CN210438458U

CN210438458U - Energy-saving anti-pollution membrane assembly

Info

Publication number: CN210438458U
Application number: CN201920818254.2U
Authority: CN
Inventors: 何铁峰; 薛向东; 李凤娥
Original assignee: SUZHOU INTER INDUSTRIAL WATER TREATMENT ENGINEERING CO LTD
Current assignee: SUZHOU INTER INDUSTRIAL WATER TREATMENT ENGINEERING CO LTD
Priority date: 2019-05-31
Filing date: 2019-05-31
Publication date: 2020-05-01
Anticipated expiration: 2029-05-31

Abstract

The utility model discloses an energy-saving anti-fouling membrane component, which comprises a first joint, a second joint, a third joint, a tube and an air distribution port, wherein the first joint and the third joint are the same in structure and are symmetrically distributed at two ends of the tube; the air distribution port comprises an external air inlet, a groove and an internal air inlet, the external air inlet is arranged on the outer side pipe wall of the first joint, the groove is formed in the inner side of the pipe wall of the first joint, and the external air inlet is located on the groove and communicated with the groove. The utility model discloses can externally the air inlet ventilate, can make gaseous even entering first joint or the third joint through recess and inside air inlet to mix with the water in first joint or the third joint, form even aqueous vapor mixture.

Description

Energy-saving anti-pollution membrane assembly

Technical Field

The utility model relates to an energy-conserving anti-soil type membrane module belongs to membrane module technical field for the water treatment.

Background

With the development of urban ecological process, the water quality requirements of water system renovation projects are increasingly raised. At present, a domestic sewage collection system is not complete, and the self-purification capacity of a river channel is reduced and the water environment is deteriorated due to the random discharge of industrial, agricultural and domestic sewage in the river channel water body. Therefore, engineering measures are needed to treat the riverway with poor water quality and improve the regional water environment. The existing sewage treatment methods are divided into a physical method and a chemical method, the chemical method needs to add various reagents to adjust the pH value of the sewage and treat organic matters contained in the sewage during the treatment, and the sewage treatment in various regions cannot be met by adopting the same set of equipment due to different sewage components in different regions, so that a large amount of cost is increased if the treatment method is designed for each region; in the physical method, the existing equipment is very complex and huge, the applicability is too low, and certain difficulty exists in application, so how to develop a simple sewage treatment structure becomes the research direction of the technicians in the field.

Disclosure of Invention

The utility model aims at providing an energy-conserving anti-soil type membrane module, this energy-conserving anti-soil type membrane module can ventilate at external air inlet, can make gaseous first joint or the third joint of evenly getting into through recess and inside air inlet to mix with the water in first joint or the third joint, form even aqueous vapor mixture.

In order to achieve the above purpose, the utility model adopts the technical scheme that: an energy-saving anti-fouling membrane component comprises a first joint, a second joint, a third joint, a tube shell and an air distribution port, wherein the first joint and the third joint are the same in structure and are symmetrically distributed at two ends of the tube shell;

the air distribution port comprises an external air inlet, a groove and an internal air inlet, the external air inlet is arranged on the outer side pipe wall of the first joint, the groove is arranged on the inner side of the pipe wall of the first joint, the external air inlet is located on the groove and communicated with the groove, a plurality of internal air inlets are distributed on the pipe shell opposite to the groove, and the internal air inlets penetrate into the pipe shell.

The further improved scheme in the technical scheme is as follows:

1. in the above scheme, the first joint, the second joint and the third joint are respectively provided with a first interface, a second interface and a third interface, and the first interface, the second interface and the third interface are communicated with the inside of the pipe shell.

2. In the above scheme, the inner air inlets are distributed in a row along the circumferential direction of the pipe shell.

3. In the above scheme, two rows of the internal air inlets are distributed along the circumferential direction of the pipe shell.

4. In the scheme, the end parts of the filtering membrane tubes are fixed at the end parts of the tube shells through sealing glue, and the sealing glue is filled between the end parts of the filtering membrane tubes.

5. In the scheme, the aperture size of the inner air inlet is 0.2-2 mm.

6. In the above scheme, the first joint and the second joint are respectively provided with two external air inlets, the external air inlets on the first joint are radially and symmetrically distributed, and the external air inlets on the second joint are radially and symmetrically distributed.

7. In the scheme, the filtering membrane tubes are uniformly distributed in the tube shell, and gaps are formed between the filtering membrane tubes.

Because of above-mentioned technical scheme's application, compared with the prior art, the utility model have the following advantage:

1. the utility model discloses energy-conserving anti-soil type membrane module, it includes first joint, second joint, third joint, tube and cloth gas port, first joint and third joint are the same, and the symmetric distribution is connected at tube both ends, and the symmetric design can make this membrane module more convenient when using, need not distinguish the installation direction; the air distribution port comprises an external air inlet, a groove and an internal air inlet, the external air inlet is arranged on the outer pipe wall of the first joint, the groove is formed in the inner side of the pipe wall of the first joint, the external air inlet is located on the groove and communicated with the groove, a plurality of internal air inlets are distributed on the pipe shell right opposite to the groove, the internal air inlets penetrate into the pipe shell and are ventilated at the external air inlets, so that air can uniformly enter the first joint or the third joint through the groove and the internal air inlets, and then the air and water in the first joint or the third joint are fully mixed to form a uniform water-air mixture.

2. The utility model discloses energy-conserving anti-soil type membrane module, its tip of filtering membrane pipe is fixed at the tube tip through sealed glue, it has sealed glue to fill between many filtering membrane pipe tip, and sealed glue keeps apart first joint or third joint and tube middle part, makes the aqueous vapor mixture of first joint or third joint can only follow the inside entering of filtering membrane pipe, prevents that aqueous vapor mixture from getting into the clearance of filtering membrane pipe and tube shell, influences sewage purification.

Drawings

FIG. 1 is a schematic structural view of the energy-saving anti-fouling membrane module of the utility model;

FIG. 2 is a sectional view of the energy-saving anti-fouling membrane module of the utility model in the A-A direction;

FIG. 3 is a schematic view of the energy-saving anti-fouling membrane module B;

figure 4 is the utility model discloses energy-conserving anti-soil type membrane module top view.

In the above drawings: 1. a first joint; 101. a first interface; 2. a second joint; 201. a second interface; 3. a third interface; 301. a third interface; 4. a pipe shell; 5. a cloth air port; 501. an external air inlet; 502. a groove; 503. an interior air inlet; 6. filtering the membrane tube; 8. and (7) sealing the glue.

Detailed Description

Example 1: an energy-saving anti-fouling membrane component comprises a first connector 1, a second connector 2, a third connector 3, a tube shell 4 and air distribution ports 5, wherein the first connector 1 and the third connector 3 are identical in structure and are symmetrically distributed at two ends of the tube shell 4, the air distribution ports 5 are respectively arranged on the first connector 1 and the third connector 3, the second connector 2 is further arranged in the middle of the tube shell 4, a plurality of filtering membrane tubes 6 distributed along the length direction of the tube shell 4 are arranged in the tube shell 4, and two ends of each filtering membrane tube 6 are fixed on the inner side of the tube shell 4;

the air distribution port 5 comprises an external air inlet 501, a groove 502 and an internal air inlet 503, the external air inlet 501 is arranged on the outer side pipe wall of the first connector 1, the groove 502 is arranged on the inner side of the pipe wall of the first connector 1, the external air inlet 501 is positioned on the groove 502 and communicated with the groove 502, a plurality of internal air inlets 503 are distributed on the pipe shell 4 opposite to the groove 502, and the internal air inlets 503 penetrate into the pipe shell 4.

The first connector 1, the second connector 2 and the third connector 3 are respectively provided with a first port 101, a second port 201 and a third port 301, and the first port 101, the second port 201 and the third port 301 are communicated with the inside of the pipe shell 4; the inner air inlets 503 are distributed in a row along the circumferential direction of the pipe shell 4;

the end parts of the filtering membrane tubes 6 are fixed at the end part of the tube shell 4 through a sealant 8, and the sealant 8 is filled among the filtering membrane tubes 6; the aperture size of the internal air inlet 503 is 0.2-2 mm;

the first joint 1 and the second joint 2 are respectively provided with two external air inlets 501, the external air inlets 501 on the first joint 1 are radially and symmetrically distributed, and the external air inlets 501 on the second joint 2 are radially and symmetrically distributed; the filtering membrane tubes 6 are uniformly distributed in the tube shell 4, and gaps are arranged among the filtering membrane tubes.

Example 2: an energy-saving anti-fouling membrane component comprises a first connector 1, a second connector 2, a third connector 3, a tube shell 4 and air distribution ports 5, wherein the first connector 1 and the third connector 3 are identical in structure and are symmetrically distributed at two ends of the tube shell 4, the air distribution ports 5 are respectively arranged on the first connector 1 and the third connector 3, the second connector 2 is further arranged in the middle of the tube shell 4, a plurality of filtering membrane tubes 6 distributed along the length direction of the tube shell 4 are arranged in the tube shell 4, and two ends of each filtering membrane tube 6 are fixed on the inner side of the tube shell 4;

The first connector 1, the second connector 2 and the third connector 3 are respectively provided with a first port 101, a second port 201 and a third port 301, and the first port 101, the second port 201 and the third port 301 are communicated with the inside of the pipe shell 4; two rows of the internal air inlets 503 are distributed along the circumferential direction of the tube shell 4;

When the energy-saving anti-fouling membrane component is adopted, the energy-saving anti-fouling membrane component comprises a first joint, a second joint, a third joint, a tube shell and an air distribution port, wherein the first joint and the third joint are the same in structure and are symmetrically distributed at two ends of the tube shell, and the membrane component is more convenient and faster to use due to the symmetrical design without distinguishing the installation direction; the air distribution port comprises an external air inlet, a groove and an internal air inlet, the external air inlet is arranged on the outer pipe wall of the first joint, the groove is formed in the inner side of the pipe wall of the first joint, the external air inlet is located on the groove and communicated with the groove, a plurality of internal air inlets are distributed on the pipe shell right opposite to the groove, the internal air inlets penetrate into the pipe shell and are ventilated at the external air inlets, so that air can uniformly enter the first joint or the third joint through the groove and the internal air inlets, and then the air and water in the first joint or the third joint are mixed to form a uniform water-air mixture.

The above embodiments are only for illustrating the technical concept and features of the present invention, and the purpose of the embodiments is to enable people skilled in the art to understand the contents of the present invention and to implement the present invention, which cannot limit the protection scope of the present invention. All equivalent changes and modifications made according to the spirit of the present invention should be covered by the protection scope of the present invention.

Claims

1. An energy-conserving anti-soil type membrane module which characterized in that: the pipe comprises a first connector (1), a second connector (2), a third connector (3), a pipe shell (4) and a gas distribution port (5), wherein the first connector (1) and the third connector (3) are identical in structure and symmetrically distributed at two ends of the pipe shell (4), the first connector (1) and the third connector (3) are respectively provided with the gas distribution port (5), the second connector (2) is further arranged in the middle of the pipe shell (4), a plurality of filtering membrane pipes (6) distributed along the length direction of the pipe shell (4) are arranged in the pipe shell (4), and two ends of each filtering membrane pipe (6) are fixed on the inner side of the pipe shell (4);

the air distribution port (5) comprises an external air inlet (501), a groove (502) and an internal air inlet (503), the external air inlet (501) is arranged on the outer side pipe wall of the first joint (1), the groove (502) is arranged on the inner side of the pipe wall of the first joint (1), the external air inlet (501) is located on the groove (502) and communicated with the groove (502), a plurality of internal air inlets (503) are distributed on the pipe shell (4) just opposite to the groove (502), and the internal air inlet (503) penetrates into the pipe shell (4).

2. The energy saving fouling resistant membrane module of claim 1, wherein: the first connector (1), the second connector (2) and the third connector (3) are respectively provided with a first interface (101), a second interface (201) and a third interface (301), and the first interface (101), the second interface (201) and the third interface (301) are communicated with the interior of the pipe shell (4).

3. The energy saving fouling resistant membrane module of claim 1, wherein: the inner air inlets (503) are distributed in a row along the circumferential direction of the pipe shell (4).

4. The energy saving fouling resistant membrane module of claim 1, wherein: two rows of the inner air inlets (503) are distributed along the circumferential direction of the pipe shell (4).

5. The energy saving fouling resistant membrane module of claim 1, wherein: the end parts of the filtering membrane tubes (6) are fixed at the end part of the tube shell (4) through a sealant (8), and the sealant (8) is filled between the end parts of the filtering membrane tubes (6).

6. The energy saving fouling resistant membrane module of claim 1, wherein: the aperture size of the inner air inlet (503) is 0.2-2 mm.

7. The energy saving fouling resistant membrane module of claim 1, wherein: the first joint (1) and the second joint (2) are respectively provided with two external air inlets (501), the external air inlets (501) on the first joint (1) are radially and symmetrically distributed, and the external air inlets (501) on the second joint (2) are radially and symmetrically distributed.

8. The energy saving fouling resistant membrane module of claim 1, wherein: the filtering membrane tubes (6) are uniformly distributed in the tube shell (4), and gaps are arranged among the filtering membrane tubes.