CN114184011A - Efficient drying system is used in production of montmorillonite powder - Google Patents

Abstract

The invention relates to the technical field of montmorillonite powder production, in particular to a high-efficiency drying system for montmorillonite powder production. Comprises an insulation can, a vacuum component, an accommodating box and a bearing seat. The vacuum component is communicated with the heat preservation box. The bearing seat is arranged in the heat preservation box. The bearing surface of the bearing seat is provided with a mounting groove, and the mounting groove is formed by sinking the bearing surface of the bearing seat. The mounting groove is internally provided with a rotating part and driven by a first driving assembly, and the top of the rotating part is eccentrically provided with a convex block. The bottom of the containing box is made of flexible materials, and the containing box is detachably arranged on the bearing seat. The efficient drying system for the bulk montmorillonite production has a first working state, and in the first working state, the lug is abutted to the bottom of the accommodating box. The method can efficiently and fully dry the montmorillonite powder, avoids repeated drying procedures in the previous procedure, reduces the waste of production resources, ensures the continuous propulsion of the production flow, and does not influence the drying of subsequent powder products.

Description

Efficient drying system is used in production of montmorillonite powder

Technical Field

The invention relates to the technical field of montmorillonite powder production, and particularly relates to a high-efficiency drying system for montmorillonite powder production.

Background

At present, in the production process of montmorillonite powder, montmorillonite powder can not be fully dried after being dried by a traditional drying procedure, and moisture still remains in the powder. In order to achieve sufficient drying, it is generally necessary to repeat the drying process. Because the residual moisture in the powder is less after the primary drying, the yield of repeatedly executing the drying process is very low, the cost is very high, the production progress is seriously slowed, and the drying process of other powder products is influenced.

In view of this, the present application is specifically made.

Disclosure of Invention

The invention aims to provide an efficient drying system for montmorillonite powder production, which can efficiently and fully dry montmorillonite powder, avoid repeated drying procedures in the previous procedure, reduce waste of production resources, ensure continuous propulsion of the production flow and avoid influence on drying of subsequent powder products. The method is suitable for fully drying the primarily dried montmorillonite powder, is efficient and energy-saving, is beneficial to reducing the production cost and ensures the production order.

The embodiment of the invention is realized by the following steps:

a high-efficiency drying system for producing montmorillonite powder comprises: insulation can, vacuum module, hold box and bear the seat. The vacuum component is communicated with the heat preservation box. The bearing seat is arranged in the heat preservation box.

The bearing surface of the bearing seat is provided with a mounting groove, and the mounting groove is formed by sinking the bearing surface of the bearing seat. The mounting groove is internally provided with a rotating part and driven by a first driving assembly, and the top of the rotating part is eccentrically provided with a convex block. The bottom of the containing box is made of flexible materials, and the containing box is detachably arranged on the bearing seat.

The efficient drying system for the bulk montmorillonite production has a first working state, and in the first working state, the lug is abutted to the bottom of the accommodating box.

Further, a base is accommodated in the mounting groove, and the base is slidably fitted to the mounting groove and driven by the second driving assembly in a depth direction of the mounting groove. The rotating part is rotatably arranged on the base, and the first driving assembly is arranged in the base.

The efficient drying system for the bulk montmorillonite production has a second working state, and in the second working state, the lug is separated from the bottom of the accommodating box.

Furthermore, the rotating parts are in multiple groups, and the multiple groups of rotating parts are distributed in an array along the surface of the base.

Furthermore, the base is provided with a yielding notch, the yielding notch is positioned in the middle of the base and is in a strip shape, and the yielding notch penetrates through the top wall of the base to the bottom wall of the base. The yielding notch is internally provided with a moving seat, and the moving seat can be matched in the yielding notch in a sliding way and driven by a third driving assembly along the depth direction of the mounting groove.

The motion seat is rotatably provided with a rotating rod and driven by a fourth driving component, and the rotating rod is arranged parallel to the bearing surface of the bearing seat.

In the first operating state, the rotating lever is separated from the bottom of the containing box. In the second working state, the rotating rod is abutted against the bottom of the accommodating box.

Further, the second driving assembly includes a sliding lever, a rotation shaft, a first rotation arm, a second rotation arm, and a linear driver.

The sliding rod is fixedly connected with the base and arranged along the depth direction of the mounting groove, the rotating shaft is mounted on the bearing seat, the first rotating arm and the second rotating arm are matched with the rotating shaft, and the first rotating arm is in transmission fit with the driving part of the linear driver so that the second rotating arm can drive the sliding rod to slide.

Further, the linear driver comprises a servo motor, a screw rod and a sleeve. The screw rod is in transmission fit with a power output part of the servo motor, the sleeve is provided with internal threads, and the screw rod is accommodated in the sleeve and is in threaded fit with the sleeve.

The screw rod and the sleeve form a third driving assembly, and the sleeve is fixedly connected to the moving seat and arranged along the depth direction of the mounting groove. The first rotating arm is in transmission fit with the sleeve.

Further, the bearing seat is also provided with an inner cavity which is positioned below the mounting groove. The slide bar runs through the bottom of mounting groove and runs through to the inner chamber, and the sleeve runs through the bottom of mounting groove and runs through to the inner chamber.

The telescopic both sides are located for two sets of and branch to the slide bar, and the axis of rotation is installed in the inner chamber and is close to one side inner wall of mounting groove, and the axis of rotation is located between slide bar and the sleeve, and first rotor arm extends towards the sleeve by the axis of rotation, and the second rotor arm extends towards the sleeve slide bar by the axis of rotation.

Further, the first rotating arm and the second rotating arm are provided with sliding grooves extending along the length direction of the first rotating arm and the second rotating arm, the outer walls of the sliding rod and the sleeve are fixedly provided with limiting columns, and the limiting columns are matched in the sliding grooves in a sliding mode.

Further, the both sides of bearing the seat all are provided with the locating part, and the locating part includes first limiting plate and second limiting plate, and first limiting plate sets up along the edge of bearing the seat, and second limiting plate and first limiting plate fixed connection extend towards the middle part of bearing the seat. The surface of the bearing seat, the first limiting plate and the second limiting plate form a limiting groove. Flanges are arranged on two sides of the accommodating box and are matched with the limiting grooves.

Furthermore, the second limiting plate is provided with a screw hole penetrating through the second limiting plate, and a screw rod is installed in the screw hole. The end part of the screw rod is rotatably matched with a rotating column, and one end of the rotating column, which is close to the bearing seat, is provided with a rubber layer.

The technical scheme of the embodiment of the invention has the beneficial effects that:

in the efficient drying system for montmorillonite powder production, provided by the embodiment of the invention, montmorillonite powder is contained in the containing box in the drying process, and when the containing box is arranged on the bearing seat, the containing box cover is arranged on the mounting groove. When the efficient drying system for the bulk montmorillonite production enters a first working state, the lug is abutted against the bottom of the accommodating box, the bottom of the accommodating box is jacked up by the lug to deform, and the part of the bottom of the accommodating box, which is in contact with the lug, is bulged upwards. When the rotation piece is driven by the first driving assembly and starts to rotate, the lug can periodically disturb the bottom of the accommodating box, so that montmorillonite powder in the accommodating box can be turned, and the montmorillonite powder is conveniently and fully dried.

In general, the efficient drying system for montmorillonite powder production provided by the embodiment of the invention can efficiently and fully dry montmorillonite powder, avoid repeated drying procedures in previous procedures, reduce waste of production resources, ensure continuous promotion of production flow and avoid influence on drying of subsequent powder products. The method is suitable for fully drying the primarily dried montmorillonite powder, is efficient and energy-saving, is beneficial to reducing the production cost and ensures the production order.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings needed to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

FIG. 1 is a schematic view of the overall structure of a high-efficiency drying system for producing montmorillonite powder provided by an embodiment of the invention;

FIG. 2 is a schematic structural diagram of a carrying seat of the efficient drying system for montmorillonite powder production according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a containing box installed on a bearing seat of the efficient drying system for montmorillonite powder production provided by the embodiment of the invention;

fig. 4 is a schematic view of another perspective structure of a bearing seat of the efficient drying system for montmorillonite powder production according to the embodiment of the invention;

fig. 5 is a schematic view of the efficient drying system for montmorillonite powder production provided by the embodiment of the invention in a first working state;

fig. 6 is a schematic view of the efficient drying system for montmorillonite powder production provided in the embodiment of the present invention in a second operating state;

fig. 7 is a schematic structural diagram of a position limiting part of the efficient drying system for producing montmorillonite powder provided by the embodiment of the invention.

Description of reference numerals:

high-efficiency drying system 1000 for montmorillonite powder production; an incubator 100; the housing box 200; a flange 210; a carrier base 300; a mounting groove 310; an inner cavity 320; a stopper 330; a first limit plate 331; the second restriction plate 332; a screw 333; a rotating post 334; a rubber layer 335; a rotating member 400; a bump 410; a base 500; a slide bar 510; a rotating shaft 520; a first rotation arm 530; a second rotating arm 540; a servo motor 550; a screw rod 560; a sleeve 570; a chute 581; a limit post 582; a yield gap 590; a kinematic seat 600; rotating the rod 610.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, 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 some, but not all, embodiments of the present invention. The components of embodiments of the present invention generally described and illustrated in the figures herein may be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present invention, presented in the figures, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. 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.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined and explained in subsequent figures.

The terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "parallel," "perpendicular," and the like do not require that the components be absolutely parallel or perpendicular, but may be slightly inclined. For example, "parallel" merely means that the directions are more parallel relative to "perpendicular," and does not mean that the structures are necessarily perfectly parallel, but may be slightly tilted.

In the description of the present invention, it should also be noted that, unless otherwise explicitly specified or limited, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly and may, for example, be fixedly connected, detachably connected, or integrally connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

Examples

Referring to fig. 1 to 6, in this embodiment, a high-efficiency drying system 1000 for producing montmorillonite powder is provided, where the high-efficiency drying system 1000 for producing montmorillonite powder includes: an incubator 100, a vacuum assembly, a containing box 200, and a carrying base 300.

The incubator 100 includes a temperature raising unit and a temperature control unit, and can maintain the temperature near a set temperature. A vacuum assembly (not shown) is connected to the thermal container 100, and the vacuum assembly can provide a certain vacuum degree to the thermal container 100, so as to dry the montmorillonite powder sufficiently and discharge the moisture sufficiently.

The supporting bases 300 are disposed in the thermal insulation box 100 and arranged in the thermal insulation box 100.

The carrying surface of the carrying seat 300 is formed with a mounting groove 310, and the mounting groove 310 is formed by recessing the carrying surface of the carrying seat 300. The rotation member 400 is installed in the installation groove 310 and driven by the first driving unit, and a protrusion 410 is eccentrically disposed on the top of the rotation member 400. The bottom of the accommodation box 200 is made of a flexible material, and the accommodation box 200 is detachably mounted to the carrier base 300.

The efficient drying system 1000 for the bulk montmorillonite production has a first working state in which the projection 410 abuts against the bottom of the containing box 200.

In the drying process, the montmorillonite powder is contained in the containing case 200, and when the containing case 200 is mounted on the bearing seat 300, the containing case 200 is covered on the mounting groove 310. When the efficient drying system 1000 for montmorillonite bulk production enters the first working state, the projection 410 abuts against the bottom of the containing box 200, the bottom of the containing box 200 is jacked up by the projection 410 and deformed, and the contact part of the bottom of the containing box 200 and the projection 410 is raised upwards. When the rotating member 400 is driven by the first driving assembly to start rotating, the protrusion 410 can periodically disturb the bottom of the accommodating box 200, so that the montmorillonite powder in the accommodating box 200 can be stirred, and the montmorillonite powder can be rapidly and sufficiently dried.

In general, the efficient drying system 1000 for montmorillonite powder production can efficiently and fully dry montmorillonite powder, avoid repeated drying processes in the previous process, reduce waste of production resources, ensure continuous propulsion of the production process and avoid influence on drying of subsequent powder products. The method is suitable for fully drying the primarily dried montmorillonite powder, is efficient and energy-saving, is beneficial to reducing the production cost and ensures the production order.

Further, the mounting groove 310 accommodates the base 500 therein, and the base 500 is slidably fitted to the mounting groove 310 in a depth direction of the mounting groove 310 and driven by the second driving assembly. The rotation member 400 is rotatably installed on the base 500, and a first driving assembly (not shown) is built in the base 500.

The efficient drying system 1000 for the bulk smectite production has a second working state in which the bump 410 is separated from the bottom of the housing box 200.

In the present embodiment, the rotating members 400 are provided in multiple groups, and the multiple groups of rotating members 400 are distributed along the surface of the base 500 in an array.

The base 500 is provided with the notch 590 of stepping down, and the notch 590 of stepping down is located the middle part of base 500, and the notch 590 of stepping down is the strip along the surface of base 500 and extends, and along the depth direction of mounting groove 310, the notch 590 of stepping down runs through to run through base 500 to its diapire by the roof of base 500. The receding gap 590 accommodates the moving seat 600 therein, and along the depth direction of the installation groove 310, the moving seat 600 is slidably fitted in the receding gap 590 and driven by the third driving assembly.

The movable seat 600 is rotatably installed with a rotating rod 610 and driven by a fourth driving assembly, the rotating rod 610 is disposed parallel to the bearing surface of the bearing seat 300, and the rotating rod 610 extends along the length direction of the abdicating notch 590. A fourth driving assembly (not shown) is built in the kinematic seat 600.

In the first operation state, the rotating lever 610 is separated from the bottom of the accommodation box 200 and accommodated in the escape notch 590. In the second operation state, the rotating lever 610 protrudes from the relief notch 590 and abuts against the bottom of the accommodation box 200. After the rotating rod 610 abuts against the bottom of the accommodating box 200, the rotating rod 610 is driven by the fourth driving component, and the rotating rod 610 can periodically turn over the bottom of the accommodating box 200 in a large area. The montmorillonite powder in the accommodating box 200 can be effectively turned by switching between the first working state and the second working state, so that the drying efficiency is greatly improved.

The efficient drying system 1000 for the bulk smectite production further has a third working state in which the projection 410 is separated from the bottom of the housing box 200 and the rotating lever 610 is also separated from the bottom of the housing box 200. With scattered production of montmorillonite with high-efficient drying system 1000 switch into third operating condition, be convenient for install and dismantle holding box 200.

Further, the second driving assembly includes a sliding bar 510, a rotation shaft 520, a first rotation arm 530, a second rotation arm 540, and a linear driver.

The sliding rod 510 is fixedly connected to the base 500 and is disposed along the depth direction of the mounting groove 310, the rotating shaft 520 is mounted on the bearing seat 300, the first rotating arm 530 and the second rotating arm 540 are both engaged with the rotating shaft 520, and the first rotating arm 530 is in transmission engagement with the driving portion of the linear actuator, so that the second rotating arm 540 can drive the sliding rod 510 to slide.

Specifically, the linear actuator includes a servo motor 550, a lead screw 560, and a sleeve 570. The screw 560 is in transmission fit with a power output part of the servo motor 550, the sleeve 570 has internal threads, and the screw 560 is accommodated in the sleeve 570 and is in threaded fit with the sleeve 570.

The screw 560 and the sleeve 570 constitute a third driving assembly, and the sleeve 570 is fixedly coupled to the moving seat 600 and disposed along the depth direction of the mounting groove 310. The first rotatable arm 530 is in driving engagement with the sleeve 570.

The carrier 300 further has an inner cavity 320, and the inner cavity 320 is located below the mounting groove 310. The sliding rod 510 penetrates the bottom of the mounting groove 310 and to the inner cavity 320, and the sleeve 570 penetrates the bottom of the mounting groove 310 and to the inner cavity 320.

The sliding rods 510 are divided into two groups and arranged at two sides of the sleeve 570, the rotating shaft 520 is arranged on the inner wall of the inner cavity 320 near one side of the mounting groove 310, the rotating shaft 520 is arranged between the sliding rods 510 and the sleeve 570, the first rotating arm 530 extends from the rotating shaft 520 to the sleeve 570, and the second rotating arm 540 extends from the rotating shaft 520 to the sleeve 570 and the sliding rods 510.

The servo motor 550 is installed at the bottom of the carriage 300, but the installation position is not limited thereto and can be flexibly adjusted and selected.

The first rotating arm 530 and the second rotating arm 540 are both provided with a sliding groove 581 extending along the length direction thereof, the outer walls of the sliding rod 510 and the sleeve 570 are both fixedly provided with a limiting column 582, and the limiting column 582 is slidably fitted in the sliding groove 581.

Through the above design, the second driving assembly and the third driving assembly are integrated, and the synchronous movement of the base 500 and the motion base 600 can be controlled only by controlling the operation of the servo motor 550. Wherein, when the base 500 is raised, the kinematic seat 600 is lowered; when the base 500 is lowered, the kinematic seat 600 is raised. Thus, the switching among the first working state, the second working state and the third working state can be flexibly realized. It can be understood that the operation of the servo motor 550 can be controlled by means of a PLC system, so as to realize the automatic switching among the first operating state, the second operating state and the third operating state.

Further, referring to fig. 7, the two sides of the bearing seat 300 are provided with the limiting members 330, each limiting member 330 includes a first limiting plate 331 and a second limiting plate 332, the first limiting plate 331 is disposed along the edge of the bearing seat 300, and the second limiting plate 332 is fixedly connected to the first limiting plate 331 and extends toward the middle of the bearing seat 300. The surface of the bearing seat 300, the first limit plate 331 and the second limit plate 332 form a limit groove. Flanges 210 are arranged on two sides of the accommodating box 200, and the flanges 210 are matched with the limiting grooves.

The second limiting plate 332 is provided with a screw hole penetrating through the second limiting plate, and a screw 333 is installed in the screw hole. The end of the screw 333 is rotatably engaged with a rotary post 334, and one end of the rotary post 334 close to the bearing seat 300 is provided with a rubber layer 335.

With this design, the accommodation box 200 can be slid into the retaining groove from the end of the carrier 300, and the retaining member 330 can fix the flange 210 on the surface of the carrier 300. After the screw 333 is screwed, the accommodating box 200 can be prevented from being deviated, thereby ensuring the smooth proceeding of the drying process.

In the present embodiment, the bump 410 has a hemispherical shape.

In summary, the efficient drying system 1000 for montmorillonite powder production provided by the embodiment of the invention can efficiently and fully dry montmorillonite powder, avoid repeated drying processes in previous processes, reduce waste of production resources, ensure continuous promotion of production processes, and do not affect drying of subsequent powder products. The method is suitable for fully drying the primarily dried montmorillonite powder, is efficient and energy-saving, is beneficial to reducing the production cost and ensures the production order.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (10)

1. A high-efficient drying system is used in production of montmorillonite powder, which characterized by comprising: the vacuum box comprises an insulation box, a vacuum assembly, an accommodating box and a bearing seat; the vacuum assembly is communicated with the heat insulation box; the bearing seat is arranged in the heat insulation box;

the bearing surface of the bearing seat is provided with an installation groove, and the installation groove is formed by sinking the bearing surface of the bearing seat; a rotating part is arranged in the mounting groove and driven by a first driving assembly, and a convex block is eccentrically arranged at the top of the rotating part; the bottom of the accommodating box is made of flexible materials, and the accommodating box is detachably arranged on the bearing seat;

the efficient drying system for the montmorillonite bulk production has a first working state, and in the first working state, the lug is abutted against the bottom of the accommodating box.

2. The efficient drying system for montmorillonite bulk production according to claim 1, wherein a base is accommodated in the mounting groove, and the base is slidably fitted to the mounting groove and driven by a second driving member in a depth direction of the mounting groove; the rotating part is rotatably arranged on the base, and the first driving assembly is arranged in the base;

the efficient drying system for the montmorillonite powder production has a second working state, and in the second working state, the lug is separated from the bottom of the accommodating box.

3. The efficient drying system for montmorillonite powder production according to claim 2, wherein the rotating members are in a plurality of groups, and the plurality of groups of rotating members are distributed in an array along the surface of the base.

4. The efficient drying system for montmorillonite powder production according to claim 2, wherein the base is provided with an abdicating notch, the abdicating notch is located in the middle of the base, the abdicating notch is strip-shaped, and the abdicating notch penetrates from the top wall to the bottom wall of the base; the abdicating notch is internally provided with a moving seat, and the moving seat can be slidably matched in the abdicating notch and driven by a third driving component along the depth direction of the mounting groove;

the moving seat is rotatably provided with a rotating rod and driven by a fourth driving assembly, and the rotating rod is arranged parallel to the bearing surface of the bearing seat;

in the first working state, the rotating rod is separated from the bottom of the accommodating box; in the second working state, the rotating rod is propped against the bottom of the accommodating box.

5. The efficient drying system for montmorillonite bulk production of claim 4, wherein the second drive assembly comprises a sliding rod, a rotating shaft, a first rotating arm, a second rotating arm, and a linear drive;

the sliding rod is fixedly connected with the base and arranged along the depth direction of the mounting groove, the rotating shaft is mounted on the bearing seat, the first rotating arm and the second rotating arm are matched with the rotating shaft, and the first rotating arm is in transmission fit with the driving part of the linear driver so that the second rotating arm can drive the sliding rod to slide.

6. The efficient drying system for montmorillonite powder production of claim 5, wherein the linear drive comprises a servo motor, a lead screw and a sleeve; the screw rod is in transmission fit with a power output part of the servo motor, the sleeve is provided with internal threads, and the screw rod is accommodated in the sleeve and is in threaded fit with the sleeve;

the screw rod and the sleeve form the third driving assembly, and the sleeve is fixedly connected to the moving seat and arranged along the depth direction of the mounting groove; the first rotating arm is in transmission fit with the sleeve.

7. The efficient drying system for montmorillonite powder production according to claim 6, wherein the bearing seat further has an inner cavity, and the inner cavity is located below the mounting groove; the sliding rod penetrates through the bottom of the mounting groove and penetrates to the inner cavity, and the sleeve penetrates through the bottom of the mounting groove and penetrates to the inner cavity;

the slide bar is two sets of and locates the both sides of sleeve, the axis of rotation install in the inner chamber is close to one side inner wall of mounting groove, the axis of rotation is located the slide bar with between the sleeve, first rotor arm by the axis of rotation court the sleeve extends, the second rotor arm by the axis of rotation court the sleeve slide bar extends.

8. The efficient drying system for montmorillonite powder production as claimed in claim 7, wherein the first rotating arm and the second rotating arm are both provided with a sliding groove extending along the length direction thereof, the sliding rod and the outer wall of the sleeve are both fixedly provided with a limiting post, and the limiting post is slidably fitted in the sliding groove.

9. The efficient drying system for montmorillonite powder production according to claim 1, wherein limiting members are disposed on both sides of the bearing seat, the limiting members comprise a first limiting plate and a second limiting plate, the first limiting plate is disposed along an edge of the bearing seat, and the second limiting plate is fixedly connected with the first limiting plate and extends toward the middle of the bearing seat; the surface of the bearing seat, the first limiting plate and the second limiting plate form a limiting groove; flanges are arranged on two sides of the accommodating box and are matched with the limiting grooves.

10. The efficient drying system for montmorillonite powder production according to claim 9, wherein the second limiting plate is provided with a screw hole through which the second limiting plate passes, and a screw is installed in the screw hole; the end part of the screw rod is rotatably matched with a rotating column, and one end of the rotating column, which is close to the bearing seat, is provided with a rubber layer.

Images