CN218988975U - Installation mechanism of MABR component - Google Patents

Abstract

The utility model provides an installation mechanism of an MABR component, which comprises a support frame, wherein the support frame is used for connecting and positioning the MABR component; the floating body is connected with the support frame and is provided with a solution cavity, a water inlet and a water outlet which are communicated with the solution cavity, and the floating body is used for water inflow or drainage to adjust the floating depth and provide buoyancy for the support frame; the liquid inlet assembly is communicated with the water inlet and is used for supplying water to the floating body; and the liquid suction assembly is communicated with the water outlet and is used for discharging water in the floating body. The installation mechanism of the MABR component can solve the problem that the MABR component in the prior art is inconvenient to install.

Description

Installation mechanism of MABR component

Technical Field

The utility model relates to the technical field related to water pollution control, in particular to an installation mechanism of an MABR component.

Background

The membrane aeration-biofilm reactor technology (Membrane biofilm reactors, MBfR) is also known as membrane aeration bioreactor technology (Membrane Aerated biofilm reactor, MABR). Essentially a novel biofilm process capable of simultaneously achieving two functions through a membrane material:

(1) providing a carrier for easy attachment growth of the biological film;

(2) delivery of gaseous substrates (typically O) to biological membranes ₂ )。

Because of the special aeration mode and oxygen transfer mechanism of the MABR reactor, the microbial film can generate an obvious layered structure, and good synchronous nitrification-denitrification effect is generated. The main technical characteristics of the method can be summarized as three points: (1) bubble-free aeration, (2) heterogeneous mass transfer, and (3) a biomembrane layered structure.

There are two types of MABR reactors available:

(1) curtain type, using hollow fiber membrane wire as gas substrate transmission and biological film adhesion carrier;

(2) plate type film sleeve made of inner film roll is used as gaseous substrate transmission and biological film adhesion carrier (plastic supports are arranged on two sides), and the inner side of the film roll is aerated.

At present, the installation mode of MABR has fixed support installation (comprising beam column type, steel frame structure type and the like) according to different engineering cases.

These mounting forms have the following disadvantages:

1. the construction time is longer, the tank body needs to be emptied for installation, and the advantages of quick installation and no water cut-off installation of the MABR technology are lost;

2. beam columns or steel structures, etc. may adversely affect the flow regime within the biological pond.

3. The maximum wet weight of the membrane component needs to be considered in the installation of the fixed support, and the installation cost is high;

4. because the beam column/steel structure supporting piece is hidden under the water surface, the position is difficult to determine when overhauling and hoisting again, and therefore, additional hoisting sliding rails or hoisting beams are often required to be added to ensure the installation accuracy;

5. the hoisting installation has the requirement on the strength of the cover plate and the side wall of the pool; while the support mounting requires strength for both the tank Bian Bi and the tank floor;

6. in a single-side hanging installation mode, in order to ensure the stability of the installation of the membrane assembly, a certain space is needed at the tank edge, so that the counterweight support of the fixing piece is facilitated;

7. in order to ensure the flow state and the treatment capacity of an activated sludge process in the operation process, the aspect ratio of the biological pond has certain requirements, and when the side wall of the pond is hung and installed, the phenomenon of uneven load or short flow of a membrane module is easily generated if the corresponding length and width are not proper.

In summary, the conventional installation method of the fixed support and the fixed hoisting has high cost, and also has various limitations, and the original space is possibly wasted.

Disclosure of Invention

The utility model mainly aims to provide an installation mechanism of an MABR component, which solves the problem of inconvenient installation of the MABR component in the prior art.

In order to achieve the above object, according to one aspect of the present utility model, there is provided an installation mechanism of an MABR module, the installation mechanism of an MABR module including a support frame for connecting and positioning the MABR module; the floating body is connected with the support frame and is provided with a solution cavity, a water inlet and a water outlet which are communicated with the solution cavity, and the floating body is used for water inflow or drainage to adjust the floating depth and provide buoyancy for the support frame; the liquid inlet assembly is communicated with the water inlet and is used for supplying water to the floating body; and the liquid suction assembly is communicated with the water outlet and is used for discharging water in the floating body.

Further, the floating body is installed at the bottom or side of the support frame.

Further, one or more floating bodies are arranged, and when one floating body is arranged, the floating body extends along the circumferential direction of the support frame; when the floating bodies are arranged in a plurality, the floating bodies are arranged at intervals or in a connecting manner along the circumferential direction of the supporting frame.

Further, the floating body is made of anti-corrosion materials, or an anti-corrosion coating is arranged on the outer surface of the floating body.

Further, the bottom surface of the interior of the floating body extends obliquely downwards from the first end to the second end so that the height of the solution cavity is gradually increased from the first end to the second end, and the water outlet is arranged at the second end.

Further, the imbibition assembly comprises a drain pipe, and one end of the drain pipe is communicated with the drain outlet; the other end of the drain pipe is connected with the cam locking quick connector; the cam locking quick connector is arranged at the liquid inlet of the water draining bag, and the water draining bag provides negative pressure.

Further, the liquid absorbing assembly further comprises a traction piece, the outer surface of the water draining bag is provided with a mounting part, the traction piece is connected with the mounting part, and length scales are arranged on the traction piece and used for detecting the floating and submerging depth of the water draining bag; and the load carrying piece is arranged on the traction piece and/or the installation part and provides gravity for the sinking of the drainage bag.

Further, the installation mechanism of the MABR component further comprises a connecting frame, and the connecting frame is installed on the supporting frame; the support arm, the support arm is provided with at least one, and the one end and the link of support arm are connected, and the other end and the MABR subassembly of support arm are connected, and the support arm is used for realizing support frame and MABR subassembly synchronous movement.

Further, the connecting frame comprises a plurality of cross beams, one or more cross beams are arranged on the cross beams, at least one supporting arm is arranged on each cross beam, when the plurality of cross beams are arranged, the plurality of cross beams are arranged at intervals, and two adjacent cross beams are connected through a connecting piece.

Further, the support frame comprises a frame; the reinforcing ribs are arranged on the frame, the frame and the reinforcing ribs form a unit frame, and the unit frames are spliced through fasteners to form a supporting frame.

Further, the outer peripheral surface of the frame is provided with anti-collision wear strips.

Further, the mounting mechanism of the MABR assembly further comprises a supporting platform, and the supporting platform is mounted on the supporting frame.

Further, the installation mechanism of the MABR component further comprises a positioning piece, the positioning piece is connected with the supporting frame, and the positioning piece is used for positioning the supporting frame.

Further, the mounting mechanism of the MABR assembly further comprises a guardrail, and the guardrail is mounted on the outer periphery of the support frame.

By applying the technical scheme of the utility model, the installation mechanism of the MABR assembly comprises a support frame, a floating body, a liquid inlet assembly and a liquid suction assembly, wherein the support frame is used for connecting and positioning the MABR assembly, the floating body is connected with the support frame and is provided with a solution cavity, a water inlet and a water outlet which are communicated with the solution cavity, the floating body is used for feeding water or draining water to adjust the floating depth, the floating body provides buoyancy for the support frame, the liquid inlet assembly is communicated with the water inlet and is used for supplying water to the floating body, and the liquid suction assembly is communicated with the water outlet and is used for draining water in the floating body.

From the above, the floating body can be used for providing buoyancy when the MABR component is installed, so that the MABR component can be directly placed on water in the installation process without draining, stopping water, adding structural members such as positioning piles and the like, and the installation mode of the water-saving floating body has the technical effects of flexible positioning and simplicity in operation. And the floating depth of the floating body can be adjusted, so that the floating depth of the MABR assembly can be adjusted, and the MABR assembly can be conveniently adjusted to a preset depth. The utility model discloses a realize realizing the location to the MABR subassembly through support frame and body complex mode to adjust the depth of diving of MABR subassembly, have simple to operate, advantage that the adjustability is high.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model. In the drawings:

FIG. 1 is a schematic diagram showing the overall structure of the mounting mechanism of the MABR module of the present utility model;

FIG. 2 illustrates a top view of the mounting mechanism of the MABR assembly of the present utility model;

FIG. 3 shows a top view of the connector of the present utility model;

FIG. 4 is a schematic view showing the connection structure of the connecting frame and the supporting arm of the present utility model;

fig. 5 shows a schematic perspective view of a wicking assembly of the present utility model.

Wherein the above figures include the following reference numerals:

10. a support frame; 20. a floating body; 210. a water inlet; 220. a water outlet; 310. a connecting frame; 320. a support arm; 40. a liquid-absorbing assembly; 410. a drain pipe; 420. a cam locking quick connector; 430. a water drainage bag; 431. a mounting part; 440. a traction member; 450. a load carrying member; 50. a support platform; 60. guard bars; 70. and a positioning piece.

Detailed Description

It should be noted that, in the case of no conflict, the embodiments and features in the embodiments may be combined with each other. The utility model will be described in detail below with reference to the drawings in connection with embodiments.

It is noted that all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this application belongs unless otherwise indicated.

In the present utility model, unless otherwise indicated, terms of orientation such as "upper, lower, top, bottom" are used generally with respect to the orientation shown in the drawings or with respect to the component itself in the vertical, upright or gravitational direction; also, for ease of understanding and description, "inner and outer" refers to inner and outer relative to the profile of each component itself, but the above-mentioned orientation terms are not intended to limit the present utility model.

For solving the inconvenient problem of MABR subassembly installation among the prior art, this application provides an installation mechanism of MABR subassembly.

As shown in fig. 1 to 5, the installation mechanism of the MABR module includes a support frame 10, a float 20, a liquid inlet module and a liquid suction module 40, the support frame 10 is used for connecting and positioning the MABR module, the float 20 is connected with the support frame 10, the float 20 is provided with a solution cavity and a water inlet 210 and a water outlet 220 communicated with the solution cavity, the float 20 is used for water inflow or drainage to adjust the submergence depth, the float 20 provides buoyancy for the support frame 10, the liquid inlet module is communicated with the water inlet 210 for supplying water to the float 20, the liquid suction module 40 is communicated with the water outlet 220 for discharging the water inside the float 20.

Specifically, the floating body 20 can be used for providing buoyancy when the MABR assembly is installed, so that the MABR assembly can be directly placed on water in the installation process, water drainage and water stopping are not needed, structural members such as positioning piles are not needed to be additionally arranged, and the installation mode has the technical effects of flexible positioning and simplicity in operation. And, the floating depth of the MABR assembly can be adjusted by adjusting the floating depth of the floating body 20, so that the MABR assembly can be conveniently adjusted to a preset depth. The utility model provides a realize realizing the location to the MABR subassembly through support frame 10 and body 20 complex mode to adjust the depth of diving of MABR subassembly, have simple to operate, advantage that the adjustability is high.

Further, the support frame 10 has a ring-shaped structure, and the MABR assembly is installed in a water area of a ring-shaped area formed by the support frame 10, and has a predetermined submergence depth to be submerged under the water line.

It should be noted that, the floating body 20 is used to provide buoyancy, and the floating body 20 may be installed at the bottom of the support frame 10 to support the support frame 10, or the floating body 20 may be installed at the side of the support frame 10 to provide buoyancy.

The connection mode between the floating body 20 and the support frame 10 may be a detachable connection mode such as plugging, buckling connection, connection through a fastener, etc., so that the floating body 20 and the support frame 10 are fixed in the process of installing the floating body 20 and the support frame 10. For example, the fastener may be a bolt.

Further, the floating body 20 is made of a corrosion-resistant material, for example, the floating body 20 may be made of a corrosion-resistant material such as glass fiber reinforced plastic/aluminum/stainless steel, and the floating body 20 is not limited to the above materials but may be made of other corrosion-resistant materials.

It should be noted that, the floating body 20 is not limited to be made of an anti-corrosion material, and the outer surface of the floating body 20 may be provided with an anti-corrosion coating to achieve an anti-corrosion technical effect, for example, the glass fiber reinforced plastic coating/heat line or other anti-corrosion finishing paint meeting ISO20340-2009 is used for anti-corrosion protection inside and outside the floating body 20.

In this embodiment, the specific size and material selection of float 20 may be adaptively adjusted based on the overall area of the body of water.

Further, the floating body 20 is provided with one or more, and when the floating body 20 is provided with one, the floating body 20 extends along the circumferential direction of the support frame 10 to form an integrated ring structure to facilitate the stable support of the support frame 10.

When the floating body 20 is provided in plurality, the plurality of floating bodies 20 are provided at intervals along the circumferential direction of the support frame 10 to provide buoyancy by the plurality of floating bodies 20 being engaged.

Preferably, the plurality of floating bodies 20 are disposed at equal intervals along the circumferential direction of the support frame 10 to provide uniform buoyancy to the support frame 10.

Of course, when the floating body 20 is provided in plurality, a plurality of floating bodies 20 may be connected to each other in the circumferential direction of the support frame 10 to provide buoyancy to the support frame 10 through the plurality of connected floating bodies 20.

In this embodiment, the liquid inlet assembly is used for providing a water source, so that when the floating body 20 is required to submerge, the water is injected into the floating body 20, the submergence depth of the floating body 20 is adjusted, wherein the water source can be clean water provided by a water source on the shore, and the water source is specifically connected with another water inlet 210 of the floating body 20 through a water pipe, so that water supply is realized, and the liquid inlet assembly further comprises a pump body, and the water supply to the water inlet 210 of the floating body 20 is controlled by controlling the pump body.

As shown in fig. 1 and 5, the bottom surface of the inside of the floating body 20 is inclined downward from the first end toward the second end so that the height of the solution chamber is gradually increased from the first end toward the second end, and the drain port 220 is provided at the second end.

Specifically, the bottom surface inside the floating body 20 is arranged obliquely downwards so as to form a slope body for flowing liquid, and the water outlet 220 is arranged at the second end of the bottom of the floating body 20, so that when the water inside the floating body 20 is discharged, the liquid can flow towards the water outlet 220 conveniently, the water inside the floating body 20 can be discharged to the outside of the floating body 20 as required, and the problem that the floating depth is inconvenient to adjust due to the fact that the water inside the floating body 20 cannot be discharged completely is avoided.

In order to ensure uniform buoyancy of floating body 20, the bottom surface of the outside of floating body 20 does not have a height difference.

Further, the pipette assembly 40 includes a drain pipe 410, a cam lock quick connector 420, and a drain bag 430, one end of the drain pipe 410 communicates with the drain port 220, the other end of the drain pipe 410 is connected with the cam lock quick connector 420, the cam lock quick connector 420 is installed at a liquid inlet of the drain bag 430, and the drain bag 430 provides negative pressure.

Wherein, the cam locking quick connector 420 is connected between the drain bag 430 and the drain pipe 410 to play a role of a switch, when the floating depth of the floating body 20 needs to be adjusted to drain the water inside the floating body 20, the cam locking quick connector 420 is controlled to open the drain bag 430, and under the action of the negative pressure provided by the drain bag 430, the drain bag 430 sucks the water inside the floating body 20 into the drain bag 430, thereby reducing the water inside the floating body 20 to change the floating depth of the floating body 20.

In this embodiment, the drain pipe 410 is a rubber hose.

As shown in fig. 5, in order to conveniently place the drainage bag 430 at a position below the water line and to know the specific depth of the drainage bag 430, the liquid suction assembly 40 further includes a traction member 440 and a loading member 450, wherein an installation portion 431 is provided on the outer surface of the drainage bag 430, the traction member 440 is connected with the installation portion 431, a length scale is provided on the traction member 440 for detecting the submergence depth of the drainage bag 430, and the loading member 450 is installed on the traction member 440 and/or the installation portion 431, and the loading member 450 provides gravity for the drainage bag 430 to sink.

Specifically, the mounting portion 431 is a hanging ring, the traction member 440 is a hanging rope or rod structure with length scales, the weight member 450 is used for providing the gravity for the submergence of the water draining bag 430, which may be a metal block, after the cam locking quick connector 420 on the water draining bag 430 is opened, the water draining bag 430 is placed into water, and the submergence is controlled by the traction member 440 under the action of the weight member 450.

Further, the drain pipe 410 is installed on the support frame 10 when the drain of the drain bag 430 is not required.

As shown in fig. 2 to 4, the installation mechanism of the MABR module further includes a connection frame 310 and a support arm 320, the connection frame 310 is installed on the support frame 10, the support arm 320 is provided with at least one, one end of the support arm 320 is connected with the connection frame 310, the other end of the support arm 320 is connected with the MABR module, and the support arm 320 is used for realizing synchronous movement of the support frame 10 and the MABR module.

Specifically, the support arm 320 is a rigid suspension arm, and is connected with the MABR component by adopting the rigid suspension arm, so that synchronous movement of the support arm 320 and the MABR component is realized, the support frame 10 drives the support arm 320 to move, and the support arm 320 drives the MABR component to move.

Further, in order to stably connect the support arm 320 with the support frame 10, a connection frame 310 is provided on the support frame 10, the connection frame 310 includes a plurality of beams, one or more beams are provided, at least one support arm 320 is installed on each beam, when a plurality of beams are provided, a plurality of beams are arranged at intervals, and two adjacent beams are connected through a connection member.

Wherein, the crossbeam is transversely arranged in the annular region of the support frame 10, so that the support arm 320 is arranged between the crossbeam and the MABR assembly, and the specific number of the crossbeams can be adaptively adjusted according to the installation requirement of the MABR assembly.

The crossbeam is provided with two in this application, is provided with two support arms 320 on every crossbeam to realize that four support arms 320 are connected with MABR subassembly, in order to provide stable holding power.

The rigid suspension arm is made of galvanized carbon steel or glass fiber reinforced plastic carbon steel.

In this embodiment, the support arm 320 and the connecting frame 310, and the connecting frame 310 and the supporting frame 10 are fixedly connected by fixing members, for example, bolts.

As shown in fig. 2, the support frame 10 includes a frame and reinforcing bars mounted on the frame, the frame and the reinforcing bars forming a unit frame, and a plurality of unit frames being spliced by fasteners to form the support frame 10.

Specifically, a plurality of unit frames are spliced to form the support frame 10, so that when a single unit frame is damaged and needs to be maintained and replaced, the corresponding unit frame is only required to be replaced.

Further, the strength of the unit frame is improved by providing the reinforcing ribs.

In this embodiment, the support frame 10 may employ: Q235A galvanized steel/glass fiber reinforced plastics/stainless steel or other materials with corresponding strength, refer to the 3.0.3 splash zone regulation in the technical Specification for corrosion protection of seaport engineering Steel Structure (JTS 164-2007). The corrosion resistance of the steel structure is protected by adopting a heavy corrosion-resistant coating or a metal thermal spraying coating and a sealing coating, and can also be protected by adopting resin mortar or a coated organic composite layer and a composite corrosion-resistant metal layer. The anticorrosive paint should be suitable for dry-wet alternation, have wear resistance, impact resistance and weather resistance, and the service life of a coating system should be considered according to 20 years, and the requirements should be not lower than the minimum design requirements and the initial performance requirements of the protective paint system in 4.3.6 of corrosion protection technical Specification of seaport engineering steel structure (JTS 164-2007) and 6.2 of splash and tide areas C5-M and lm2 of performance requirements of protective paint systems of colored paint and varnish-offshore platform and related structures (ISO 20340-2009).

In order to avoid the outer peripheral surface of the frame from being damaged by impact, in the embodiment, an anti-collision wear strip is arranged on the outer peripheral surface of the frame.

As shown in fig. 1 and 2, to facilitate walking on the support frame 10, the installation mechanism of the MABR module further includes a support platform 50, and the support platform 50 is installed on the support frame 10.

In particular, the support platform 50 may be a skid resistant wood board or fiberglass grid or other structural member of skid resistant corrosion resistant ultraviolet resistant material that is laid on the support frame 10.

Further, the mounting mechanism of the MABR module further includes a guard rail 60, and the guard rail 60 is mounted on the outer circumference of the support frame 10 to facilitate the protection of the person walking on the support platform 50.

As shown in FIG. 1, the mounting mechanism of the MABR module further comprises a positioning member 70, wherein the positioning member 70 is connected with the support frame 10, and the positioning member 70 is used for positioning the support frame 10.

Specifically, the positioning member 70 may be fixed by sinking or shore.

In the sinking type fixing manner, the positioning member 70 is formed by combining a fixing anchor bolt, a steel rope, a spring and a concrete balancing weight, and the fixing anchor bolt is sunk to the water level so as to realize the function of fixing the supporting frame 10.

Further, the connection part of the concrete fitting block and the fixed anchor bolt is provided with a spring for storing certain elastic potential energy so as to have certain adjusting capacity and constantly maintain the fixing function on the integral floating device.

In the shore-based fixing manner, the positioning member 70 includes a fixing anchor bolt, a steel rope or a fixing rope, and a spring, and the fixing anchor bolt is connected with a positioning point on the shore for positioning.

Further, the connection part of the fixed anchor bolt and the steel rope or the fixed rope is provided with a spring for storing certain elastic potential energy so as to have certain adjusting capacity and constantly maintain the fixing function on the integral floating device.

From the above description, it can be seen that the above embodiments of the present utility model achieve the following technical effects:

1. the floating body 20 can be used for providing buoyancy when the MABR assembly is installed, so that the MABR assembly can be directly placed on water in the installation process, water drainage and water stopping are not needed, structural members such as positioning piles are not needed to be additionally arranged, and the installation mode has the technical effects of flexible positioning and simplicity in operation.

2. The floating depth of the MABR module can be adjusted by adjusting the floating depth of the floating body 20, so that the MABR module can be conveniently adjusted to a preset depth.

3. The support arm 320 adopts a rigid boom structure to facilitate the same submergence depth of the support frame 10 and the MABR assembly, thereby improving the accuracy of the submergence depth adjustment of the MABR assembly.

It will be apparent that the embodiments described above are merely some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the present utility model without making any inventive effort, shall fall within the scope of the present utility model.

It is noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of example embodiments in accordance with the present application. As used herein, the singular is also intended to include the plural unless the context clearly indicates otherwise, and furthermore, it is to be understood that the terms "comprises" and/or "comprising" when used in this specification are taken to specify the presence of stated features, steps, operations, devices, components, and/or combinations thereof.

It should be noted that the terms "first," "second," and the like in the description and claims of the present application and the above figures are used for distinguishing between similar objects and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used may be interchanged where appropriate such that embodiments of the present application described herein may be implemented in sequences other than those illustrated or described herein.

The above description is only of the preferred embodiments of the present utility model and is not intended to limit the present utility model, but various modifications and variations can be made to the present utility model by those skilled in the art. Any modification, equivalent replacement, improvement, etc. made within the spirit and principle of the present utility model should be included in the protection scope of the present utility model.

Claims (14)

1. A mounting mechanism for an MABR module comprising:

the support frame (10), the said support frame (10) is used for connecting and positioning MABR assembly;

a floating body (20), wherein the floating body (20) is connected with the support frame (10), the floating body (20) is provided with a solution cavity, a water inlet (210) and a water outlet (220) which are communicated with the solution cavity, the floating body (20) is used for water inflow or drainage to adjust the submergence depth, and the floating body (20) provides buoyancy for the support frame (10);

a liquid inlet assembly in communication with the water inlet (210) for supplying water to the float (20);

a wicking assembly (40), the wicking assembly (40) in communication with the drain port (220) for draining water from the interior of the float (20).

2. The MABR module mounting mechanism according to claim 1, wherein the float (20) is mounted at the bottom or side of the support frame (10).

3. The mounting mechanism of an MABR module according to claim 1, wherein the float (20) is provided with one or more,

when the floating body (20) is provided with one, the floating body (20) extends along the circumferential direction of the supporting frame (10);

when the floating bodies (20) are arranged in a plurality, the floating bodies (20) are arranged at intervals or in a connecting mode along the circumferential direction of the supporting frame (10).

4. The MABR module mounting mechanism according to claim 1, wherein the float (20) is made of anti-corrosion material or the outer surface of the float (20) is provided with an anti-corrosion coating.

5. The MABR module mounting mechanism according to claim 1, wherein the bottom surface of the interior of the float (20) is inclined downward from a first end toward a second end so that the height of the solution chamber is gradually increased from the first end toward the second end, and the drain port (220) is provided at the second end.

6. The MABR assembly mounting mechanism according to claim 1, wherein the pipetting assembly (40) comprises:

a drain pipe (410), one end of the drain pipe (410) being in communication with the drain port (220);

the other end of the drain pipe (410) is connected with the cam locking quick connector (420);

the cam locking quick connector (420) is arranged at the liquid inlet of the water draining bag (430), and the water draining bag (430) provides negative pressure.

7. The MABR assembly mounting mechanism according to claim 6, wherein the wicking assembly (40) further comprises:

a traction member (440), wherein an installation part (431) is arranged on the outer surface of the drainage bag (430), the traction member (440) is connected with the installation part (431), and the traction member (440) is provided with length scales for detecting the floating depth of the drainage bag (430);

-a load carrying member (450), said load carrying member (450) being mounted on said traction member (440) and/or said mounting portion (431), said load carrying member (450) providing gravity for the sinking of said drain bag (430).

8. The MABR module mounting mechanism of any one of claims 1 to 7, further comprising:

-a connection rack (310), said connection rack (310) being mounted on said support frame (10);

the support arm (320), support arm (320) are provided with at least one, the one end of support arm (320) with link (310) are connected, the other end of support arm (320) with MABR subassembly is connected, support arm (320) are used for realizing support frame (10) with MABR subassembly synchronous motion.

9. The MABR module mounting mechanism according to claim 8, wherein said connector (310) comprises a plurality of beams, one or more of said beams being provided, at least one of said support arms (320) being mounted on each of said beams, and when a plurality of said beams are provided, a plurality of beams are provided at intervals, adjacent ones of said beams being connected by connectors.

10. The mounting mechanism of an MABR module according to any one of claims 1 to 7, wherein the support bracket (10) comprises:

a frame;

the reinforcing ribs are arranged on the frames, the frames and the reinforcing ribs form a unit frame, and a plurality of unit frames are spliced through fasteners to form the supporting frame (10).

11. The MABR module mounting mechanism of claim 10, wherein an anti-collision wear strip is provided on an outer perimeter of the frame.

12. The mounting mechanism of an MABR module according to claim 10, further comprising a support platform (50), said support platform (50) being mounted on said support frame (10).

13. The mounting mechanism of an MABR module according to any one of claims 1 to 7, further comprising a positioning member (70), said positioning member (70) being connected to said support frame (10), said positioning member (70) being used for positioning said support frame (10).

14. The mounting mechanism of an MABR module according to any one of claims 1 to 7, further comprising a rail (60), said rail (60) being mounted on the outer periphery of the support frame (10).

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