CN212881890U - Ultra-filtration assembly - Google Patents

Abstract

The utility model provides a hyperfiltration component belongs to fibre membrane shell installation technical field. It has solved the problem that current filtering component filter effect is poor and inconvenient installation. The utility model relates to an ultrafiltration module includes casing, mould shell, fibre membrane, buckle subassembly, pulls subassembly, draw-in groove, swivelling chute and spacing subassembly. The utility model discloses in, through the mating reaction of buckle subassembly with spacing subassembly for the mould shell can be stabilized the card and establish in the casing that corresponds. Secondly, when people will change the mould shell, people need to control system for spacing subassembly is in the indentation casing again, removes the back when spacing subassembly is complete from the swivelling chute, pulls the subassembly and drives the motion of buckle subassembly, makes buckle subassembly rotate out from the draw-in groove that corresponds, through the swivelling chute, finally rotates in the mould shell, so, makes things convenient for people to follow the casing that corresponds with the mould shell and takes out.

Description

Ultra-filtration assembly

Technical Field

The utility model belongs to the technical field of the installation of fibre membrane shell, a hyperfiltration subassembly is related to.

Background

At present, the sewage recycling work is carried out in society, most of the sewage recycling work adopts the traditional treatment technologies, such as biochemical degradation, coagulating sedimentation, air flotation, filtration and the like, but the components of domestic sewage are complex, pollutants in the sewage cannot be effectively removed by the water treated by the traditional process, the requirement of new water for production cannot be met, and the problem is solved by the membrane method deep treatment. In the installation process of the fiber membranes, two ends of a plurality of fiber membranes need to be fixed by membrane shells, and then the membrane shells are connected with two shells suitable for the membrane shells to enable the fiber membranes to normally work; secondly, when people assemble the membrane module, because the distance between the two shells is fixed, the membrane module cannot be unfolded normally when people install or use the membrane module, and only the membrane module cannot work normally.

Disclosure of Invention

The utility model aims at having the above-mentioned problem to current technique, provided a good and easy to assemble's of filter effect ultrafiltration subassembly.

The purpose of the utility model can be realized by the following technical proposal: an ultrafiltration module comprising:

a membrane shell is inserted between each shell, and a fiber membrane is arranged between the two membrane shells;

the pair of buckle assemblies are respectively arranged on two sides of the membrane shell, and a traction assembly for retracting the buckle assemblies into the membrane shell is arranged in the membrane shell; all set up a plurality of draw-in grooves of establishing corresponding buckle subassembly with the card in every casing, still offer in the casing and be used for the rotatory swivelling chute of buckle subassembly, install in the casing with blockking the rotatory spacing subassembly of buckle subassembly, spacing subassembly can insert to be established in the swivelling chute, the relative casing of spacing subassembly removes.

In foretell ultrafiltration module, every buckle subassembly is all including articulating the fixture block on the membrane shell, offers the holding tank that is used for the installation to correspond the fixture block on the membrane shell, is equipped with the spring between holding tank and the fixture block that corresponds.

In the ultrafiltration assembly, the top of the accommodating groove is provided with a stop block for stopping the fixture block from turning over; the clamping groove is communicated with the rotating groove.

In a foretell ultrafiltration module, the subassembly that pulls is equipped with the bull stick including being used for connecting the haulage rope of each fixture block and being used for driving the motor of haulage rope motion on the motor, and the equal bull stick of one end of each haulage rope is connected.

In the ultrafiltration assembly, the limiting assembly comprises supporting blocks corresponding to the rotating grooves and a cylinder body for driving each supporting block to move, and each supporting block moves relative to the shell.

In the ultrafiltration module, the cylinder body is provided with the cylinder rod, each supporting block is provided with the extension rod, and each extension rod is connected with the cylinder rod through the same cylinder plate.

In the ultrafiltration module, the top surface of the fixture block is arc-shaped.

In one of the above ultrafiltration modules, the two housings are connected by at least two connecting rods.

In the ultrafiltration module, each shell is provided with a top shell, each top shell is provided with at least two upper magnetic blocks, and each membrane shell is provided with a lower magnetic block of the corresponding upper magnetic block.

Compared with the prior art, the utility model discloses following beneficial effect has:

1. the utility model discloses in, through the mating reaction of buckle subassembly with spacing subassembly for the membrane shell can be stabilized the card and establish in the casing that corresponds.

2. When people will change the membrane shell, people need to control system for in spacing subassembly indentation casing again, remove the back when spacing subassembly is complete from the rotary groove, pull the subassembly and drive the motion of buckle subassembly, make buckle subassembly roll out from the draw-in groove that corresponds, through the rotary groove, finally rotate in advancing the membrane shell, so, make things convenient for people to follow the casing that corresponds with the membrane shell and take out.

3. The selection of draw-in groove is by the length decision of fibre membrane for when the membrane shell passes through the buckle subassembly card and is fixed in the casing, this fibre membrane can remain throughout and expand the state, thereby makes this ultrafiltration subassembly can have better filtering capability.

Drawings

FIG. 1 is a side view of an ultrafiltration module.

Fig. 2 is a cross-sectional view at a-a in fig. 1.

Fig. 3 is an enlarged schematic view of B in fig. 2.

Detailed Description

The following are specific embodiments of the present invention and the accompanying drawings are used to further describe the technical solution of the present invention, but the present invention is not limited to these embodiments.

As shown in fig. 1-3, the ultrafiltration module of the present invention comprises a housing 100, a membrane housing 200, a fibrous membrane 210, a buckle assembly 300, a traction assembly 400, a slot 110, a rotation slot 120, and a limit assembly 500.

The utility model is provided with a pair of shells 100, a membrane shell 200 is inserted between each shell 100, a fiber membrane 210 is arranged between two membrane shells 200, a pair of buckle components 300 are respectively arranged at two sides of the membrane shell 200, and a traction component 400 for retracting the buckle components 300 into the membrane shell 200 is arranged in the membrane shell 200; each shell 100 is provided with a plurality of clamping grooves 110 for clamping corresponding buckle assemblies 300, the shell 100 is further provided with a rotating groove 120 for rotating the buckle assemblies 300, a limiting assembly 500 for blocking the rotation of the buckle assemblies 300 is installed in the shell 100, the limiting assembly 500 can be inserted into the rotating groove 120, the limiting assembly 500 moves relative to the shell 100, the clamping grooves 110 are communicated with the rotating groove 120, before assembly, people need to install the fiber membranes 210 between two membrane shells 200, when assembly, people need to push the limiting assembly 500 into the corresponding rotating groove 120, then people need to select a proper clamping groove 110 according to the length of the fiber membranes 210, and then insert the membrane shells 200 into the corresponding shells 100, because the elasticity exists between the buckle assemblies 300 and the corresponding membrane shells 200, the buckle assemblies 300 can be smoothly clamped into the corresponding clamping grooves 110, and the limiting assemblies 500 are located in the corresponding rotating grooves 120, so that the limiting assembly 500 can block the rotation of the buckle assembly 300, i.e., so that the buckle assembly 300 is stably clamped in the clamping groove 110, i.e., so that the membrane housing 200 is stably installed in the corresponding housing 100; secondly, the selection of the clamping groove 110 is determined by the length of the fiber membrane 210, so that when the membrane shell 200 is clamped in the shell 100 through the clamping component 300, the fiber membrane 210 can be always maintained in the unfolded state, and the ultrafiltration component can have a better filtering function; the utility model discloses an ultrafiltration module is still including being used for controlling spacing subassembly 500, draw the control system (not mark in the picture) of subassembly 400, when people will change membrane shell 200, people need control system, make spacing subassembly 500 retract in casing 100 again, move away the back when spacing subassembly 500 is complete from the swivelling chute 120, draw subassembly 400 to drive buckle subassembly 300 motion, make buckle subassembly 300 transfer out from the draw-in groove 110 that corresponds, through swivelling chute 120, finally in rotatory membrane shell 200 of advancing, so, people alright follow the casing 100 that corresponds with membrane shell 200 smoothly from taking out.

Each buckle assembly 300 comprises a clamping block 310 hinged on the membrane shell 200, the top surface of the clamping block 310 is arc-shaped, an accommodating groove 220 used for installing the corresponding clamping block 310 is formed in the membrane shell 200, a spring 320 is arranged between the accommodating groove 220 and the corresponding clamping block 310, a stop 221 used for stopping the clamping block 310 from overturning is arranged at the top of the accommodating groove 220, in the process of installing the membrane shell 200 into the corresponding shell 100, the accommodating groove 220 is connected with the corresponding clamping block 310 through the spring 320, so that the membrane shell 200 can be smoothly inserted into the shell 100, in the process, the spring 320 is compressed and stressed, when the clamping block 310 moves to the corresponding clamping groove 110, the clamping block 310 at the moment has the elastic action of the spring 320, one end of the clamping block 310 is inserted into the clamping groove 110, namely, the membrane shell 200 is clamped in the shell 100.

The pulling assembly 400 comprises pulling ropes 410 for connecting each fixture block 310 and a motor 420 for driving the pulling ropes 410 to move, a rotating rod 421 is arranged on the motor 420, one end of each pulling rope 410 is connected with the rotating rod 421, and the other end of each pulling rope 410 is connected with the fixture block 310, the fixture block 310 is hinged with the top of the accommodating groove 220, so that when a user operates the control system, the motor 420 drives the rotating rod 421 to rotate, the pulling ropes 410 are wound on the rotating rods 421, the pulling ropes 410 drive the corresponding fixture blocks 310 to move towards the corresponding accommodating grooves 220, at the moment, the springs 320 are compressed under stress, therefore, the user can smoothly take out the membrane shells 200 from the corresponding shell 100, when the user inserts the membrane shells 200 into the corresponding shell 100 again, the user only needs to operate the control system again, the motor 420 is turned over, so that the pulling string 410 wound around the rotating rod 421 is separated from the rotating rod 421, and the spring 320 is installed between the latch 310 and the receiving groove 220, so that the spring 320 pushes the latch 310 out of the receiving groove 220, and when a person inserts the membrane housing 200 into the housing 100 again, the latch 310 can be latched into the corresponding latch groove 110 again.

The position limiting assembly 500 includes supporting blocks 510 corresponding to the rotary slot 120 and a cylinder 520 for driving each supporting block 510 to move, each supporting block 510 moves relative to the housing 100, a cylinder rod 521 is disposed on the cylinder 520, an extension rod 511 is disposed on each supporting block 510, each extension rod 511 is connected to the cylinder rod 521 through the same cylinder plate 530, when one blocks the rotary slot 120, one needs to operate a control system, so that the cylinder block 520 pushes out the cylinder rod 521, and since each extension bar 511 is connected to the cylinder rod 521 through the same cylinder plate 530, each extension bar 511 is connected to the support block 510, so that each support block 510 is inserted into the corresponding rotation groove 120, that is, the rotation grooves 120 are filled with the corresponding support blocks 510, and therefore, when the latch 310 is inserted into the corresponding latch groove 110, the supporting block 510 will block the rotation of the clamping block 310, so that the membrane housing 200 can be stably clamped in the housing 100; when the cylinder 520 retracts the cylinder rod 521, each supporting block 510 is transferred from the corresponding rotating groove 120 into the housing 100, so that when the motor 420 rotates, the latch 310 rotates at the hinge point of the latch 310 and the receiving groove 220, passes through the rotating groove 120, and finally rotates into the receiving groove 220, and thus, one can take out the membrane housing 200 from the housing 100.

The two housings 100 are connected by at least two connecting rods 130.

Each casing 100 is provided with a top casing 600, each top casing 600 is provided with at least two upper magnetic blocks 610, each membrane casing 200 is provided with a lower magnetic block 230 of the corresponding upper magnetic block 610, during installation, people need to install the top casing 600 on the corresponding casing 100, during the process of installing the membrane casing 200 into the corresponding casing 100, when the membrane casing 200 abuts against the casing 100, the lower magnetic block 230 is magnetically connected with the upper magnetic block 610, so that the membrane casing 200 is not easy to fall out of the casing 100.

The specific embodiments described herein are merely illustrative of the spirit of the invention. Various modifications, additions and substitutions for the specific embodiments described herein may be made by those skilled in the art without departing from the spirit of the invention or exceeding the scope of the invention as defined in the accompanying claims.

Claims (9)

1. An ultrafiltration module, comprising:

a membrane shell is inserted between each shell, and a fiber membrane is arranged between the two membrane shells;

the pair of buckle assemblies are respectively arranged on two sides of the membrane shell, and a traction assembly for retracting the buckle assemblies into the membrane shell is arranged in the membrane shell; every all set up a plurality of draw-in grooves that are used for the card to establish corresponding buckle subassembly in the casing, still set up the swivelling chute that is used for buckle subassembly rotatory in the casing, the installation is with blockking the rotatory spacing subassembly of buckle subassembly in the casing, spacing subassembly can be pegged graft and is located the swivelling chute, spacing subassembly casing relative movement.

2. The ultrafiltration assembly of claim 1, wherein each of the snap assemblies comprises a fixture block hinged to the membrane housing, the membrane housing is provided with an accommodating groove for mounting a corresponding fixture block, and a spring is disposed between the accommodating groove and the corresponding fixture block.

3. The ultrafiltration module of claim 2, wherein the top of the receiving channel is provided with a stop for stopping the cartridge from flipping over; the clamping groove is communicated with the rotating groove.

4. The ultrafiltration module of claim 2, wherein the traction module comprises a traction rope for connecting each fixture block and a motor for driving the traction rope to move, the motor is provided with a rotating rod, and one end of each traction rope is connected with the rotating rod.

5. An ultrafiltration module according to claim 1 wherein said stop assembly comprises support blocks corresponding to the rotary channel and a cylinder for driving movement of each support block, each support block being movable relative to the housing.

6. A hyperfiltration assembly according to claim 5, wherein cylinder rods are provided on the cylinder block, extension rods are provided on each support block, and each extension rod is connected to a cylinder rod by the same cylinder plate.

7. The ultrafiltration module of claim 2 wherein said top surface of said cartridge is curved.

8. An ultrafiltration module according to claim 2 wherein the two housings are connected by at least two connecting rods.

9. The ultrafiltration module of claim 2 wherein each of said housings has a top housing, each of said top housings having at least two upper magnets thereon, each of said membrane housings having a corresponding lower magnet of said upper magnets thereon.

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