CN215465863U - Cellulase strain screening system - Google Patents

Abstract

The utility model discloses a cellulase strain screening system, which comprises a base, wherein a damping device is rotatably connected on the base, a connecting plate is fixedly connected at the top of the damping device, a separating cylinder is movably connected on the connecting plate, raw materials with strains are poured into the separating cylinder from a feeding port, parallel fixing rings are driven to rotate through the rotation of a servo motor, the fixing ring above the separating cylinder drives a shifting lever, when the shifting lever touches a bulge at the bottom of a linkage plate, as the linkage plate and a screen structure are movably connected through a fixing shaft and are movably arranged in a first notch and a second notch, the linkage plate drives the screen structure to swing left and right, so that the strains with larger specifications cannot pass through the screen structure, the strains fall into an upper discharging pipe through the inclination of the screen structure, the strains with smaller specifications fall onto a bottom plate through a gap between the second notch and the linkage plate while swinging, and the strains with smaller specifications rotate on the bottom plate through a cleaning structure, the strains are dropped into the lower discharging pipe for layered screening.

Description

Cellulase strain screening system

Technical Field

The utility model relates to the technical field of strain screening equipment, in particular to a cellulase strain screening system.

Background

The product not only can compensate amino acid which is easy to lack in conventional feed, but also can quickly convert nutrient components of other coarse feed raw materials to achieve the effect of enhancing digestion, absorption and utilization, and the microbial strains are often required to be separated out and stored separately.

To this end, chinese utility model patent with the publication number CN209292344U discloses a microorganism strain screening device, which comprises a connecting rod and a box body, wherein during the operation, a door plate is opened, a proper amount of microorganism strains are poured into the inner bottom surface of a centrifugal tank from a strain introducing pipe from a channel position, a valve on an inner pipe is opened, nutrient solution in a mother liquid tank is introduced into the centrifugal tank and mixed with microorganisms, and a proper amount of nutrient solution is added, thereby closing the valve, continuously rotating at high speed to generate centrifugal force, layering the microorganism strains and waste residues, high screening efficiency, simple and convenient operation, stable operation of the whole device, safety guarantee is provided for the use process, the waste residues and the microorganism strains are respectively introduced into two screening pipes to be removed through an electric control valve one and an electric control valve two, a baffle block plays a separating role, and people can conveniently remove the screened microorganism strains, the utility model discloses a through high-speed centrifugal screening, produce the layering with microbial srain and waste residue, the screening efficiency is high, and easy operation is convenient, and whole device operation is stable.

The use process of the screening device in the above case is complicated, different screening programs are replaced in screening of different thallus populations, and the screen is inconvenient to replace, so that a cellulase strain screening system is provided for solving the above problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims to provide a cellulase strain screening system to solve the problems in the background technology.

In order to achieve the purpose, the utility model provides the following technical scheme: a cellulase strain screening system comprises a base 1, wherein a damping device 2 is rotatably connected to the base 1, a connecting plate 21 is fixedly connected to the top of the damping device 2, and a separating cylinder 5 is movably connected to the connecting plate 21;

through a plurality of spliced pole 22 rigid couplings between the bottom of knockout drum 5 and the connecting plate 21, and cup joint damping spring 23 on the spliced pole 22, change groove 50 is seted up at the middle part of knockout drum 5, discharging pipe 51 under the fixed through connection of one-third department of one side of knockout drum 5, discharging pipe 52 is connected in the fixed through connection of two-thirds department of the opposite side of knockout drum 5, it is sealed that shrouding 53 is passed through to the bottom of knockout drum 5, charge door 6 is seted up at shrouding 53 middle part, and charge door 6 runs through shrouding 53 to inside the knockout drum 5.

Preferably, the side wall of the separation cylinder 5 below the replacement groove 50 is fixedly connected with a hinged seat 4, the interior of the hinged seat 4 is rotatably connected with one end of a connecting sheet 42 through a hinged shaft 41, the side wall of the separation cylinder 5 above the replacement groove 50 is fixedly connected with a connecting seat 43, and the other end of the connecting sheet 42 is movably connected with the connecting seat 43.

Preferably, the separating chamber 7 is arranged in the separating cylinder 5, the bottom of the separating chamber 7 is fixedly connected with the bottom plate 81, the servo motor 8 is fixedly installed in the bottom plate 81, one end of the servo motor 8 is fixedly connected with the rotating shaft 80, the top end of the rotating shaft 80 is fixedly connected with the limiting ring 83, the middle part of the rotating shaft 80 is fixedly connected with the parallel fixing ring 82, a side wall of the upper fixing ring 82 is fixedly connected with the shifting rod 84, and a side wall of the lower fixing ring 82 is fixedly connected with the cleaning structure 85.

Preferably, the inner wall of the separation cabin 7 is provided with a first notch 71 and a second notch 72 which are parallel, the screen structure 9 is movably installed inside the first notch 71, the linkage plate 74 is movably installed inside the second notch 72, and the linkage plate 74 is movably connected with the middle part of the screen structure 9 through a fixed shaft 73.

Preferably, the bottom wall of the linkage plate 74 is fixedly connected with parallel protrusions 741, one end of the shift lever 84 movably shifts the side wall of the connection protrusion 741, the other end of the lower discharge pipe 51 is disposed between the bottom plate 81 and the linkage plate 74, and the other end of the upper discharge pipe 52 is disposed between the linkage plate 74 and the screen structure 9.

Preferably, the screen structure 9 includes a main screen 90, an annular groove 91 is formed in a side wall of the main screen 90, a secondary screen 92 is movably installed inside the annular groove 91, and a through hole 93 is formed in the middle of the main screen 90 and the secondary screen 92.

Preferably, the other side wall of the main screen 90 is fixedly connected with the handle ring 54, and the screen structure 9 is movably installed in the replacement groove 50 through the handle ring 54.

Compared with the prior art, the utility model has the beneficial effects that:

the damping device on the base has a damping effect when the separating cylinder is separated, the damping device and the bottom of the separating cylinder can be stronger through the damping spring, the device is not easy to damage, and meanwhile, strains with different specifications are screened through the upper discharging pipe and the lower discharging pipe which are arranged on two sides, so that the screening is more convenient and the structure is simplified;

simultaneously, the cleaning structure is installed through the fixed ring above and below the rotating shaft, the cleaning structure is driven to rotate on the bottom plate through rotation of the rotating shaft, strains falling on the bottom plate are stirred, the strains fall into the discharging pipe, and meanwhile, the specification of screening is adjusted through changing the position relation of the main screen and the secondary screen, so that the complex flow of changing the whole screen is omitted.

Drawings

FIG. 1 is a schematic structural view of the present invention;

FIG. 2 is a sectional view showing the internal structure of the separation chamber according to the present invention;

FIG. 3 is a schematic diagram of a screen according to the present invention.

In the figure: 1. a base; 2. a damping device; 21. a connecting plate; 22. connecting columns; 23. a damping spring; 4. a hinged seat; 41. a hinge shaft; 42. connecting sheets; 43. a connecting seat; 5. a separation cylinder; 50. replacing the groove; 51. discharging a pipe downwards; 52. feeding a discharge pipe; 53. closing the plate; 54. a handle ring; 6. a feed inlet; 7. a separation chamber; 71. a first notch; 72. a second notch; 73. a fixed shaft; 74. a linkage plate; 741. a protrusion; 8. a servo motor; 80. a rotating shaft; 81. a base plate; 82. a fixing ring; 83. a limiting ring; 84. a deflector rod; 85. cleaning the structure; 9. a screen mesh structure; 90. a main screen; 91. an annular groove; 92. a secondary screen; 93. and (6) perforating.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1-3, the present invention provides a technical solution: a cellulase strain screening system comprises a base 1, wherein a damping device 2 is rotatably connected to the base 1, a connecting plate 21 is fixedly connected to the top of the damping device 2, and a separating cylinder 5 is movably connected to the connecting plate 21;

through a plurality of spliced pole 22 rigid couplings between the bottom of knockout drum 5 and the connecting plate 21, and cup joint damping spring 23 on the spliced pole 22, change groove 50 is seted up at the middle part of knockout drum 5, discharging pipe 51 under the fixed through connection of one-third department of one side of knockout drum 5, discharging pipe 52 is connected in the fixed through connection of two-thirds department of the opposite side of knockout drum 5, it is sealed that shrouding 53 is passed through to the bottom of knockout drum 5, charge door 6 is seted up at shrouding 53 middle part, and charge door 6 runs through shrouding 53 to inside the knockout drum 5.

The side wall of the separating cylinder 5 below the replacing groove 50 is fixedly connected with a hinged seat 4, the inside of the hinged seat 4 is rotatably connected with one end of a connecting sheet 42 through a hinged shaft 41, the side wall of the separating cylinder 5 above the replacing groove 50 is fixedly connected with a connecting seat 43, and the other end of the connecting sheet 42 is movably connected with the connecting seat 43.

A separating cabin 7 is arranged in the separating cylinder 5, the bottom of the separating cabin 7 is fixedly connected with a bottom plate 81, a servo motor 8 is fixedly arranged in the bottom plate 81, one end of the servo motor 8 is fixedly connected with a rotating shaft 80, the top end of the rotating shaft 80 is fixedly connected with a limiting ring 83, the middle part of the rotating shaft 80 is fixedly connected with parallel fixing rings 82, one side wall of the upper fixing ring 82 is fixedly connected with a shifting rod 84, and one side wall of the lower fixing ring 82 is fixedly connected with a cleaning structure 85.

The inner wall of the separation cabin 7 is provided with a first notch 71 and a second notch 72 which are parallel, the screen structure 9 is movably arranged in the first notch 71, the linkage plate 74 is movably arranged in the second notch 72, and the linkage plate 74 is movably connected with the middle part of the screen structure 9 through a fixed shaft 73.

Parallel protrusions 741 are fixedly connected to the bottom wall of the linkage plate 74, one end of the poking rod 84 movably pokes the side wall of the connection protrusions 741, the other end of the lower discharging pipe 51 is arranged between the bottom plate 81 and the linkage plate 74, and the other end of the upper discharging pipe 52 is arranged between the linkage plate 74 and the screen structure 9.

The screen structure 9 comprises a main screen 90, an annular groove 91 is formed in one side wall of the main screen 90, a secondary screen 92 is movably mounted in the annular groove 91, and a through hole 93 is formed in the middle of the main screen 90 and the secondary screen 92.

The other side wall of the main screen 90 is fixedly connected with a handle ring 54, and the screen structure 9 is movably arranged in the replacement groove 50 through the handle ring 54.

The distance between the two ends of the screen structure 9 and the inner wall of the first notch 71 is smaller than the distance between the linkage plate 74 and the inner wall of the second notch 72.

The working principle is as follows: when the device is used normally, raw materials with strains are poured into the separating cylinder 5 from the feeding port 6, the servo motor 8 is started, the parallel fixing rings 82 are driven to rotate through the rotation of the servo motor 8, the fixing ring 82 above drives the shifting rod 84, when the shifting rod 84 touches the bulge 741 at the bottom of the linkage plate 74, the linkage plate 74 and the screen structure 9 are movably connected through the fixing shaft and are movably installed in the first notch 71 and the second notch 72, the linkage plate 74 drives the screen structure 9 to shake left and right, so that the strains with larger specifications cannot pass through the screen structure 9, the strains fall into the upper discharging pipe 52 through the inclination of the screen structure 9, the strains with smaller specifications fall onto the bottom plate 81 through the gap between the second notch 72 and the linkage plate 74 while shaking, and the cleaning structure 85 is installed through the fixing ring 82 above and below the rotating shaft 80, through the rotation of pivot 80, drive clearance structure 85 and rotate on bottom plate 81, stir the bacterial that will fall on bottom plate 81, make the bacterial fall into down discharging pipe 52 in, carry out the layering screening.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (7)

1. The utility model provides a cellulase bacterial screening system, includes base (1), rotate on base (1) and connect damping device (2), and damping device (2) top rigid coupling connecting plate (21), swing joint cylinder (5), its characterized in that on connecting plate (21):

through a plurality of spliced poles (22) rigid coupling between the bottom of knockout drum (5) and connecting plate (21), and cup joint damping spring (23) on spliced pole (22), change groove (50) are seted up at the middle part of knockout drum (5), discharging pipe (51) under the fixed through connection of third department of one side of knockout drum (5), discharging pipe (52) are connected in the fixed through connection of two-thirds department of the opposite side of knockout drum (5), the bottom of knockout drum (5) is sealed through shrouding (53), charge door (6) are seted up at shrouding (53) middle part, and charge door (6) run through shrouding (53) to inside of knockout drum (5).

2. The cellulase strain screening system of claim 1, wherein: change articulated seat (4) of rigid coupling on the lateral wall of cylinder (5) of groove (50) below, articulated seat (4) inside rotates the one end of connecting at connection piece (42) through hinge (41), change rigid coupling connecting seat (43) on the lateral wall of cylinder (5) of groove (50) top, the other end swing joint of connection piece (42) is on connecting seat (43).

3. The cellulase strain screening system of claim 1, wherein: separating chamber (7) are seted up to cylinder (5) inside, bottom rigid coupling bottom plate (81) of separating chamber (7), bottom plate (81) inside fixed mounting servo motor (8), and one of servo motor (8) serves and serves rigid coupling pivot (80), top rigid coupling spacing ring (83) of pivot (80), parallel solid fixed ring (82) of middle part rigid coupling of pivot (80), and a lateral wall rigid coupling driving lever (84) of the solid fixed ring (82) of top, below a lateral wall rigid coupling clearance structure (85) of solid fixed ring (82).

4. The cellulase strain screening system of claim 3, wherein: the inner wall of the separation cabin (7) is provided with a first notch (71) and a second notch (72) which are parallel to each other, the screen structure (9) is movably mounted in the first notch (71), a linkage plate (74) is movably mounted in the second notch (72), and the linkage plate (74) is movably connected with the middle part of the screen structure (9) through a fixed shaft (73).

5. The cellulase strain screening system of claim 4, wherein: parallel protrusions (741) are fixedly connected to the bottom wall of the linkage plate (74), one end of the poking rod (84) movably pokes the side wall of the connection protrusions (741), the other end of the lower discharging pipe (51) is arranged between the base plate (81) and the linkage plate (74), and the other end of the upper discharging pipe (52) is arranged between the linkage plate (74) and the screen structure (9).

6. The cellulase strain screening system of claim 4, wherein: the screen structure (9) comprises a main screen (90), an annular groove (91) is formed in one side wall of the main screen (90), a secondary screen (92) is movably mounted in the annular groove (91), and a through hole (93) is formed in the middle of the main screen (90) and the secondary screen (92).

7. The cellulase strain screening system of claim 6, wherein: the other side wall of the main screen (90) is fixedly connected with a handle ring (54), and a screen structure (9) is movably arranged in the replacing groove (50) through the handle ring (54).

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