CN220877815U - Novel protein removal device based on porous adsorption material - Google Patents

Abstract

The utility model discloses a novel protein removal device based on a porous adsorption material, which relates to the technical field of protein removal and comprises a box body and a rotating rod rotatably arranged in the back side of the box body, wherein a connecting plate is fixedly sleeved on the rod wall of the rotating rod, both ends of the connecting plate are fixedly provided with filter shells, molecular sieves are filled in the filter shells, the side walls of the filter shells are communicated with a liquid outlet pipe, the top of the box body is fixedly provided with a feed pipe in a penetrating way, the top of the feed pipe is communicated with a hopper, the inner wall of the box body is provided with a guide unloading mechanism for dumping the molecular sieves, and the bottom and the upper end of the back side of the box body are respectively provided with a discharge hole and a feed hole. According to the utility model, after the molecular sieve adsorbs and removes proteins in raw materials for a long time, the molecular sieves in the two filter shells can be replaced, so that the adsorption and removal of the proteins can be continuously and stably carried out.

Description

Novel protein removal device based on porous adsorption material

Technical Field

The utility model relates to the technical field of protein removal, in particular to a novel protein removal device based on a porous adsorption material.

Background

During the biological reaction, some byproducts or impurities are often produced, and the impurity proteins can be adsorbed and removed by using a porous adsorption material, so that a purer enzyme preparation is obtained.

Through searching, patent number CN207371362U discloses a device for removing enzyme protein impurities in biological enzymolysis reaction liquid, when the biological enzymolysis reaction liquid in the device enters a circulating tank 2 and reaches a set value, a liquid level sensor sends information to a main control module of a PLC system, and the main control module starts a valve 303 and a variable frequency pump 101 to start circulating filtration impurity removing operation.

The device adopts the separator to filter and remove impurities, and the separator or other adsorption materials are saturated when used for a long time, so that the impurities cannot be adsorbed continuously, and meanwhile, the adsorption component is arranged inside the device, so that more time is required to be consumed for replacement during replacement.

Disclosure of utility model

The present utility model has been made in view of the above-described problems with the conventional novel protein removal apparatus based on porous adsorption materials.

Therefore, the utility model aims to provide a novel protein removal device based on a porous adsorption material, which solves the problems that impurities cannot be adsorbed continuously and replacement difficulty is high because a separator or other adsorption materials are saturated when used for a long time.

In order to achieve the above object, the present utility model provides the following technical solutions:

The utility model provides a novel protein removal device based on porous adsorption material, includes the box and rotates locates the inside bull stick of box back, the fixed cover of pole wall of bull stick is equipped with the link plate, the both ends of link plate are all fixed to be equipped with the filtration shell, the inside packing of filtration shell is equipped with the molecular sieve, the lateral wall intercommunication of filtration shell is equipped with the drain pipe, the fixed inlet pipe that wears to be equipped with in top of box, the top intercommunication of inlet pipe is equipped with the hopper, the inner wall of box is equipped with the direction shedding mechanism that is used for empting the molecular sieve, discharge gate and feed inlet have been seted up respectively to the bottom and the back upper end of box, and the inside molecular sieve of filtration shell can carry out quick absorption to the protein in the raw materials and get rid of, and two filtration shells can rotate the transposition, are convenient for change after the molecular sieve long-time use, avoid the molecular sieve to appear saturating and reduce the absorption removal performance to the protein as far as possible;

A plugging feeding mechanism for feeding the molecular sieve is arranged in the feed pipe;

A rotary transposition mechanism for rotating the two filter shells is arranged between the rear end of the rotating rod and the feeding pipe.

Preferably, the guide discharging mechanism comprises a guide plate, the guide plate is fixedly arranged on the inner wall of the box body and is in contact fit with the shell wall of the filter shell, a discharging opening is formed in the lower end of the side wall of the box body, a through hole is formed in the lower end of the inside of the guide plate, a discharging plate is fixedly arranged between the inner wall of the discharging opening and the lower end of the side wall of the guide plate, when the filter shell rotates in a transposition mode, the shell opening of the filter shell is blocked through the guide plate, and sliding discharging of the molecular sieve is performed after the filter shell is connected with the through hole.

Preferably, the shutoff feeding mechanism includes the actuating lever, the actuating lever rotates to be located in the inlet pipe, and the fixed cover of pole wall is equipped with the baffle, the outer wall of baffle is connected with the inner wall contact of inlet pipe, can carry out shutoff storage to the inside molecular sieve of hopper, can receive the drive back with the inlet pipe open at the baffle, in the molecular sieve whereabouts of being convenient for and entering filter shell.

Preferably, the rotary transposition mechanism comprises a cross rod, the cross rod is rotationally connected with the upper end of the back side of the box body, a first belt pulley is fixedly sleeved on the rod wall, a second belt pulley is arranged on the first belt pulley through belt transmission, the second belt pulley is fixedly sleeved on the rear end of the rod wall of the driving rod, a bidirectional driving tooth is fixedly sleeved on the rod wall of the rotating rod, a torsion spring is sleeved on the rod wall of the cross rod, two ends of the torsion spring are fixedly connected with the cross rod and the box body respectively, and when the filtering shell rotates for transposition under the transmission of the first belt pulley, the second belt pulley and the belt, the feeding pipe can be opened for blanking replacement of the molecular sieve;

the bidirectional driving teeth are meshed with round gears, the round gears are fixedly sleeved on the outer sides of the cross bars, and a rotation positioning mechanism used for limiting the rotation position of the rotating rod is arranged in the bidirectional driving teeth.

Further, the rotation positioning mechanism comprises two positioning rods which are symmetrically arranged, the positioning rods are slidably arranged in the two-way driving teeth, the back side of the box body is provided with positioning grooves which are matched with the positioning rods in a plugging mode, the rod wall of the positioning rods is sleeved with springs, two ends of each spring are fixedly connected with the positioning rods and the two-way driving teeth respectively, after the positions of the rotating rods and the filtering shells are fixed after the positions of the filtering shells are changed, and stability of protein removal during operation is guaranteed.

Preferably, two the locating levers are fixed together and sleeved with a pulling plate at one end far away from the box body, so that the two locating levers can be pulled simultaneously, and the bidirectional driving teeth can be rotated conveniently.

Preferably, the stripper plate is located at the lower end of the through hole, so that the molecular sieve in the filter shell can flow onto the stripper plate through the through hole when tilting downward, and finally slide away from the box body.

Preferably, the guide plate is arranged in an arc shape, and can always seal the shell opening of the filter shell when the filter shell rotates.

Preferably, the feed inlet is disposed at the upper rear side of the filter housing above.

In the technical scheme, the utility model has the technical effects and advantages that:

1. according to the utility model, through the box body, the rotating rod, the connecting plate, the filtering shell, the molecular sieve, the feeding pipe, the hopper, the guide unloading mechanism, the plugging feeding mechanism and the rotary transposition mechanism, after the molecular sieve adsorbs and removes proteins in raw materials for a long time, transposition and replacement can be performed on the molecular sieve in the two filtering shells, so that the adsorption and removal work of the proteins can be continuously and stably performed.

2. According to the utility model, through the rotating rod, the bidirectional driving teeth and the rotating and positioning mechanism, after the rotating rod drives the two filter shells and the molecular sieve to be used in transposition, the positions of the filter shells are fixed, and the stable performance of protein adsorption and removal operation is ensured.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings required for the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments described in the present utility model, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic diagram of the structure of the present utility model;

FIG. 2 is a rear view of FIG. 1 of the present utility model;

FIG. 3 is an enlarged schematic view of portion A of FIG. 2 in accordance with the present utility model;

fig. 4 is a schematic perspective view of the guide plate of fig. 1 according to the present utility model.

Reference numerals illustrate:

1. A case; 2. a rotating rod; 3. a connecting plate; 4. a filter housing; 5. a molecular sieve; 6. a liquid outlet pipe; 7. a feed pipe; 8. a hopper; 9. a guide plate; 10. a stripper plate; 11. a driving rod; 12. a baffle; 13. a cross bar; 14. a first pulley; 15. a belt; 16. a second pulley; 17. a bi-directional drive tooth; 18. a torsion spring; 19. a circular gear; 20. a positioning rod; 21. a spring; 22. pulling the plate.

Detailed Description

In order to make the technical scheme of the present utility model better understood by those skilled in the art, the present utility model will be further described in detail with reference to the accompanying drawings.

The embodiment of the utility model discloses a novel protein removal device based on a porous adsorption material.

Example 1

The utility model provides a novel protein removing device based on porous adsorption materials, which is shown in figures 1-4, and comprises a box body 1 and a rotating rod 2 rotatably arranged in the back side of the box body 1, wherein a connecting plate 3 is fixedly sleeved on the rod wall of the rotating rod 2, both ends of the connecting plate 3 are fixedly provided with a filter shell 4, the inside of the filter shell 4 is filled with a molecular sieve 5, the side wall of the filter shell 4 is communicated with a liquid outlet pipe 6, the top of the box body 1 is fixedly provided with a feeding pipe 7 in a penetrating way, the top of the feeding pipe 7 is communicated with a hopper 8, the inner wall of the box body 1 is provided with a guiding unloading mechanism for dumping the molecular sieve 5, the bottom and the upper end of the back side of the box body 1 are respectively provided with a discharging hole and a feeding hole, and the feeding hole is arranged on the back side above the filter shell 4.

Before carrying out the removal work of albumen, at inside packing molecular sieve 5 of hopper 8, rotate bull stick 2 this moment for inside inlet pipe 7 is opened, molecular sieve 5 accessible inlet pipe 7 gets into inside filtering shell 4, put in the raw materials to inside filtering shell 4 through the feed inlet this moment, and contact with molecular sieve 5, thereby molecular sieve 5 can adsorb the removal fast to the inside albumen of raw materials, and after carrying out long-time adsorption work, rotatable bull stick 2, make two filtering shell 4 rotate, the molecular sieve 5 landing that is saturated in this process is kept away from box 1, accomplish the quick replacement of molecular sieve 5, guarantee that the removal work of albumen is continuous stable going on.

Example 2

Embodiment 2 in order that the molecular sieve 5 in the hopper 8 can stably enter the filter shell 4 on the basis of embodiment 1, as shown in fig. 1, a plugging feeding mechanism for feeding the molecular sieve 5 is arranged in the feed pipe 7, the plugging feeding mechanism comprises a driving rod 11, the driving rod 11 is rotationally arranged in the feed pipe 7, a baffle 12 is fixedly sleeved on the wall of the rod, and the outer wall of the baffle 12 is in contact connection with the inner wall of the feed pipe 7.

When the rotating rod 2 rotates, the driving rod 11 is synchronously driven to drive the baffle 12 to rotate, so that the inside of the feeding pipe 7 is opened, and the molecular sieve 5 in the hopper 8 can enter the inside of the filtering shell 4 through the feeding pipe 7 to perform adsorption.

Example 3

In order to stably throw the molecular sieve 5 into the filter shells 4 when the rotary rod 2 drives the two filter shells 4 to rotate and shift on the basis of the embodiment 1-2, as shown in fig. 1-3, a rotating shifting mechanism for rotating the two filter shells 4 is arranged between the rear end of the rotary rod 2 and the feed pipe 7, the rotating shifting mechanism comprises a transverse rod 13, the transverse rod 13 is rotationally connected with the upper end of the back side of the box body 1, a first belt pulley 14 is fixedly sleeved on the rod wall, a second belt pulley 16 is arranged on the first belt pulley 14 in a transmission manner through a belt 15, the second belt pulley 16 is fixedly sleeved on the rear end of the rod wall of the driving rod 11, a bidirectional driving tooth 17 is fixedly sleeved on the rod wall of the rotary rod 2, a torsion spring 18 is sleeved on the rod wall of the transverse rod 13, and two ends of the torsion spring 18 are respectively fixedly connected with the transverse rod 13 and the box body 1;

The two-way drive tooth 17 meshing is equipped with round gear 19, round gear 19 fixed cover locates the outside of horizontal pole 13, the inside of two-way drive tooth 17 is equipped with the rotation positioning mechanism that is used for restricting bull stick 2 rotation position, rotation positioning mechanism includes two locating levers 20 that the symmetry set up, locating lever 20 slides and locates the inside of two-way drive tooth 17, the constant head tank that cooperation locating lever 20 pegged graft is seted up to the dorsal part of box 1, locating lever 20's pole wall cover is equipped with spring 21, spring 21's both ends respectively with locating lever 20 and two-way drive tooth 17 fixed connection, the one end common fixed cover that keeps away from box 1 of two locating levers 20 is equipped with arm-tie 22.

After the rotating rod 2 drives the two filter shells 4 to shift through the connecting plate 3, the bottom filter shell 4 rotates to the upper part, in the process, the bidirectional driving teeth 17 start to be meshed with the gear 19, so that the transverse rod 13 is driven to twist the torsion spring 18, the driving rod 11 rotates along with the transmission of the first belt pulley 14, the second belt pulley 16 and the belt 15, the baffle 12 rotates at the moment, the molecular sieve 5 can enter the feeding pipe 7, the rotating filter shell 4 is positioned at the lower end of the feeding pipe 7 and starts to receive the molecular sieve 5 and gradually rotates to the vertical position, and after the bidirectional driving teeth 17 are separated from the gear 19, the transverse rod 13 can be rotated to the original position through the torsion of the torsion spring 18, and the driving rod 11 drives the baffle 12 to rotate to the horizontal position and continues to plug the feeding pipe 7.

Example 4

Embodiment 4 in order to rapidly unload the saturated molecular sieve 5 in the replacement process of the molecular sieve 5 based on embodiments 1-3, as shown in fig. 1 and 4, the guiding unloading mechanism comprises a guiding plate 9, the guiding plate 9 is in an arc shape, the guiding plate 9 is fixedly arranged on the inner wall of the box body 1 and is in contact fit with the shell wall of the filtering shell 4, the lower end of the side wall of the box body 1 is provided with an unloading opening, the lower end of the inner part of the guiding plate 9 is provided with a through hole, an unloading plate 10 is fixedly arranged between the inner wall of the unloading opening and the lower end of the side wall of the guiding plate 9, and the unloading plate 10 is positioned at the lower end of the through hole.

In the replacement process of the molecular sieve 5, the upper filter shell 4 starts to rotate and always contacts with the inside of the guide plate 9, at the moment, the inside saturated molecular sieve 5 is blocked and cannot fall into the box 1, when the filter shell 4 is communicated with the through hole, the filter shell 4 is inclined downwards, at the moment, the saturated molecular sieve 5 can be far away from the box through the through hole and the stripper plate 10, and the filter shell 4 is convenient to replace and bear the subsequent molecular sieve 5.

While certain exemplary embodiments of the present utility model have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the utility model. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the utility model, which is defined by the appended claims.

Claims (9)

1. The utility model provides a novel protein removal device based on porous adsorption material, includes box (1) and rotates locates inside bull stick (2) of box (1) back side, its characterized in that, the fixed cover of pole wall of bull stick (2) is equipped with even board (3), the both ends of even board (3) are all fixed to be equipped with filtration shell (4), the inside packing of filtration shell (4) is equipped with molecular sieve (5), the lateral wall intercommunication of filtration shell (4) is equipped with drain pipe (6), feed pipe (7) are worn to be equipped with in the top of box (1) is fixed, the top intercommunication of feed pipe (7) is equipped with hopper (8), the inner wall of box (1) is equipped with the direction shedding mechanism that is used for empting molecular sieve (5), discharge gate and feed inlet have been seted up respectively to the bottom and the back side upper end of box (1).

A blocking feeding mechanism for feeding the molecular sieve (5) is arranged in the feeding pipe (7);

a rotary transposition mechanism for rotating the two filter shells (4) is arranged between the rear end of the rotating rod (2) and the feeding pipe (7).

2. The novel protein removal device based on porous adsorption materials according to claim 1, wherein the guiding discharging mechanism comprises a guiding plate (9), the guiding plate (9) is fixedly arranged on the inner wall of the box body (1) and is in contact fit with the shell wall of the filtering shell (4), a discharging opening is formed in the lower end of the side wall of the box body (1), a through hole is formed in the lower end of the inside of the guiding plate (9), and a discharging plate (10) is fixedly arranged between the inner wall of the discharging opening and the lower end of the side wall of the guiding plate (9).

3. The novel protein removal device based on the porous adsorption material according to claim 1, wherein the plugging and feeding mechanism comprises a driving rod (11), the driving rod (11) is rotatably arranged in the feeding pipe (7), a baffle (12) is fixedly sleeved on the wall of the rod, and the outer wall of the baffle (12) is in contact connection with the inner wall of the feeding pipe (7).

4. The novel protein removal device based on porous adsorption materials according to claim 1, wherein the rotary transposition mechanism comprises a cross rod (13), the cross rod (13) is rotationally connected with the upper end of the back side of the box body (1), a first belt pulley (14) is fixedly sleeved on the wall of the cross rod, a second belt pulley (16) is arranged on the first belt pulley (14) in a transmission manner through a belt (15), the second belt pulley (16) is fixedly sleeved on the rear end of the wall of the driving rod (11), a bidirectional driving tooth (17) is fixedly sleeved on the wall of the rotating rod (2), a torsion spring (18) is sleeved on the wall of the cross rod (13), and two ends of the torsion spring (18) are fixedly connected with the cross rod (13) and the box body (1) respectively;

The bidirectional driving gear (17) is meshed with a round gear (19), the round gear (19) is fixedly sleeved on the outer side of the cross rod (13), and a rotation positioning mechanism for limiting the rotation position of the rotating rod (2) is arranged in the bidirectional driving gear (17).

5. The novel protein removal device based on porous adsorption materials according to claim 4, wherein the rotary positioning mechanism comprises two positioning rods (20) which are symmetrically arranged, the positioning rods (20) are slidably arranged in the two-way driving teeth (17), positioning grooves which are matched with the positioning rods (20) in an inserted manner are formed in the back side of the box body (1), springs (21) are sleeved on the rod walls of the positioning rods (20), and two ends of the springs (21) are fixedly connected with the positioning rods (20) and the two-way driving teeth (17) respectively.

6. The novel protein removal device based on porous adsorption material according to claim 5, wherein a pull plate (22) is fixedly sleeved at one end of the two positioning rods (20) far away from the box body (1).

7. The novel protein removal apparatus based on porous adsorption material according to claim 2, wherein the stripper plate (10) is located at the lower end of the through-hole.

8. Novel protein removal device based on porous adsorption material according to claim 2, characterized in that the guide plate (9) is arranged in an arc shape.

9. The novel protein removal device based on porous adsorption material according to claim 1, wherein the feed inlet is provided at the upper rear side of the filter housing (4) above.