CN212411422U - Taylorgutt flow state experimental apparatus - Google Patents

Abstract

The utility model discloses a Taylor Kute flow state experimental device, which comprises an outer barrel, an upper end cover and a lower base, wherein the upper end cover and the lower base are respectively arranged on the upper end and the lower end of the outer barrel to form a fluid flow cavity, the lower surface of the lower base is fixedly connected with one end of a first rotating shaft, and the other end of the first rotating shaft is connected with a first servo motor; an inner cylinder is arranged in the fluid flow cavity, an annular gap for fluid flow is formed between the inner cylinder and the outer cylinder, a second rotating shaft is arranged in the inner cylinder, the lower end of the second rotating shaft is rotatably connected with the lower base, and the upper end of the second rotating shaft penetrates through the upper end cover and then is connected with a second servo motor; the upper end cover is provided with a liquid inlet for guiding fluid into an annular gap between the outer barrel and the inner barrel, the lower base is provided with a liquid drainage channel for draining the fluid, and the external port of the liquid drainage channel is provided with a detachable bolt for plugging the fluid. The device can realize that binocular independently sets up the rotational speed and turns to, and the rotational speed is controllable, but the annular gap width quick adjustment between two section of thick bamboo, and the device leakproofness is good, and coaxial degree is high.

Description

Taylorgutt flow state experimental apparatus

Technical Field

The utility model relates to a hydrodynamics technical field specifically is a taylor couette flow state experimental apparatus.

Background

Fluid flow between two coaxial rotating cylinders is a classical fluid dynamics problem, known as "Taylor-Couette" flow, the taylorgurt flow. The fluid in the cylinder annular gap can present a plurality of flow states such as laminar flow, Taylor vortex, turbulent flow and the like due to the difference of the rotation modes and the rotation speeds of the two cylinders, the process has important academic significance for researching turbulent flow, fluid stability and the like, the complicated and changeable flow form of the fluid is the focus of attention of a plurality of researchers for a long time, and the researchers continuously develop related theoretical analysis, numerical calculation and experimental observation research so far. The Taylorgutt removal can be used for theoretical research in the direction of fluid mechanics, and can also be widely applied to equipment for blending, grinding, extraction and the like in industry, such as: the filtration device adopting the eddy current to reduce concentration polarization, the rotating cylindrical electrode, the two-phase emulsified countercurrent liquid extractor and the like have important practical application values.

There are four common forms of rotation of the two cylinders: the outer cylinder is fixed, and the inner cylinder rotates; the inner cylinder is fixed, and the outer cylinder rotates; the inner and outer cylinders rotate in the same direction; the inner and outer cylinders rotate in opposite directions. Most of the existing experimental devices only rotate one cylinder, the other cylinder is fixed, the transmission mode is belt transmission, independent speed regulation rotation of the two cylinders cannot be realized, transmission errors exist in the belt transmission, and flow state distribution in an annular gap under a specified Reynolds number cannot be accurately observed; most experimental devices are fixed in structure, the width of an annular gap between the two cylinders cannot be adjusted quickly, when different annular gap sizes need to be observed, devices can be manufactured again or modified more complexly, and the utilization rate of the devices is low; finally, most of the existing experimental devices adopt through shafts, and the problems of solution leakage and poor coaxiality degree in the annular space exist in the devices.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art not enough, and provide a taylor kutt flows state experimental apparatus, the device can realize that the binocular independently sets up the rotational speed and turns to, and the rotational speed is controllable, but the annular gap width quick adjustment between two, and the device seal is good, and coaxial degree is high.

Realize the utility model discloses the technical scheme of purpose is:

a Taylorgutt flow state experimental apparatus, including the outer cylinder, upper end cap, lower base set up in the outer cylinder, lower end form the fluid flow cavity separately, the lower surface of the lower base is fixedly connected with one end of the first spindle through the flange plate, another end of the first spindle passes the first dead plate, second dead plate sequentially, connect with first servomotor through the first shaft coupling; an inner cylinder is arranged in the fluid flow cavity, an annular gap for fluid flow is formed between the inner cylinder and the outer cylinder, a second rotating shaft is arranged in the inner cylinder, the lower end of the second rotating shaft is rotatably connected with the lower base, and the upper end of the second rotating shaft penetrates through the upper end cover, then penetrates through a third fixing plate and then is connected with a second servo motor through a second coupler;

the upper end cover is provided with a liquid inlet for guiding fluid into an annular gap between the outer barrel and the inner barrel, the lower base is provided with a liquid drainage channel for discharging the fluid, and the external port of the liquid drainage channel is provided with a detachable bolt for blocking the fluid.

The first rotating shaft is rotatably connected with the first fixing plate and the second fixing plate; a first bearing sleeve is arranged between the first rotating shaft and the first fixing plate, tapered roller bearings are embedded at the upper end and the lower end of the first bearing sleeve, and the first rotating shaft is rotatably connected with the first fixing plate through the tapered roller bearings; a bearing seat is arranged between the first rotating shaft and the second fixing plate, a ball bearing is embedded in the bearing seat, and the first rotating shaft and the second fixing plate are rotatably connected through the ball bearing.

And a locking mechanism is arranged on the first rotating shaft above the connecting part of the first rotating shaft and the second fixing plate, and is used for keeping the outer cylinder in a static state when the inner cylinder rotates independently so as to ensure that the outer cylinder does not rotate and deviate.

The lower end of the second rotating shaft is designed into a step shape, the lower base is provided with a step-shaped groove matched with the second rotating shaft, a deep groove ball bearing is embedded in the step of the groove, the bottommost plane of the groove is a semi-circular arc surface, a ball is arranged on the semi-circular arc surface, and the second rotating shaft is rotatably connected with the lower base through the deep groove ball bearing and the ball.

The second rotating shaft is rotatably connected with the third fixing plate, a second bearing sleeve is arranged between the second rotating shaft and the third fixing plate, deep groove ball bearings are embedded at the upper end and the lower end of the second bearing sleeve, and the second rotating shaft is rotatably connected with the third fixing plate through the deep groove ball bearings.

The top of the inner cylinder is connected with the second rotating shaft through a key, and a locking ring is arranged above the mounting key of the second rotating shaft and used for reducing shaking and keeping the inner cylinder and the second rotating shaft from moving relatively.

The first fixing plate, the second fixing plate and the third fixing plate are parallel to each other and are respectively fixed on the support frame; the first servo motor and the second servo motor are respectively arranged on the bottom supporting plate and the top supporting plate of the supporting frame through motor seats.

The flowing back passageway be the L type, evenly be equipped with 3 flowing back passageways on the base down, the inner wall of outside port department is equipped with screw thread and detachable butterfly bolt meshing.

The annular space between the outer cylinder and the inner cylinder is 2-15mm, a sealing gasket is arranged between the outer cylinder and the lower base and is compressed through a bolt, and the outer cylinder is made of transparent materials, so that the flowing condition of fluid can be observed conveniently in an experiment.

The utility model provides a pair of taylor couette flow state experimental apparatus, the device has following advantage:

1. the inner cylinder and the outer cylinder are respectively connected with the servo motor through the coupler, the steering and the rotating speed of the inner cylinder and the outer cylinder can be freely controlled, and the fluid condition in the annular gap can be favorably observed under the appointed Reynolds number;

2. the distance between the annular gaps between the outer cylinder and the inner cylinder can be adjusted, so that the Taylorgutt flow under different parameters can be tested and verified;

3. a sealing gasket is arranged between the outer barrel and the lower base and is tightly pressed through a bolt, so that the tightness of the device is ensured, and the second rotating shaft does not penetrate through the lower base, so that a complex sealing structure is not needed, the problem of leakage of an experimental solution is avoided, and the influence of the leakage of the experimental solution on an experiment is reduced;

4. through the matching of the bearing sleeve and the first rotating shaft and the second rotating shaft, the rotating shafts are prevented from inclining, the bending deformation is reduced, and the coaxiality of the device is ensured; the end cover at the top can reduce the deformation of the outer cylinder, ensure the cylinder surface level between the two cylinders and be beneficial to ensuring the reliability of the experimental result.

Drawings

FIG. 1 is a schematic structural diagram of a Taylorgutt flow regime experimental apparatus;

FIG. 2 is an enlarged view of portion A of FIG. 1;

FIG. 3 is an enlarged view of portion B of FIG. 1;

FIG. 4 is a schematic structural view of the upper end cap;

in the figure: 1. the support frame 2, the second fixing plate 3, the first fixing plate 4, the lower base 5, the outer cylinder 6, the annular gap 7, the inner cylinder 8, the upper end cover 9, the third fixing plate 10, the second servo motor 11, the second coupler 12, the second bearing sleeve 13, the deep groove ball bearing 14, the bolt 15, the butterfly bolt 16, the liquid discharge channel 17, the brake caliper 18, the bearing seat 19, the first coupler 20, the first servo motor 21, the adjusting pin 22, the brake disc 23, the first locking ring 24, the first rotating shaft 25, the second rotating shaft 26, the first bearing sleeve 27, the tapered roller bearing 28, the ball flange 30, the second locking ring 31, the key 32, the liquid inlet 33 and the hexagon socket screw.

Detailed Description

The present invention will be further explained with reference to the drawings and examples, but the present invention is not limited thereto.

As shown in fig. 1, a taylorgutt flow state experimental device comprises an outer cylinder 5, an upper end cover 8 and a lower base 4, wherein the upper end cover 8 and the lower base 4 are respectively arranged at the upper end and the lower end of the outer cylinder 5 to form a fluid flow cavity, as shown in fig. 2, the lower surface of the lower base 4 is fixedly connected with one end of a first rotating shaft 24 through a flange 29, and the other end of the first rotating shaft 24 sequentially penetrates through a first fixing plate 3 and a second fixing plate 2 and then is connected with a first servo motor 20 through a first coupler 19; an inner cylinder 7 is arranged in the fluid flow cavity, an annular gap 6 for fluid flow is formed between the inner cylinder 7 and the outer cylinder 5, a second rotating shaft 25 is arranged in the inner cylinder 7, the lower end of the second rotating shaft 25 is rotatably connected with the lower base 4, and the upper end of the second rotating shaft 25 penetrates through the upper end cover 8, then penetrates through a third fixing plate 9 and then is connected with a second servo motor 10 through a second coupler 11;

as shown in fig. 4, the upper end cover 8 is provided with a liquid inlet 32 for introducing a fluid into the annular gap 6 between the outer cylinder 5 and the inner cylinder 7, the edge of the upper end cover 8 is fixedly connected with the outer cylinder through a hexagon socket screw 33, the lower base 4 is provided with a liquid drainage channel 16 for draining the fluid, and a detachable butterfly bolt 15 for blocking the fluid is arranged at an outer port of the liquid drainage channel 16.

The first rotating shaft 24 is rotatably connected with the first fixing plate 3 and the second fixing plate 2; as shown in fig. 2, a first bearing sleeve 26 is arranged between the first rotating shaft 24 and the first fixing plate 3, tapered roller bearings 27 are embedded at the upper and lower ends of the first bearing sleeve 26, and the first rotating shaft 24 is rotatably connected with the first fixing plate 3 through the tapered roller bearings 27; a bearing seat 18 is arranged between the first rotating shaft 24 and the second fixing plate 2, a ball bearing is embedded in the bearing seat, and the first rotating shaft 24 is rotatably connected with the second fixing plate 2 through the ball bearing.

The first rotating shaft 24 is provided with a locking mechanism above the connecting part of the first rotating shaft 24 and the second fixing plate 2, and the locking mechanism is used for keeping the outer cylinder in a static state when the inner cylinder rotates independently so as to ensure that the outer cylinder does not rotate and deviate. The locking mechanism may be a product having a locking function in the prior art, and the locking mechanism used in this embodiment includes a brake disc 22, a first locking ring 23, and a brake caliper 17, the brake disc 22 is fixed on the first rotating shaft 24 by the first locking ring 23, and the brake caliper 17 is fixed on the second fixing plate 2 for locking the brake disc 22.

As shown in fig. 2, the lower end of the second rotating shaft 25 is designed to be stepped, the lower base 4 is provided with a stepped groove matched with the second rotating shaft 25, a deep groove ball bearing 13 is embedded in the step of the groove, the bottommost plane of the groove is a semi-circular arc surface, a ball 28 is arranged on the semi-circular arc surface, and the second rotating shaft 25 is rotatably connected with the lower base 4 through the deep groove ball bearing 13 and the ball 28.

Second pivot 25 and third fixed plate 9 rotate and be connected, be equipped with second bearing housing 12 between second pivot 25 and the third fixed plate 9, deep groove ball bearing 13 is inlayed at both ends about second bearing housing 12, realizes that second pivot 25 and third fixed plate 9 rotate through deep groove ball bearing 13 and is connected.

As shown in FIG. 3, the top of the inner cylinder 7 is connected with the second rotating shaft 25 by a key 31, and a second locking ring 30 is arranged above the key-mounting portion of the second rotating shaft 25 for reducing the shaking and keeping the inner cylinder 7 and the second rotating shaft 25 from moving relatively.

The first fixing plate 3, the second fixing plate 2 and the third fixing plate 9 are parallel to each other and are respectively fixed on the support frame 1; first servo motor 20, second servo motor 10 are established respectively on the bottom sprag board and the top sprag board of support frame 1 through the motor cabinet, and the bottom of support frame 1 is equipped with adjusts foot 21.

The drainage channel 16 be the L type, evenly be equipped with 3 drainage channels 16 on base 4 down, the inner wall of outside port department is equipped with the screw thread and meshes with detachable butterfly bolt 15.

The distance between the annular gap 6 between the outer cylinder 5 and the inner cylinder 7 is 2-15mm, a sealing gasket is arranged between the outer cylinder 5 and the lower base 4 and is tightly pressed through a bolt 14, and the outer cylinder 5 is made of transparent materials, so that the flowing condition of fluid can be observed conveniently during experiments.

Example 1:

firstly, determining the rotating speed and the rotating direction of the inner cylinder 7 and the outer cylinder 5 in the experiment, adjusting corresponding parameters of a controller to enable a driver to drive a first servo motor 20 at the bottom of the support frame 1 and a second servo motor 10 at the top to rotate according to the specified rotating speed, selecting the outer cylinder 5 with the corresponding size to enable the width of the annular gap 6 to meet the requirement required by the experiment, adjusting an adjusting pin 21 at the bottom of the support frame 1 at the bottom to enable the whole device to be kept horizontal, injecting an experimental solution into the annular gap 6 from a liquid inlet 32 to achieve an ideal observation height, removing bubbles in the annular gap 6 to ensure that a brake caliper 17 releases a brake disc 22, then, the first servo motor 20 is started, the first servo motor 20 rotates and the first shaft coupling 19 drives the first rotating shaft 24 to rotate, the first rotating shaft 24 is in interference connection with the first shaft sleeve 26 and the bearing seat 18 respectively, coaxiality of the first rotating shaft 24 is guaranteed, and shaking is reduced. The first rotating shaft 24 drives the flange 29 to rotate, so that the lower base 4 and the outer cylinder 5 rotate around the axial center, meanwhile, the second servo motor 10 rotates, the second rotating shaft 25 is driven to rotate by the second coupler 11, the second rotating shaft 25 and the deep groove ball bearing 13 in the second shaft sleeve 12 form interference connection, the lower end of the second rotating shaft 25 is fixed on the inner surface of the deep groove ball bearing 13 embedded in the lower base 4, the coaxiality of the second rotating shaft is ensured, the ball 28 provides a fulcrum for the second rotating shaft 25 to prevent the second rotating shaft 25 from falling down, the second rotating shaft 25 drives the inner cylinder 7 to rotate by the key 31, the inner cylinder 7 is fixed by the second rotating shaft 25 and the second locking ring 30, and the inner cylinder 7 is prevented from moving in the rotating process; and after the rotation speed reaches the specified requirement, observing the flow state condition in the annular gap under the condition of determining the Reynolds number and rotating the double cylinders, acquiring data, opening the butterfly bolt 15 to discharge the experimental solution after the experiment is finished and the inner cylinder 7 and the outer cylinder 5 are static, cleaning the experimental device, and waiting for the next experiment.

Example 2:

firstly, determining the rotating speed and the rotating direction of an inner cylinder 7 in the experiment, adjusting corresponding parameters of a controller, enabling a driver to drive a second servo motor 10 at the top of a support frame 1 to rotate according to the specified rotating speed, selecting an outer cylinder 5 with a corresponding size, loosening a bolt 14, dismounting a related part and installing a new outer cylinder 5, screwing the bolt 14 to prevent the device from leaking, enabling the width of an annular gap 6 to meet the requirement required by the experiment, adjusting an adjusting pin 21 at the bottom of the support frame 1 to enable the whole device to be kept horizontal, injecting an experiment solution into the annular gap from a liquid inlet 32 to reach an ideal observation height, removing bubbles in the annular gap 6, and ensuring that a brake caliper 17 fixes a brake disc 22 to enable the outer cylinder 5 to be still; starting a second servo motor 10, wherein the second servo motor 10 drives a second rotating shaft 25 to rotate through a second coupler 11, the second rotating shaft 25 is in interference connection with a deep groove ball bearing 13 in a second shaft sleeve 12, the lower end of the second rotating shaft 25 is fixed on the inner surface of the deep groove ball bearing 13 embedded in the lower base 4, the coaxiality of the second rotating shaft is ensured, a ball 28 provides a fulcrum for the second rotating shaft 25 to prevent the second rotating shaft 25 from dropping, the second rotating shaft 25 drives an inner cylinder 7 to rotate through a key 31, the inner cylinder 7 is fixed through the second rotating shaft 25 and a second locking ring 30, and the inner cylinder 7 is prevented from moving in the rotating process; when the rotating speed reaches the specified requirement, the determined Reynolds number can be observed, the outer barrel 5 is fixed, the flow state condition in the annular gap under the rotating condition of the inner barrel 7 can be acquired, after the experiment is finished, the butterfly bolt 15 is opened to discharge the experimental solution when the inner barrel 7 is static, the experimental device is cleaned, and the next experiment is waited.

Claims (9)

1. A Theilercatt flow state experimental device is characterized by comprising an outer barrel, an upper end cover and a lower base, wherein the upper end cover and the lower base are respectively arranged at the upper end and the lower end of the outer barrel to form a fluid flow cavity; an inner cylinder is arranged in the fluid flow cavity, an annular gap for fluid flow is formed between the inner cylinder and the outer cylinder, a second rotating shaft is arranged in the inner cylinder, the lower end of the second rotating shaft is rotatably connected with the lower base, and the upper end of the second rotating shaft penetrates through the upper end cover, then penetrates through a third fixing plate and then is connected with a second servo motor through a second coupler;

the upper end cover is provided with a liquid inlet for guiding fluid into an annular gap between the outer barrel and the inner barrel, the lower base is provided with a liquid drainage channel for discharging the fluid, and the external port of the liquid drainage channel is provided with a detachable bolt for blocking the fluid.

2. The taylorcatt flow regime experimental device of claim 1, wherein the first rotating shaft is rotatably connected to the first fixing plate and the second fixing plate; a first bearing sleeve is arranged between the first rotating shaft and the first fixing plate, tapered roller bearings are embedded at the upper end and the lower end of the first bearing sleeve, and the first rotating shaft is rotatably connected with the first fixing plate through the tapered roller bearings; a bearing seat is arranged between the first rotating shaft and the second fixing plate, a ball bearing is embedded in the bearing seat, and the first rotating shaft and the second fixing plate are rotatably connected through the ball bearing.

3. The Taylorcatt flow state experimental device according to claim 1, wherein the locking mechanism is arranged on the first rotating shaft above the connection part of the first rotating shaft and the second fixing plate, and is used for keeping the outer cylinder in a static state when the inner cylinder rotates independently, so as to ensure that the outer cylinder does not rotate and deviate.

4. The Taylor storehouse special flow state experimental apparatus as claimed in claim 1, wherein the lower end of the second rotating shaft is designed to be stepped, the lower base is provided with a stepped groove matched with the second rotating shaft, deep groove ball bearings are embedded in the steps of the groove, the bottommost plane of the groove is a semi-circular arc surface, balls are arranged on the semi-circular arc surface, and the second rotating shaft is rotatably connected with the lower base through the deep groove ball bearings and the balls.

5. The Taylor Kute flow state experimental device as claimed in claim 1, wherein the second rotating shaft is rotatably connected with a third fixing plate, a second bearing sleeve is arranged between the second rotating shaft and the third fixing plate, deep groove ball bearings are embedded at the upper end and the lower end of the second bearing sleeve, and the second rotating shaft is rotatably connected with the third fixing plate through the deep groove ball bearings.

6. The Taylorgutt flow state experimental device of claim 1, wherein the top of the inner cylinder is connected with the second rotating shaft through a key to form a key, and a locking ring is arranged above the key part for mounting the second rotating shaft, so as to reduce the shaking and keep the inner cylinder and the second rotating shaft from moving relatively.

7. The taylorcatt flow regime experimental device of claim 1, wherein the first, second and third fixing plates are parallel to each other and fixed to the support frame respectively; the first servo motor and the second servo motor are respectively arranged on the bottom supporting plate and the top supporting plate of the supporting frame through motor seats.

8. The Taylorcatt flow state experimental device according to claim 1, wherein the drainage channels are L-shaped, 3 drainage channels are uniformly arranged on the lower base, and the inner wall of the outer port is provided with threads to be engaged with the detachable butterfly bolt.

9. The Taylorgutt flow state experimental device of claim 1, wherein the annular space between the outer cylinder and the inner cylinder is 2-15mm, a sealing gasket is arranged between the outer cylinder and the lower base and is pressed tightly by a bolt, and the outer cylinder is made of transparent material, so that the flowing condition of fluid can be observed conveniently during experiment.

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