CN218486066U - Efficient Raymond pendulum grinding and crushing device for comprehensive utilization of mineral resources - Google Patents

Abstract

The utility model discloses a high-efficient leimeng pendulum-type mill of ore resources integrated utilization is smashed relates to ore crushing technical field, and inconvenient shake the filtration to the fine powder sieve for on the fine powder sieve, it has a lot of powdered ore to adsorb, produces the jam to the fine powder sieve, the supporting shoe is installed to the bottom of bottom plate, the cavity is installed on the top of bottom plate, first pulley structure is installed to the bottom of pivot, the initiative motor is installed to one side on bottom plate top, the output of initiative motor is connected with the one end of pivot, the inboard top of cavity is provided with filter mechanism, the utility model discloses a be provided with filter mechanism on the inside top of cavity, utilize mutually supporting of filter mechanism, can shake the filtration to the fine powder sieve for the powdered ore that does not pass through the fine powder sieve falls to the bottom of cavity again and grinds, is difficult for adsorbing on the fine powder sieve, causes the jam to the fine powder sieve, has improved the practicality of the device when using.

Description

Efficient Raymond pendulum mill grinding for comprehensive utilization of ore resources

Technical Field

The utility model relates to a technical field is smashed to the ore, specifically is a high-efficient thunder covers pendulum-type mill that ore resources comprehensive utilization is smashed.

Background

Along with the development of economy, the technological level is continuously improved, the utilization of mineral resources in China is very high in efficiency, and a Raymond mill is also called a Raymond mill powder machine, is common milling equipment, is mainly used for high-fineness milling processing of 280 kinds of materials in the industries such as non-flammable and non-explosive mineral products, chemical engineering, buildings and the like of common ores, and needs to use a novel Raymond mill in order to enable the comprehensive utilization of the mineral resources to be more high in efficiency;

the prior Raymond mill has the following problems in use:

1. when the existing Raymond mill is used, because the fine powder sieve is inconvenient to shake and filter, a great amount of mineral powder is adsorbed on the fine powder sieve, the fine powder sieve is blocked, and the practicability of the device in use is reduced;

2. when using, the existing Raymond mill needs to be crushed by a jaw crusher, so that large materials are crushed automatically and inconveniently, and the working efficiency of the device is greatly reduced when the device is used.

Therefore, the efficient Raymond pendulum type grinding and crushing method for comprehensive utilization of ore resources is provided for solving the problems.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a high-efficient thunder covers pendulum-type mill of ore resources comprehensive utilization is smashed to solve the problem that proposes in the above-mentioned background art.

In order to achieve the above object, the utility model provides a following technical scheme: the utility model provides a high-efficient leimeng pendulum-type mill of ore resources integrated utilization is smashed, includes the bottom plate, the supporting shoe is installed to the bottom of bottom plate, the cavity is installed on the top of bottom plate, the top of cavity is provided with the discharge gate, the fan is installed to one side on bottom plate top, the fan is linked together with one side of cavity, broken chamber is installed to one side of cavity, the material loading mouth is installed on the top in broken chamber, the inside in broken chamber is provided with broken mechanism, the feed chamber is installed to the bottom in broken chamber, the one end in feed chamber is linked together with one side of cavity, the pivot is installed to the inside bottom of cavity, the grinding roller is installed in the outside of pivot, the inboard bottom of cavity is provided with the grinding ring, the scraper is installed to the below in the pivot outside, first belt pulley structure is installed to the bottom of pivot, the initiative motor is installed to one side on bottom plate top, the output of initiative motor is connected with the one end of pivot, the inboard top of cavity is provided with filtering mechanism.

As a preferred technical scheme of the utility model, the grinding roller is provided with a plurality ofly, and is a plurality of the grinding roller is the annular in the inside of cavity and distributes.

As a preferred technical scheme of the utility model, broken mechanism includes first servo motor, driving gear, driven gear, driving roller and broken tooth, first servo motor installs in the one end in broken chamber, the one end in broken chamber is installed to the driving gear, first servo motor's output is connected with the one end of driving gear, one side meshing of driving gear has driven gear, the driving gear is connected with the driving roller with driven gear's one end, the lateral wall of driving roller is provided with broken tooth.

As an optimal technical scheme of the utility model, broken tooth is provided with a plurality ofly, and is a plurality of broken tooth is equidistant distribution at the lateral wall of driving roller.

As an optimized technical scheme of the utility model, the driving roller is provided with two, two be symmetric distribution about the axis in broken chamber between the driving roller.

As the utility model discloses an optimal technical scheme, filtering mechanism is including screening subassembly and power component, the screening subassembly includes fine powder sieve and expanding spring, the fine powder sieve is installed in the top of the inside of cavity, expanding spring sets up in the inside both sides of cavity, the fine powder sieve sets up in expanding spring's inboard.

As a preferred technical scheme of the utility model, power component includes second servo motor, second belt pulley structure, first bevel gear, second bevel gear, bent axle, movable sleeve and connecting rod, the bent axle is installed on the inside top of cavity, second bevel gear is installed to one side of bent axle, one side meshing of second bevel gear has first bevel gear, second belt pulley structure installs in the top of cavity, the bottom of second belt pulley structure is connected with the one end of first bevel gear, second servo motor is installed on the top of second belt pulley structure, the intermediate position department cover in the bent axle outside is equipped with the movable sleeve, the connecting rod is installed to the bottom of movable sleeve, the bottom of connecting rod is connected with the top of fine powder sieve.

As an optimal technical scheme of the utility model, the bent axle is provided with two sets ofly, the fine powder sieve drives the connecting rod through the bent axle and is concertina movement.

Compared with the prior art, the beneficial effects of the utility model reside in that:

1. the utility model discloses a top in the cavity is provided with filtering mechanism, utilizes the mutual cooperation of fine powder sieve, expanding spring, second servo motor, second belt pulley structure, first conical gear, second conical gear, bent axle, movable sleeve and the connecting rod of filtering mechanism, can shake the fine powder sieve and filter, makes the powdered ore that does not pass through the fine powder sieve fall to the bottom of cavity again and grinds, is difficult for adsorbing on the fine powder sieve, causes the jam to the fine powder sieve, has improved the practicality of the device when using;

2. the utility model discloses a be provided with broken mechanism in the inside in broken chamber, utilize mutually supporting of broken mechanism's a servo motor, driving gear, driven gear, driving roller and broken tooth, can carry out the breakage to the bold ore for the device is more high-efficient when using, thereby has improved the work efficiency of the device when using greatly.

Drawings

FIG. 1 is a schematic view of the overall structure of the present invention,

FIG. 2 is a schematic view of the front cross-sectional structure of the filtering mechanism of the present invention,

FIG. 3 is a schematic top sectional view of the crushing mechanism of the present invention,

fig. 4 is a schematic diagram of a partially enlarged structure at a position in fig. 2 according to the present invention.

In the figure: 1. a base plate; 2. a support block; 3. a cavity; 4. a discharge port; 5. a rotating shaft; 6. grinding the roller; 7. grinding a ring; 8. a scraper; 9. a first pulley structure; 10. an active motor; 11. a fan; 12. a feeding port; 13. a crushing chamber; 14. a feeding cavity; 15. a first servo motor; 16. a driving gear; 17. a driven gear; 18. a driving roller; 19. crushing teeth; 20. fine powder screening; 21. a tension spring; 22. a second servo motor; 23. a second pulley structure; 24. a first bevel gear; 25. a second bevel gear; 26. a crankshaft; 27. a movable sleeve; 28. a connecting rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

The embodiment is as follows: as shown in figures 1-4, the utility model provides a high-efficiency Raymond pendulum grinding and crushing device for comprehensive utilization of mineral resources, which comprises a bottom plate 1, a supporting block 2 is arranged at the bottom end of the bottom plate 1, a cavity 3 is arranged at the top end of the bottom plate 1, a discharge hole 4 is arranged at the top end of the cavity 3, a fan 11 is arranged at one side of the top end of the bottom plate 1, the fan 11 is communicated with one side of the cavity 3, a crushing cavity 13 is arranged at one side of the cavity 3, a feeding hole 12 is arranged at the top end of the crushing cavity 13, a crushing mechanism is arranged in the crushing cavity 13, a feeding cavity 14 is arranged at the bottom end of the crushing cavity 13, one end of the feeding cavity 14 is communicated with one side of the cavity 3, a rotating shaft 5 is arranged at the bottom end of the interior of the cavity 3, a grinding roller 6 is arranged at the outer side of the rotating shaft 5, and a plurality of grinding rollers 6 are arranged, the grinding rollers 6 are distributed in the cavity 3 in an annular mode, the grinding ring 7 is arranged at the bottom end of the inner side of the cavity 3, a scraper 8 is installed below the outer side of the rotating shaft 5, a first belt pulley structure 9 is installed at the bottom end of the rotating shaft 5, an active motor 10 is installed on one side of the top end of the bottom plate 1, the output end of the active motor 10 is connected with one end of the rotating shaft 5, a filtering mechanism is arranged above the inner side of the cavity 3, when the grinding roller is used, ore falls into the bottom end of the inner side of the cavity 3 through the feeding cavity 14, the active motor 10 is started to drive the first belt pulley structure 9 to rotate, the rotating shaft 5 is driven to rotate, the grinding rollers 6 and the grinding ring 7 are matched with each other to grind the ore, the fan 11 is started to blow up the ground ore powder, and the ore powder is discharged from the discharge port 4 through the fine powder screen 20.

Further, broken mechanism includes first servo motor 15, driving gear 16, driven gear 17, driving roller 18 and broken tooth 19, first servo motor 15 is installed in the one end of broken chamber 13, driving gear 16 is installed in the one end of broken chamber 13, the output of first servo motor 15 is connected with driving gear 16's one end, driving gear 16's one side meshing has driven gear 17, driving gear 16 is connected with driving roller 18 with driven gear 17's one end, the lateral wall of driving roller 18 is provided with broken tooth 19, broken tooth 19 is provided with a plurality ofly, a plurality of broken teeth 19 are equidistant distribution at the lateral wall of driving roller 18, driving roller 18 is provided with two, be symmetric distribution about the axis of broken chamber 13 between two driving rollers 18, during the use, pour the material into the inside of broken chamber 13 from material loading mouth 12, then start first servo motor 15 and drive driving gear 16 and rotate, so drive driven gear 17 and rotate, and then drive two driving rollers 18 and rotate in opposite directions, utilize broken tooth 19 to carry out the breakage to the big piece ore, make the device more high-efficient when using, thereby greatly improving the work efficiency of the device when using.

Further, the filtering mechanism comprises a screening component and a power component, the screening component comprises a fine powder screen 20 and a telescopic spring 21, the fine powder screen 20 is installed above the inner part of the cavity 3, the telescopic spring 21 is arranged on two sides of the inner part of the cavity 3, the fine powder screen 20 is arranged on the inner side of the telescopic spring 21, the power component comprises a second servo motor 22, a second belt pulley structure 23, a first conical gear 24, a second conical gear 25, a crankshaft 26, a movable sleeve 27 and a connecting rod 28, the crankshaft 26 is installed on the top end of the inner part of the cavity 3, the second conical gear 25 is installed on one side of the crankshaft 26, the first conical gear 24 is meshed on one side of the second conical gear 25, the second belt pulley structure 23 is installed on the top end of the cavity 3, the bottom end of the second belt pulley structure 23 is connected with one end of the first conical gear 24, the second servo motor 22 is installed on the top end of the second belt pulley structure 23, the movable sleeve 27 is sleeved at the middle position of the outer side of the crankshaft 26, the connecting rod 28 is installed on the connecting rod 28, the connecting rod 28 is connected with the top end of the fine powder screen 20, the crankshaft 26, the two sets of the fine powder screen 20 are used for driving the connecting rod to move telescopically, the second servo motor 22 is started to drive the second belt pulley structure 23 to rotate, so as to drive the two first bevel gears 24 to rotate, the crankshaft 26 is driven to rotate by the transmission of the second bevel gear 25, and the movable sleeve 27 is driven to move up and down, the fine powder sieve 20 is driven to shake up and down under the coordination of the extension spring 21, so that the mineral powder which does not pass through the fine powder sieve 20 falls to the bottom end of the cavity 3 again for grinding and is not easy to be adsorbed on the fine powder sieve 20, the fine powder sieve 20 is blocked, so that the discharging of the device is more efficient, and the practicability of the device in use is improved.

The working principle is as follows: the staff pours the material into the inside of the crushing cavity 13 from the feeding hole 12, then starts the first servo motor 15 to drive the driving gear 16 to rotate, so as to drive the driven gear 17 to rotate, and further drives the two driving rollers 18 to rotate oppositely, the large ore is crushed by the crushing teeth 19, so that the device is more efficient when in use, thereby greatly improving the working efficiency of the device when in use, then the ore falls into the bottom inside the cavity 3 through the feeding cavity 14, the driving motor 10 is started to drive the first belt pulley structure 9 to rotate, so as to drive the rotating shaft 5 to rotate, the grinding roller 6 and the grinding ring 7 are matched with each other to grind the ore, the fan 11 is started to blow up the ground ore powder, the ore powder is discharged from the discharge hole 4 through the fine powder sieve 20, at the moment, the second servo motor 22 is started to drive the second belt pulley structure 23 to rotate, so as to drive the two first conical gears 24 to rotate, and further drive the crankshaft 26 to rotate through the transmission of the second conical gear 25, at the moment, the movable sleeve 27 is driven to drive the fine powder sieve 20 to move up and down, so that the fine powder sieve 20 is shaken up and the bottom of the device is not easy to be adsorbed on the fine powder falling, thereby improving the practicality, and the device is more effectively.

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

Claims (8)

1. The utility model provides a high-efficient leimeng pendulum-type grinds and smashes of ore resources integrated utilization, includes bottom plate (1), its characterized in that: the bottom end of the bottom plate (1) is provided with a supporting block (2), the top end of the bottom plate (1) is provided with a cavity (3), a discharge hole (4) is arranged at the top end of the cavity (3), a fan (11) is arranged at one side of the top end of the bottom plate (1), the fan (11) is communicated with one side of the cavity (3), one side of the cavity (3) is provided with a crushing cavity (13), a feeding port (12) is arranged at the top end of the crushing cavity (13), a crushing mechanism is arranged in the crushing cavity (13), a feeding cavity (14) is arranged at the bottom end of the crushing cavity (13), one end of the feeding cavity (14) is communicated with one side of the cavity body (3), a rotating shaft (5) is arranged at the bottom end inside the cavity (3), a grinding roller (6) is arranged on the outer side of the rotating shaft (5), a grinding ring (7) is arranged at the bottom end of the inner side of the cavity (3), a scraper (8) is arranged below the outer side of the rotating shaft (5), a first belt pulley structure (9) is arranged at the bottom end of the rotating shaft (5), one side of the top end of the bottom plate (1) is provided with an active motor (10), the output end of the driving motor (10) is connected with one end of the rotating shaft (5), and a filtering mechanism is arranged above the inner side of the cavity (3).

2. The high-efficiency Raymond pendulum grinding and crushing device for comprehensive utilization of mineral resources, according to claim 1, is characterized in that: the grinding rollers (6) are arranged in a plurality, and the grinding rollers (6) are annularly distributed in the cavity (3).

3. The high-efficiency Raymond pendulum grinding and crushing device for comprehensive utilization of mineral resources, according to claim 1, is characterized in that: broken mechanism includes first servo motor (15), driving gear (16), driven gear (17), driving roller (18) and broken tooth (19), the one end in broken chamber (13) is installed in first servo motor (15), the one end in broken chamber (13) is installed in driving gear (16), the output of first servo motor (15) is connected with the one end of driving gear (16), the one side meshing of driving gear (16) has driven gear (17), driving gear (16) and the one end of driven gear (17) are connected with driving roller (18), the lateral wall of driving roller (18) is provided with broken tooth (19).

4. The high-efficiency Raymond pendulum grinding and crushing device for comprehensive utilization of mineral resources, according to claim 3, is characterized in that: broken tooth (19) are provided with a plurality ofly, and it is a plurality of broken tooth (19) are equidistant distribution at the lateral wall of driving roller (18).

5. The efficient Raymond pendulum mill grinding method for comprehensive utilization of mine resources, according to claim 3, is characterized in that: the transmission rollers (18) are arranged in two numbers, and the transmission rollers (18) are symmetrically distributed around the central axis of the crushing cavity (13).

6. The efficient Raymond pendulum mill grinding method for comprehensive utilization of mine resources, according to claim 1, is characterized in that: the filtering mechanism comprises a screening assembly and a power assembly, the screening assembly comprises a fine powder screen (20) and an expansion spring (21), the fine powder screen (20) is installed above the inner part of the cavity (3), the expansion spring (21) is arranged on two sides of the inner part of the cavity (3), and the fine powder screen (20) is arranged on the inner side of the expansion spring (21).

7. The efficient Raymond pendulum mill grinding method for comprehensive utilization of mine resources, according to claim 6, is characterized in that: the power component comprises a second servo motor (22), a second belt pulley structure (23), a first bevel gear (24), a second bevel gear (25), a crankshaft (26), a movable sleeve (27) and a connecting rod (28), wherein the crankshaft (26) is installed at the top end inside the cavity (3), the second bevel gear (25) is installed at one side of the crankshaft (26), the first bevel gear (24) is meshed at one side of the second bevel gear (25), the second belt pulley structure (23) is installed at the top end of the cavity (3), the bottom end of the second belt pulley structure (23) is connected with one end of the first bevel gear (24), the second servo motor (22) is installed at the top end of the second belt pulley structure (23), the movable sleeve (27) is sleeved at the middle position outside the crankshaft (26), the connecting rod (28) is installed at the bottom end of the movable sleeve (27), and the bottom end of the connecting rod (28) is connected with the top end of the fine powder sieve (20).

8. The efficient Raymond pendulum mill grinding method for comprehensive utilization of mine resources, according to claim 7, is characterized in that: the two groups of crankshafts (26) are arranged, and the fine powder sieve (20) drives the connecting rod (28) to do telescopic motion through the crankshafts (26).

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