor comprises an inner tube, a limiting sleeve and a protective barrel, and a plurality of pairs of magnet blocks are embedded on the limiting sleeve; the inlet end of the inner pipe is provided with a guide cylinder. The utility model discloses can prolong reverse osmosis membrane filter's life and go out water safety.

Description

Strong magnetic antiscale water purifier

Technical Field

The utility model relates to a water treatment device, in particular to a strong magnetic antiscale water purifier.

Background

Along with the improvement of the living standard of people, the requirements of people on safety and sanitation of water resources are increasingly improved, and water purification machines are used by more and more families. At present, a reverse osmosis device with an RO (reverse osmosis) membrane is arranged in a water purifier, so that viruses and bacteria can be effectively filtered, and filtered water can be purified to be directly drunk. However, the RO membrane in the reverse osmosis device is easy to scale, so that the water yield is reduced and the energy consumption is increased, and even the RO membrane fails in advance due to a serious structure, thereby bringing great economic loss to users.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a strong magnetism scale control water purification machine to solve the problem that the RO membrane in the reverse osmosis unit that current water purification machine exists is easy to scale deposit.

The utility model discloses a realize like this:

a strong-magnetic antiscale water purifier is characterized by comprising a shell, a PPF (polypropylene fluoride) filter, a granular activated carbon filter, a sintered activated carbon filter, a strong magnetic processor, a reverse osmosis membrane filter and a T33 activated carbon filter, wherein a water inlet pipe is arranged on one side of the shell, and the water inlet pipe, the PPF filter, the granular activated carbon filter, the sintered activated carbon filter, the strong magnetic processor, the reverse osmosis membrane filter and the T33 activated carbon filter are sequentially connected through a pipeline according to the direction of water flow;

a water storage barrel is communicated between the reverse osmosis membrane filter and the T33 activated carbon filter, the inlet end of the water storage barrel is communicated with the reverse osmosis membrane filter, the outlet end of the water storage barrel is communicated with the inlet end of the T33 activated carbon filter, and the outlet end of the T33 activated carbon filter is communicated with a water outlet pipe;

the strong magnetic processor comprises an inner tube, a limiting sleeve sleeved on the outer side wall of the inner tube and a protection cylinder sleeved on the outer side wall of the limiting sleeve, wherein a plurality of pairs of magnet blocks are embedded on the limiting sleeve along the axial direction of the limiting sleeve; and a guide cylinder is arranged at the inlet end of the inner pipe, and the inner diameter of the inlet end of the guide cylinder is larger than that of the outlet end of the guide cylinder.

The inlet end and the outlet end of the inner tube are both closed, the inlet end of the inner tube is provided with a liquid inlet tube communicated with the inside of the inner tube, and the outlet end of the inner tube is provided with a liquid outlet tube communicated with the inside of the inner tube.

The outlet end of the inner tube is provided with a turbulence cylinder, and the inner diameter of the inlet end of the turbulence cylinder is smaller than that of the outlet end of the turbulence cylinder.

The magnet piece with the lateral wall laminating setting of inner tube.

The magnet piece is arc neodymium iron boron magnet piece.

And the two axial ends of the protection cylinder are respectively provided with a sealing cover, and the sealing covers are fixedly connected with the corresponding ends of the protection cylinder through screws.

The utility model has the advantages that:

when water passes through the strong magnetic processor, the water becomes magnetized water, the water which is magnetized instantly has high solubility and strong permeability, and the water scale separated out from the reverse osmosis membrane filter is easily decomposed by the magnetized water, does not adhere to the wall by cohesive mass, but suspends or sinks. In addition, the scale generated in the reverse osmosis membrane filter can gradually crack and fall off under the washing of the magnetized water, so that the service life of the reverse osmosis membrane filter can be prolonged, and the water outlet safety can be improved.

Drawings

Fig. 1 is a schematic structural diagram of the present invention;

FIG. 2 is a schematic diagram of the construction of a ferromagnetic processor;

FIG. 3 is a view taken along A-A of FIG. 2 with the spoiler removed.

In the figure: 1. a housing; 2. a PPF filter; 3. a granular activated carbon filter; 4. sintering the activated carbon filter; 5. a reverse osmosis membrane filter; 6. a T33 carbon filter; 7. a water inlet pipe; 8. a water outlet pipe; 9. a ferromagnetic processor; 10. a water storage barrel; 11. a waste water discharge pipe; 12. a support frame; 91. an inner tube; 92. a limiting sleeve; 93. a protective cylinder; 94. a magnet block; 95. a draft tube; 96. a turbulence cylinder; 97. a liquid inlet pipe; 98. a liquid outlet pipe; 99. and (7) sealing the cover.

Detailed Description

The present invention is further illustrated by the following examples, which are given by way of illustration only and are not intended to limit the scope of the present invention in any way.

As shown in fig. 1, the utility model discloses a casing 1, PPF filter 2, granular activated carbon filter 3, sintering activated carbon filter 4, strong magnetism treater 9, reverse osmosis membrane filter 5 and T33 activated carbon filter 6 set up inlet tube 7 in one side of casing 1, inlet tube 7, PPF filter 2, granular activated carbon filter 3, sintering activated carbon filter 4, strong magnetism treater 9, reverse osmosis membrane filter 5 and T33 activated carbon filter 6 connect gradually through the pipeline according to the direction of rivers. In the T33 activated carbon filter 6, T33 is the name of activated carbon core, and T33 activated carbon filter 6 is used in post-filtration of water purification equipment, and in this embodiment, T33 activated carbon filter 6 is also called post-activated carbon filter. The reverse osmosis membrane filter 5 includes a membrane housing and an RO membrane (not shown in the drawing) disposed inside the membrane housing. The strong magnetic processor 9 is communicated and arranged between the sintered activated carbon filter 4 and the reverse osmosis membrane filter 5. The water storage barrel 10 is communicated between the reverse osmosis membrane filter 5 and the T33 activated carbon filter 6, the water storage barrel 10 is arranged at the bottom in the shell 1, and in the embodiment in the market, the water storage barrel 10 is positioned at the right side of the bottom in the shell 1. The inlet end of the water storage barrel 10 is communicated with the outlet end of the reverse osmosis membrane filter 5, namely, the inlet end of the water storage barrel 10 is communicated with the water producing end of the reverse osmosis membrane filter 5, the outlet end of the water storage barrel 10 is communicated with the inlet end of the T33 activated carbon filter 6. in the embodiment, the inlet end of the water storage barrel 10 is arranged at the lower part of the water storage barrel 10, and the outlet end of the water storage barrel 10 is arranged at the upper part of the water storage barrel 10. The outlet end of the T33 activated carbon filter 6 is communicated with a water outlet pipe 8. The water outlet pipe 8 extends to the outside of the shell 1, namely the outlet end of the water outlet pipe 8 extends to the outside of the shell 1. The reverse osmosis membrane filter 5 is provided with a waste water discharge pipe 11.

In this embodiment, a support frame 12 is disposed at the middle upper portion in the housing 1, and a storage slot is recessed downward at one side of the support frame 12, and in this embodiment, a storage slot is recessed downward at the left side of the support frame 12. PPF filter 2, granular activated carbon filter 3 and sintered activated carbon filter 4 all vertically set up should put the thing inslot, and PPF filter 2, granular activated carbon filter 3 and sintered activated carbon filter 4 are arranged by a left side to the right side in proper order. The strong magnetic processor 9 and the reverse osmosis membrane filter 5 are horizontally disposed at an upper portion in the housing 1. The T33 carbon filter 6 is horizontally disposed at a lower portion in the housing 1, and the T33 carbon filter 6 is located below the support frame 12. In this embodiment, the reverse osmosis membrane filter 5, the T33 activated carbon filter 6 and the ferromagnetic processor 9 can be all fixedly connected to the inner side wall of the corresponding side of the casing 1 through the connecting assembly, and the connecting assembly can be a connecting structure common in the prior art, such as connecting plates (not shown in the figure) disposed between the inner side walls of the corresponding sides of the reverse osmosis membrane filter 5 and the casing, between the inner side walls of the corresponding sides of the T33 activated carbon filter 6 and the casing, and between the inner side walls of the corresponding sides of the ferromagnetic processor 9 and the casing.

As shown in fig. 2 and fig. 3, the ferromagnetic processor 9 includes an inner tube 91, a limiting sleeve 92 sleeved on the outer side wall of the inner tube 91, and a protecting cylinder 93 sleeved on the outer side wall of the limiting sleeve 92, wherein a plurality of pairs of magnet blocks 94 are embedded on the limiting sleeve 92 along the axial direction thereof, the magnet blocks 94 are attached to the outer side wall of the inner tube 91, in this embodiment, the number of the ferromagnetic blocks 94 is 4, and the ferromagnetic block 94 at the inlet end of the inner tube 91 is close to the inlet end of the inner tube 91, that is, the right end face of the ferromagnetic block 94 at the right end of the inner tube 91 is located above the inlet end and the outlet end of the guiding cylinder 95. The magnet blocks 94 are arc neodymium iron boron magnet blocks 94, each pair of magnet blocks 94 are arranged oppositely in the vertical direction, the magnet block 94 arranged at the upper part of the inner tube 91 is an N-pole magnet, and the magnet block 94 arranged at the lower part of the inner tube 91 is an S-pole magnet. The inlet end and the outlet end of the inner tube 91 are both closed, the inlet end of the inner tube 91 is provided with a liquid inlet pipe 97 communicated with the inside of the inner tube 91, and the outlet end of the inner tube 91 is provided with a liquid outlet pipe 98 communicated with the inside of the inner tube 91. A guide cylinder 95 is provided at an inlet end of the inner tube 91, and an inner diameter of the inlet end of the guide cylinder 95 is larger than an inner diameter of an outlet end thereof. The inner diameter of the liquid inlet pipe 97 is between the maximum inner diameter and the minimum inner diameter of the guide cylinder 95, in this embodiment, the right end of the inner pipe 91 is the inlet end thereof, the left end of the inner pipe 91 is the outlet end thereof, the guide cylinder 95 is arranged at the right end of the inner pipe 91, and the inner diameter of the right end of the guide cylinder 95 is larger than that of the left end thereof. The outlet end of the inner tube 91 is provided with a turbulence cylinder 96, namely the turbulence cylinder 96 is arranged at the left end of the inner tube 91, and the inner diameter of the inlet end of the turbulence cylinder 96 is smaller than that of the outlet end thereof. In the present embodiment, the right end of the spoiler 96 has an inner diameter smaller than that of the left end thereof. The arrangement of the guide cylinder 95 can increase the flow velocity of water entering the inner tube 91, and can better meet the requirement of the magnet block 94 on the flow velocity of the magnetized water. The turbulent flow cylinder 96 is arranged to reduce the flow velocity of the magnetized water at the position, and to form turbulent flow of the water, so that the water can be sufficiently magnetized in the inner pipe, the flow velocity of the magnetized water entering the reverse osmosis membrane filter 5 can be reduced, and the magnetized water can be sufficiently contacted with the reverse osmosis membrane filter 5. The inner tube 91, the limiting sleeve 92 and the protective cylinder 93 are all made of non-magnetic materials. The inner tube 91 is a PPR tube, and the limiting sleeve 92 and the protective sleeve 93 are stainless steel sleeves. The structure that the magnet block 94 is embedded in the limiting sleeve 92 is as follows: a plurality of through grooves for accommodating the magnet blocks 94 are uniformly formed in the limiting sleeve 92 along the axial direction thereof. Therefore, the limiting sleeve 92 can clamp the magnet block 94 to a certain position, the magnet block 94 does not need to be fixedly connected with the inner tube 91 through other fixing pieces, and the magnet block 94 is convenient to replace due to the arrangement of the structure. The two axial ends of the protection cylinder 93 are both provided with sealing covers 99, and the sealing covers 99 are fixedly connected with the corresponding ends of the protection cylinder 93 through screws. The one end that meets with feed liquor pipe 97 of protection section of thick bamboo 93 is seted up and is used for holding the through-hole that feed liquor pipe 97 passed, and the one end that meets with drain pipe 98 of protection section of thick bamboo 93 is seted up and is used for holding the through-hole that drain pipe 98 passed. The inner diameter of the protective cylinder 93 is slightly larger than the outer diameter of the limiting sleeve 92, so that the protective cylinder 93 can be conveniently disassembled and assembled. When the magnet block 94 is replaced, the sealing covers 99 at the two ends are taken down, and then the protective cylinder 93 is taken down, so that the magnet block 94 can be conveniently detached.

The above description in this specification is merely illustrative of the present invention. Various modifications, additions and substitutions may be made by those skilled in the art without departing from the scope of the invention as defined in the accompanying claims.

Claims

1. A strong-magnetic antiscale water purifier is characterized by comprising a shell, a PPF (polypropylene fluoride) filter, a granular activated carbon filter, a sintered activated carbon filter, a strong magnetic processor, a reverse osmosis membrane filter and a T33 activated carbon filter, wherein a water inlet pipe is arranged on one side of the shell, and the water inlet pipe, the PPF filter, the granular activated carbon filter, the sintered activated carbon filter, the strong magnetic processor, the reverse osmosis membrane filter and the T33 activated carbon filter are sequentially connected through a pipeline according to the direction of water flow;

2. The strong magnetic antiscale water purifier as recited in claim 1, wherein the inlet end and the outlet end of the inner tube are closed, the inlet end of the inner tube is provided with a liquid inlet tube communicated with the inside of the inner tube, and the outlet end of the inner tube is provided with a liquid outlet tube communicated with the inside of the inner tube.

3. The strong magnetic antiscale water purifier as recited in claim 1, wherein a turbulence cylinder is provided at the outlet end of said inner tube, and the inner diameter of the inlet end of said turbulence cylinder is smaller than the inner diameter of the outlet end thereof.

4. The strong magnetic antiscale water purifier as recited in claim 1, wherein said magnet block is attached to the outer sidewall of said inner tube.

5. The strong magnetic antiscale water purifier as recited in claim 1, wherein said magnet is an arc-shaped neodymium iron boron magnet.

6. The strong magnetic antiscale water purifier as recited in claim 1, wherein both axial ends of the protective cylinder are provided with a sealing cover, and the sealing covers are fixedly connected with the corresponding ends of the protective cylinder through screws.