CN113509865A

CN113509865A - A agitating unit for detecting mineral material performance

Info

Publication number: CN113509865A
Application number: CN202110684378.8A
Authority: CN
Inventors: 李洲; 张露
Original assignee: Central South University
Current assignee: Central South University
Priority date: 2021-06-21
Filing date: 2021-06-21
Publication date: 2021-10-19
Also published as: WO2022267406A1; ZA202200659B

Abstract

The invention discloses a stirring device for detecting mineral material performance, which comprises a material stirring barrel, wherein an upper cover is arranged on the material stirring barrel, a rotating mechanism is arranged on the upper cover, an output end of the rotating mechanism is provided with a rotating shaft component deviating from the axis of the rotating mechanism, a self-rotating structure is arranged between the rotating shaft component and the upper cover, the outer wall of the rotating shaft circumference of the rotating shaft component is provided with a plurality of rotating stirring blade components, 1, the angle of a stirring blade is freely adjusted according to the stirring requirement and the mineral material performance detection requirement, the influence parameter of the angle on the mineral material abrasion can be calculated according to the inclination angle of the stirring blade, the pressure of a motor is reduced, the service life is ensured, the revolution and the self-rotation of the stirring blade are realized by one motor, the manufacturing cost is saved, the stirring uniformity can be improved, and the stirring strength is ensured, 3. the synchronous driving structure can realize internal and external conduction in the revolution and rotation processes by being provided with a reasonable conductive structure.

Description

A agitating unit for detecting mineral material performance

Technical Field

The invention relates to a mineral material detection device, in particular to a stirring device for detecting the performance of a mineral material.

Background

After mining, a series of performance tests need to be carried out on the mineral materials, such as the wear resistance, hardness, density and other parameters of the mineral materials are tested, in order to improve the detection efficiency, a stirring device is generally adopted to continuously stir the mineral materials, and the wear resistance, hardness and density of the mineral materials are detected after stirring, but in such a stirring mode, because the stirring blades are vertically arranged, the stirring process is wider in the area of the attack of the mineral materials, and the stirring surface is perpendicular to the rotating direction, so that the motor is rapidly lost, the service life is short, and therefore the stirring test device which can synchronously adjust the angles of the stirring blades according to the test requirements, can realize revolution and autorotation of the stirring blades and also has a reasonable conduction control structure needs to be provided.

Accordingly, further improvement is required in the existing mineral material detection apparatus.

Disclosure of Invention

The invention aims to provide a stirring device for detecting the performance of mineral materials, which can synchronously adjust the angles of a plurality of stirring blades according to the test requirements, can realize revolution and rotation of the stirring blades, and simultaneously has a reasonable conduction control structure.

In order to achieve the purpose, the invention adopts the following scheme:

the utility model provides an agitating unit for detecting mineral material performance, includes the material agitator, be provided with the upper cover on the material agitator, on cover and be provided with rotary mechanism, rotary mechanism's output is provided with the skew rotary mechanism axle center is provided with the rotation axle subassembly, the rotation axle subassembly with be provided with the rotation structure between the upper cover, the rotation axis circumference outer wall of rotation axle subassembly is provided with a plurality of rotatory stirring leaf subassemblies, be provided with on the rotation axle subassembly and be used for synchronous drive a plurality of the rotatory same angle's of rotatory stirring leaf subassembly synchronous drive mechanism, rotatory stirring leaf subassembly is connected with synchronous drive mechanism, the rotation axle subassembly with be provided with between the upper cover and be used for doing the conductive component structure of synchronous drive mechanism power supply.

Further, rotary mechanism including set up in the motor cabinet of upper cover lower surface, install the rotating electrical machines in the motor cabinet.

Further, the rotation shaft assembly comprises a cross rod arranged at the output end of the rotating motor, a vertical rotation shaft seat is arranged at the outer end of the cross rod, and a rotation shaft is installed in the vertical rotation shaft seat.

Furthermore, the rotation structure comprises a rotation gear arranged on the outer wall of the circumference of the rotation shaft, a fixed gear which is tangent to and meshed with the rotation gear is arranged around the edge of the upper cover at the center of the rotation mechanism, and the fixed gear and the rotation gear are in meshing transmission.

Further, rotatory stirring leaf subassembly is including centering on a plurality of horizontal shaft holes of the equipartition of axis of rotation circumference outer wall, install horizontal pivot in the horizontal shaft hole, horizontal pivot outer end is provided with the stirring leaf, horizontal pivot with be provided with between the horizontal shaft hole and be used for the restriction horizontal pivot axial displacement's stop gear.

Further, the stirring leaf is including setting up the stirring leaf link of horizontal pivot outer end, the stack is installed detachable corrosion-resistant stirring piece and low carbon steel stirring piece on the stirring leaf link.

Further, the synchronous driving mechanism comprises a cavity arranged in the self-rotating shaft, a vertical rotating shaft mounting seat is arranged in the cavity, a vertical rotating shaft is installed in the vertical rotating shaft mounting seat, a turbine is arranged at the upper end of the vertical rotating shaft, a servo motor is arranged on the vertical rotating shaft mounting seat, a transmission lead screw is arranged at the output end of the servo motor and is in meshed transmission with the turbine, a first bevel gear is arranged at the lower end of the vertical rotating shaft, a second bevel gear is arranged at the inner end of the horizontal rotating shaft, and the second bevel gear is in meshed transmission with the first bevel gear.

Further, the conducting component structure including set up in the inside electrically conductive montant of cavity, electrically conductive montant with the servo motor electricity is connected, electrically conductive montant upper end extends to the rotation gear top is provided with first conducting ring, first conducting ring with be provided with fixed connecting rod between the horizontal pole, the fixed gear top edge is provided with the second conducting ring, first conducting ring is close to second conducting ring one side is provided with electrically conductive horizontal pole, electrically conductive horizontal pole outer end be provided with paste tightly in the electrically conductive arc piece of second conducting ring inner wall.

Furthermore, the first conducting ring and the rotation gear are concentrically arranged, and the circle center of the arc line of the conducting arc-shaped block and the circle center of the second conducting ring are concentrically arranged.

Furthermore, a signal receiver is arranged on the upper cover and is in communication connection with a control module, the control module is in communication connection with the servo motor, and the second conducting ring is electrically connected with a storage battery or a power supply.

In summary, compared with the prior art, the invention has the beneficial effects that:

the invention solves the defects existing in the existing mineral material stirring detection device, and has the advantages that 1, the angle of the stirring blade can be freely adjusted according to the stirring requirement and the mineral material performance detection requirement, the influence parameter of the angle on the mineral material abrasion can be calculated according to the inclination angle of the stirring blade, the pressure of the motor is reduced, the service life is ensured, the revolution and the rotation of the stirring blade are realized by one motor, the manufacturing cost is saved, the stirring uniformity can be improved, the stirring strength is ensured, and 3, the invention is provided with a reasonable conductive structure, so that the synchronous driving structure can realize the internal and external conduction in the revolution and rotation processes, the normal operation of the synchronous driving mechanism is ensured, and the invention has breakthrough progress in the mineral material performance detection field, is greatly convenient for the research and development of technical personnel, has simple structure and is convenient to use.

Drawings

FIG. 1 is a perspective view of the present invention;

FIG. 2 is a front view of the present invention;

FIG. 3 is a cross-sectional view taken along line A-A of FIG. 2;

FIG. 4 is a cross-sectional view taken along line C-C of FIG. 3;

FIG. 5 is a cross-sectional view taken along line B-B of FIG. 3;

FIG. 6 is an enlarged view of a portion of FIG. 5 at E;

FIG. 7 is an enlarged view of a portion of FIG. 3 at D;

FIG. 8 is one of the schematic internal components of the present invention;

FIG. 9 is a second schematic diagram of the internal components of the present invention;

FIG. 10 is a third schematic view of the internal components of the present invention;

FIG. 11 is a fourth schematic view of the internal components of the present invention.

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 FIGS. 1-11, the present invention provides

A stirring device for detecting the performance of mineral materials comprises a material stirring barrel 1, an upper cover 2 is arranged on the material stirring barrel 1, the upper cover 2 is provided with a rotating mechanism 3, the output end of the rotating mechanism 3 is provided with a self-rotating shaft component 4 deviating from the axis of the rotating mechanism 3, a rotation structure 5 is arranged between the rotation shaft assembly 4 and the upper cover 2, a plurality of rotary stirring blade assemblies 6 are arranged on the outer wall of the circumference of the rotation shaft assembly 4, the rotation shaft assembly 4 is provided with a synchronous driving mechanism 7 for synchronously driving a plurality of rotary stirring blade assemblies 6 to rotate by the same angle, the rotary stirring blade assembly 6 is connected with a synchronous driving mechanism 7, and a conductive assembly structure 8 for supplying power to the synchronous driving mechanism 7 is arranged between the rotating shaft assembly 4 and the upper cover 2;

the working principle is as follows: pouring mineral materials into a material stirring barrel 1, starting a rotating mechanism 3, wherein the rotating mechanism 3 drives a rotating shaft assembly 4 to revolve around the axis of the rotating mechanism 3, and in the rotating process, a rotating shaft of the rotating shaft assembly 4 rotates through a rotating structure 5, and a rotating stirring blade assembly 6 below the rotating shaft assembly realizes revolution and rotation to stir the mineral materials;

adjusting the rotating stirring blade assembly 6 according to the detected requirement;

researching the abrasion degree of the inclined angle of the rotary stirring blade assembly 6 to the mineral material within a specified time; the synchronous driving mechanism 7 drives the rotary stirring blade assemblies 6 to rotate and incline by a specified angle, stirring is started after the inclination, the rotary stirring blade assemblies 6 stir the mineral materials, and after the stirring is finished, the performance, the abrasion degree and the like of the mineral materials are detected;

meanwhile, a conductive assembly structure 8 is arranged, and the conductive assembly structure 8 is used for continuously supplying power to enable the synchronous driving mechanism 7 to be in a revolution or rotation state, so that the inclination angle of the rotary stirring blade assembly 6 can be conveniently adjusted in real time.

The rotating mechanism 3 comprises a motor base 301 arranged on the lower surface of the upper cover 2, and a rotating motor 302 is arranged in the motor base 301.

The automatic rotation shaft assembly 4 comprises a cross rod 401 arranged at the output end of the rotating motor 302, wherein a vertical rotation shaft seat 402 is arranged at the outer end of the cross rod 401, and an automatic rotation shaft 403 is arranged in the vertical rotation shaft seat 402.

The rotation structure 5 of the present invention includes a rotation gear 501 disposed on the outer circumferential wall of the rotation shaft 403, a fixed gear 502 tangent to and meshed with the rotation gear 501 is disposed around the edge of the upper cover 2 at the center of the rotation mechanism 3, and the fixed gear 502 and the rotation gear 501 are in meshing transmission.

The rotary stirring blade assembly 6 comprises a plurality of transverse shaft holes 601 uniformly distributed around the circumferential outer wall of the rotation shaft 403, a transverse rotation shaft 602 is installed in each transverse shaft hole 601, a stirring blade 603 is arranged at the outer end of each transverse rotation shaft 602, and a limiting mechanism 604 for limiting the transverse rotation shaft 602 to axially move is arranged between each transverse rotation shaft 602 and each transverse shaft hole 601.

The stirring blade 603 comprises a stirring blade connecting frame 6031 arranged at the outer end of the transverse rotating shaft 602, and a detachable corrosion-resistant stirring blade 6032 and a low-carbon steel stirring blade 6033 are superposed on the stirring blade connecting frame 6031;

the corrosion-resistant stirring sheet 6032 is made of 2205 or Mn8 material;

the synchronous driving mechanism 7 comprises a cavity 701 arranged in the rotating shaft 403, a vertical rotating shaft mounting seat 702 is arranged in the cavity 701, a vertical rotating shaft 703 is arranged in the vertical rotating shaft mounting seat 702, a turbine 704 is arranged at the upper end of the vertical rotating shaft 703, a servo motor 705 is arranged on the vertical rotating shaft mounting seat 702, a transmission screw rod 706 is arranged at the output end of the servo motor 705, the transmission screw rod 706 is in meshing transmission with the turbine 704, a first bevel gear 707 is arranged at the lower end of the vertical rotating shaft 703, a second bevel gear 708 is arranged at the inner end of the transverse rotating shaft 602, and the second bevel gear 708 is in meshing transmission with the first bevel gear 707;

the servo motor 705 rotates a designated angle after a command is input, and drives the transmission screw rod 706 to be meshed with the turbine 704, at this time, the turbine 704 drives the vertical rotating shaft 703 to rotate, the lower end of the vertical rotating shaft 703 drives the first bevel gear 707 to rotate, the first bevel gear 707 synchronously drives the second bevel gears 708 to rotate, and the plurality of transverse rotating shafts 602 synchronously rotate at the same angle.

The conducting component structure 8 of the present invention includes a conducting vertical rod 801 disposed inside the cavity 701, the conducting vertical rod 801 is electrically connected to the servo motor 705, a first conducting ring 802 is disposed at an upper end of the conducting vertical rod 801 extending above the rotation gear 501, a fixed connecting rod 803 is disposed between the first conducting ring 802 and the cross rod 401, a second conducting ring 804 is disposed at an upper edge of the fixed gear 502, a conducting cross rod 805 is disposed at a side of the first conducting ring 802 close to the second conducting ring 804, and a conducting arc-shaped block 806 tightly attached to an inner wall of the second conducting ring 804 is disposed at an outer end of the conducting cross rod 805.

The first conducting ring 802 and the rotation gear 501 are concentrically arranged, and the circle center of the arc of the conducting arc block 806 is concentrically arranged with the circle center of the second conducting ring 804.

The upper cover 2 is provided with a signal receiver 100, the signal receiver 100 is connected to a control module 200 in a communication manner, the control module 200 is connected to the servo motor 705 in a communication manner, and the second conductive ring 804 is electrically connected with a storage battery or a power supply.

While there have been shown and described the fundamental principles and principal features of the invention and advantages thereof, it will be understood by those skilled in the art that the invention is not limited by the embodiments described above, which are given by way of illustration of the principles of the invention, but is susceptible to various changes and modifications without departing from the spirit and scope of the invention as defined by the appended claims. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides an agitating unit for detecting mineral material performance, includes material agitator (1), be provided with upper cover (2) on material agitator (1), its characterized in that: be provided with rotary mechanism (3) on upper cover (2), the output of rotary mechanism (3) is provided with the skew rotary mechanism (3) axle center is provided with rotation shaft subassembly (4), rotation shaft subassembly (4) with be provided with rotation structure (5) between upper cover (2), the rotation axis circumference outer wall of rotation shaft subassembly (4) is provided with a plurality of rotatory stirring leaf subassemblies (6), be provided with on rotation shaft subassembly (4) and be used for synchronous drive a plurality of synchronous drive mechanism (7) of rotatory stirring leaf subassembly (6) rotatory same angle, rotatory stirring leaf subassembly (6) and synchronous drive mechanism (7) are connected, rotation shaft subassembly (4) with be provided with between upper cover (2) and be used for doing conductive component structure (8) of synchronous drive mechanism (7) power supply.

2. A mixer apparatus for testing the properties of mineral materials according to claim 1, wherein: the rotating mechanism (3) comprises a motor base (301) arranged on the lower surface of the upper cover (2), and a rotating motor (302) is installed in the motor base (301).

3. A mixer apparatus for testing the properties of mineral materials according to claim 2, wherein: the automatic rotation shaft assembly (4) comprises a cross rod (401) arranged at the output end of the rotating motor (302), a vertical rotation shaft seat (402) is arranged at the outer end of the cross rod (401), and an automatic rotation shaft (403) is installed in the vertical rotation shaft seat (402).

4. A mixer apparatus for testing the properties of mineral materials according to claim 3, wherein: the rotation structure (5) comprises a rotation gear (501) arranged on the outer wall of the circumference of the rotation shaft (403), a fixed gear (502) tangent and meshed with the rotation gear (501) is arranged around the edge of the upper cover (2) at the center of the rotation mechanism (3), and the fixed gear (502) and the rotation gear (501) are in meshing transmission.

5. A blending assembly according to claim 4, wherein: rotatory stirring leaf subassembly (6) is including centering on a plurality of horizontal shaft hole (601) of axis of rotation (403) circumference outer wall equipartition, install horizontal pivot (602) in horizontal shaft hole (601), horizontal pivot (602) outer end is provided with stirring leaf (603), horizontal pivot (602) with be provided with between horizontal shaft hole (601) and be used for the restriction horizontal pivot (602) axial displacement's stop gear (604).

6. A blending assembly according to claim 5, wherein: stirring leaf (603) are in including setting up stirring leaf link (6031) of horizontal rotating shaft (602) outer end, the stack is installed detachable corrosion-resistant stirring piece (6032) and mild steel stirring piece (6033) on stirring leaf link (6031).

7. A blending assembly according to any of claims 5 or 6, wherein: the synchronous driving mechanism (7) comprises a cavity (701) arranged inside the rotating shaft (403), a vertical rotating shaft mounting seat (702) is arranged in the cavity (701), a vertical rotating shaft (703) is installed in the vertical rotating shaft mounting seat (702), a turbine (704) is arranged at the upper end of the vertical rotating shaft (703), a servo motor (705) is arranged on the vertical rotating shaft mounting seat (702), a transmission lead screw (706) is arranged at the output end of the servo motor (705), the transmission lead screw (706) is in meshing transmission with the turbine (704), a first bevel gear (707) is arranged at the lower end of the vertical rotating shaft (703), a second bevel gear (708) is arranged at the inner end of the transverse rotating shaft (602), and the second bevel gear (708) is in meshing transmission with the first bevel gear (707).

8. A blending assembly according to claim 7, wherein: conducting component structure (8) including set up in inside electrically conductive montant (801) of cavity (701), electrically conductive montant (801) with servo motor (705) electricity is connected, electrically conductive montant (801) upper end extends to rotation gear (501) top is provided with first conducting ring (802), first conducting ring (802) with be provided with fixed connecting rod (803) between horizontal pole (401), fixed gear (502) top edge is provided with second conducting ring (804), first conducting ring (802) are close to second conducting ring (804) one side is provided with electrically conductive horizontal pole (805), electrically conductive horizontal pole (805) outer end be provided with paste tightly in electrically conductive arc piece (806) of second conducting ring (804) inner wall.

9. The stirring device for detecting the performance of the mineral material according to claim 8, wherein: the first conducting ring (802) and the rotation gear (501) are concentrically arranged, and the circle center of an arc line of the conducting arc-shaped block (806) and the circle center of the second conducting ring (804) are concentrically arranged.

10. The stirring device for detecting the performance of the mineral material according to claim 8, wherein: the upper cover (2) is provided with a signal receiver (100), the signal receiver (100) is in communication connection with a control module (200), the control module (200) is in communication connection with the servo motor (705), and the second conductive ring (804) is electrically connected with a storage battery or a power supply.