CN213078731U

CN213078731U - Cement processing equipment

Info

Publication number: CN213078731U
Application number: CN202020872606.5U
Authority: CN
Inventors: 董智宇
Original assignee: Shangrao Evergreen Commercial Concrete Co ltd
Current assignee: Shangrao Evergreen Commercial Concrete Co ltd
Priority date: 2020-05-22
Filing date: 2020-05-22
Publication date: 2021-04-30
Anticipated expiration: 2030-05-22

Abstract

The utility model relates to a cement processing equipment field, more specifically the cement processing equipment that says so, including one-level reducing mechanism, sieving mechanism, second grade reducing mechanism, hoisting device and power device, its characterized in that: the following fixedly connected with sieving mechanism of one-level reducing mechanism, sieving mechanism below fixedly connected with second grade reducing mechanism, hoisting device fixed connection is in second grade reducing mechanism's side, power device's one end and one-level reducing mechanism fixed connection, power device's other one end and second grade reducing mechanism fixed connection, can screen lime through the sieving mechanism, wherein great bold limestone will be sent to the one-level reducing mechanism through hoisting device and smash, less limestone will get into second grade reducing mechanism and smash, second grade reducing mechanism's functioning speed is faster than one-level reducing mechanism's slew velocity, can protect second grade reducing mechanism effectively through setting up the sieving mechanism and avoid its damage.

Description

Cement processing equipment

Technical Field

The utility model relates to a cement processing equipment field, more specifically the cement processing equipment that says so.

Background

For example, during the use of the conventional limestone crusher for cement production with publication number CN209631295U, due to the different sizes of limestone, it is difficult to crush the limestone to the required particle level at one time, and after the primary crushing, the addition effect of the secondary crushed lime is affected due to the existence of the larger block limestone.

Disclosure of Invention

The utility model aims at providing a cement processing equipment can effectively protect the second grade reducing mechanism and improve simultaneously and smash efficiency.

The purpose of the utility model is realized through the following technical scheme:

the utility model provides a cement processing equipment, includes one-level reducing mechanism, sieving mechanism, second grade reducing mechanism, hoisting device and power device, its characterized in that: the lower fixedly connected with sieving mechanism of one-level reducing mechanism, the fixedly connected with second grade reducing mechanism below the sieving mechanism, hoisting device fixed connection are in second grade reducing mechanism's side, power device's one end and one-level reducing mechanism fixed connection, power device's the other end and second grade reducing mechanism fixed connection.

As this technical scheme's further optimization, the utility model relates to a cement processing equipment, one-level reducing mechanism includes frame I, the gyro wheel is smashed to the one-level, gear I, drive gear I and bevel gear I, it smashes the gyro wheel to be provided with two one-levels in the frame I, the one end that the gyro wheel was smashed to every one-level is all rotated and is connected in frame I, the equal fixedly connected with gear I of gyro wheel is smashed to every one-level, rotate on the frame I and be connected with drive gear I, two gear I all with drive gear between the I meshing be connected, fixedly connected with bevel gear I on the drive gear I, bevel gear I is connected with the power device transmission, the below fixedly connected with sieving.

As this technical scheme's further optimization, the utility model relates to a cement processing equipment, sieving mechanism includes frame II, shale shaker, connecting rod, bevel gear II and bent axle, sliding connection has the shale shaker on frame II, be provided with the spring between shale shaker and the frame II, it is connected with the bent axle to rotate on the frame II, be connected through the connecting rod transmission between bent axle and the shale shaker, the one end fixedly connected with bevel gear II of bent axle, bevel gear II rotates with power device to be connected, frame II fixed connection is in the below of frame I, the below fixedly connected with second grade reducing mechanism of frame II.

As this technical scheme's further optimization, the utility model relates to a cement processing equipment, second grade reducing mechanism includes frame III, second grade crushing gyro wheel, gear II, bevel gear III and drive gear II, frame III fixed connection is in the below of frame II, be provided with two second grade crushing gyro wheels in the frame III, the equal fixedly connected with gear II of one end of every second grade crushing gyro wheel, it is connected with drive gear II to rotate in the frame III, two gears II all with drive gear between II meshing connection, fixedly connected with bevel gear III on drive gear II, bevel gear III is connected with the power device transmission.

As this technical scheme's further optimization, the utility model relates to a cement processing equipment, hoisting device includes frame IV, drive wheel, motor II, hopper and drive belt, and frame IV fixed connection is provided with two drive wheels in the frame III in the frame IV, and every drive wheel all rotates to be connected in the frame IV, and the one end fixed connection of one of them drive wheel is on the output shaft of motor II, and II fixed connections of motor are in the frame IV, and two drive wheels pass through drive belt transmission and connect, a plurality of hopper of fixedly connected with on the drive belt.

As this technical scheme's further optimization, the utility model relates to a cement processing equipment, power device includes motor I, axle and bevel gear IV, and I fixed connection of motor is in frame III, fixedly connected with axle on the output shaft of motor I, and the one end of axle is rotated and is connected in frame I, and the other one end fixed connection of axle is in frame III, and epaxial three bevel gear IV of fixedly connected with that sets up, and three bevel gear IV meshes in bevel gear I, bevel gear II and bevel gear III respectively and connects.

The utility model relates to a cement processing equipment's beneficial effect does:

the utility model relates to a cement processing device, which can effectively improve the efficiency of crushing limestone and protect a secondary crushing device; lime stone filters through the sieving mechanism behind the one-level reducing mechanism during the use, wherein bigger limestone will be screened out by the screening, transport the limestone that unsatisfied will go in the one-level reducing mechanism to smash through hoisting device, the limestone after the screening will get into the secondary crushing mechanism and smash, the secondary crushing mechanism can smash the limestone into lime powder, the functioning speed of secondary crushing mechanism's reducing mechanism is faster than the slew velocity of one-level reducing mechanism, can protect secondary crushing mechanism effectively through setting up the sieving mechanism and avoid its damage.

Drawings

The invention is described in further detail below with reference to the accompanying drawings and specific embodiments.

Fig. 1 is a schematic view of the overall structure of the present invention;

FIG. 2 is a schematic view of the overall structure of the primary crushing device of the present invention;

FIG. 3 is a schematic view of the overall structure of the screening device of the present invention;

FIG. 4 is a schematic view of the overall structure of the second stage crushing device of the present invention;

fig. 5 is a schematic view of the overall structure of the lifting device of the present invention;

fig. 6 is a schematic view of the overall structure of the power plant of the present invention.

In the figure: a primary crushing device 1; a rack I101; a primary crushing roller 102; a gear I103; a transmission gear I104; a bevel gear I105; a screening device 2; a frame II 201; a vibrating screen 202; a connecting rod 203; a bevel gear II 204; a crankshaft 205; a secondary crushing device 3; a frame III 301; secondary crushing rollers 302; a gear II 303; a bevel gear III 304; a transmission gear II 305; a lifting device 4; a frame IV 401; a drive wheel 402; a motor II 403; a hopper 404; a belt 405; a power plant 5; a motor I501; a shaft 502; and a bevel gear IV 503.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings.

The first embodiment is as follows:

the present embodiment is described below with reference to fig. 1 to 6, and a cement processing apparatus includes a primary crushing device 1, a screening device 2, a secondary crushing device 3, a lifting device 4, and a power device 5, and is characterized in that: the lower part of the primary crushing device 1 is fixedly connected with a screening device 2, the lower part of the screening device 2 is fixedly connected with a secondary crushing device 3, a lifting device 4 is fixedly connected to the side surface of the secondary crushing device 3, one end of a power device 5 is fixedly connected with the primary crushing device 1, and the other end of the power device 5 is fixedly connected with the secondary crushing device 3; lime stone filters lime through sieving mechanism 2 behind one-level reducing mechanism 1 during the use, wherein great lime stone will be screened out, convey unsatisfied lime stone that will go to one-level reducing mechanism 1 through hoisting device 4 and smash, the lime stone after the screening will get into second grade reducing mechanism 3 and smash, second grade reducing mechanism 3 can smash the lime stone into lime powder, second grade reducing mechanism 3's reducing mechanism's the functioning speed is faster than 1 reducing mechanism's of one-level reducing mechanism rotational speed, can protect second grade reducing mechanism 3 effectively through setting up sieving mechanism 2 and avoid its damage.

The second embodiment is as follows:

the embodiment is described below with reference to fig. 1 to 6, and the embodiment further describes the first embodiment, where the primary crushing device 1 includes a rack i 101, primary crushing rollers 102, a gear i 103, a transmission gear i 104, and a bevel gear i 105, two primary crushing rollers 102 are disposed on the rack i 101, one end of each primary crushing roller 102 is rotatably connected to the rack i 101, each primary crushing roller 102 is fixedly connected to the gear i 103, the rack i 101 is rotatably connected to the transmission gear i 104, the two gears i 103 are engaged with the transmission gear i 104, the transmission gear i 104 is fixedly connected to the bevel gear i 105, the bevel gear i 105 is in transmission connection with a power device 5, and a screening device 2 is fixedly connected below the rack i 101; the power of the power device 5 drives the transmission gear I104 to rotate through the bevel gear I105, and due to the fact that the transmission gear I104 and the two gears I103 are mutually kneaded and transmitted, the transmission gear I104 can drive the gears I103 to rotate, the gears I103 and the primary crushing rollers 102 are fixedly connected, the two primary crushing rollers 102 also rotate along with the gears I103, and limestone is crushed through the interaction of the two primary crushing rollers 102.

The third concrete implementation mode:

the following describes the present embodiment with reference to fig. 1 to 6, and the present embodiment further describes the first embodiment, where the screening device 2 includes a frame ii 201, a vibrating screen 202, a connecting rod 203, a bevel gear ii 204, and a crankshaft 205, the vibrating screen 202 is connected to the frame ii 201 in a sliding manner, a spring is disposed between the vibrating screen 202 and the frame ii 201, the frame ii 201 is connected to the crankshaft 205 in a rotating manner, the crankshaft 205 and the vibrating screen 202 are connected in a transmission manner through the connecting rod 203, one end of the crankshaft 205 is fixedly connected to the bevel gear ii 204, the bevel gear ii 204 is connected in a transmission manner to the power device 5, the frame ii 201 is fixedly connected to the lower portion of the frame i 101, and the lower portion of the frame ii 201 is fixedly; power of power device 5 passes through bevel gear II 204 and conveys power to bent axle 205, because of being connected through connecting rod 203 transmission between bent axle 205 and the shale shaker 202, bent axle 205 rotates and can drive shale shaker 202, because of shale shaker 202 sliding connection is on frame II 201, so shale shaker 202 can slide along with bent axle 205, because of being provided with the spring between shale shaker 202 and the frame II 201, shale shaker 202 receives the effect of bent axle 205 and spring to shake, select the limestone of great piece, and with the leading-in hoisting device 4 of the limestone of great piece, hoisting device 4 promotes the limestone of great piece to smash once more in primary crushing device 1, less limestone will enter into secondary crushing device 3 through shale shaker 202 and smash.

The fourth concrete implementation mode:

the second-stage crushing device 3 comprises a rack iii 301, second-stage crushing rollers 302, a gear ii 303, a bevel gear ii 304 and a transmission gear ii 305, wherein the rack iii 301 is fixedly connected below the rack ii 201, the rack iii 301 is provided with two second-stage crushing rollers 302, one end of each second-stage crushing roller 302 is fixedly connected with the gear ii 303, the rack iii 301 is rotatably connected with the transmission gear ii 305, the two gears ii 303 are respectively in meshing connection with the transmission gear ii 305, the transmission gear ii 305 is fixedly connected with the bevel gear ii 304, and the bevel gear ii 304 is rotatably connected with the power device 5; the power of the power device 5 drives the transmission gear II 305 to rotate through the bevel gear II 304, the transmission gear II 305 drives the gear II 303 to rotate due to mutual kneading transmission between the transmission gear II 305 and the two gears II 303, the two secondary grinding rollers 302 also rotate along with the transmission gear II 303 and the two secondary grinding rollers 302 due to the fixed connection between the gear II 303 and the two secondary grinding rollers 302, and small limestone blocks are smashed through the interaction of the two secondary grinding rollers 302.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 6, and the embodiment further describes the first embodiment, where the lifting device 4 includes a frame iv 401, driving wheels 402, a motor ii 403, a hopper 404, and a transmission belt 405, the frame iv 401 is fixedly connected to the frame iii 301, two driving wheels 402 are disposed on the frame iv 401, each driving wheel 402 is rotatably connected to the frame iv 401, one end of one driving wheel 402 is fixedly connected to an output shaft of the motor ii 403, the motor ii 403 is fixedly connected to the frame iv 401, the two driving wheels 402 are in transmission connection through the transmission belt 405, and the transmission belt 405 is fixedly connected to a plurality of hoppers 404; when the limestone pulverizer is used, the driving motor II 403 drives the driving wheels 402 to rotate, a transmission belt 405 is arranged between the two driving wheels 402, a hopper 404 is fixed on the transmission belt 405, when the driving wheels 402 drive the transmission belt 405 to rotate, the hopper 404 can also rotate along with the transmission belt, and limestone screened by the screening device 2 is conveyed into the primary crushing device 1 through the hopper 404 to be crushed again.

The fifth concrete implementation mode:

the embodiment is described below with reference to fig. 1 to 6, and the embodiment further describes the first embodiment, where the power device 5 includes a motor i 501, a shaft 502, and a bevel gear iv 503, the motor i 501 is fixedly connected to a rack iii 301, the shaft 502 is fixedly connected to an output shaft of the motor i 501, one end of the shaft 502 is rotatably connected to the rack i 101, the other end of the shaft 502 is fixedly connected to the rack iii 301, three bevel gears iv 503 are fixedly connected to the shaft 502, and the three bevel gears iv 503 are respectively engaged and connected to a bevel gear i 105, a bevel gear ii 204, and a bevel gear iii 304; when the bevel gear mechanism is used, a motor I501 is driven, the motor I501 drives a shaft 502 to rotate, the shaft 502 is fixedly connected with three bevel gears IV 503, and the three bevel gears IV 503 drive a bevel gear I105, a bevel gear II 204 and a bevel gear III 304 to rotate respectively.

The utility model discloses a cement processing equipment, its theory of operation is:

when the bevel gear mechanism is used, a driving motor I501 is driven, the motor I501 drives a shaft 502 to rotate, the shaft 502 is fixedly connected with three bevel gears IV 503, and the three bevel gears IV 503 respectively drive a bevel gear I105, a bevel gear II 204 and a bevel gear III 304 to rotate; limestone firstly passes through the primary crushing device 1, the power of the power device 5 passes through the bevel gear I105 to drive the transmission gear I104 to rotate, and the transmission gear I104 and the two gears I103 are mutually kneaded and transmitted, so that the transmission gear I104 can drive the gears I103 to rotate, the gears I103 and the primary crushing rollers 102 are fixedly connected, the two primary crushing rollers 102 also rotate along with the gears I103, and the limestone is crushed through the interaction of the two primary crushing rollers 102; the lime is screened by the screening device 2, the power of the power device 5 is transmitted to the crankshaft 205 through the bevel gear II 204, the crankshaft 205 is in transmission connection with the vibrating screen 202 through the connecting rod 203, the vibrating screen 202 is driven by the rotation of the crankshaft 205, and the vibrating screen 202 is in sliding connection with the rack II 201, so that the vibrating screen 202 can slide along with the crankshaft 205, a spring is arranged between the vibrating screen 202 and the rack II 201, the vibrating screen 202 is vibrated under the action of the crankshaft 205 and the spring to screen out larger limestone, and the larger limestone is guided into the lifting device 4, the lifting device 4 lifts the larger limestone into the primary grinding device 1 for grinding again, and the smaller limestone enters the secondary grinding device 3 for grinding through the vibrating screen 202; the screened limestone passes through the lifting device 4, the driving motor II 403 of the lifting device 4 drives the driving wheels 402 to rotate, a transmission belt 405 is arranged between the two driving wheels 402, a hopper 404 is fixed on the transmission belt 405, when the driving wheels 402 drive the transmission belt 405 to rotate, the hopper 404 also rotates along with the transmission belt, and the limestone screened by the screening device 2 is sent to the primary crushing device 1 through the hopper 404 to be crushed again; the screened limestone enters a secondary crushing device 3 to be crushed, the power of a power device 5 of the secondary crushing device 3 drives a transmission gear II 305 to rotate through a bevel gear II 304, the transmission gear II 305 and two gears II 303 are mutually kneaded and transmitted, the transmission gear II 305 drives the gears II 303 to rotate, the two secondary crushing rollers 302 also rotate along with the transmission gear II 303 and the secondary crushing rollers 302 due to the fixed connection between the gears II 303 and the secondary crushing rollers 302, and the smaller limestone blocks are crushed into lime powder through the interaction of the two secondary crushing rollers 302; the running speed of the crushing device of the second-stage crushing device 3 is faster than the rotating speed of the crushing device of the first-stage crushing device 1, and the second-stage crushing device 3 can be effectively protected from being damaged by the screening device 2.

Of course, the above description is not intended to limit the present invention, and the present invention is not limited to the above examples, and the changes, modifications, additions or replacements made by those skilled in the art within the scope of the present invention also belong to the protection scope of the present invention.

Claims

1. The utility model provides a cement processing equipment, includes one-level reducing mechanism (1), sieving mechanism (2), second grade reducing mechanism (3), hoisting device (4) and power device (5), its characterized in that: the grinding device is characterized in that a screening device (2) is fixedly connected below the first-stage grinding device (1), a second-stage grinding device (3) is fixedly connected below the screening device (2), a lifting device (4) is fixedly connected to the side face of the second-stage grinding device (3), one end of a power device (5) is fixedly connected with the first-stage grinding device (1), and the other end of the power device (5) is fixedly connected with the second-stage grinding device (3).

2. A cement processing plant according to claim 1, characterized in that: one-level reducing mechanism (1) is including frame I (101), one-level crushing gyro wheel (102), gear I (103), drive gear I (104) and bevel gear I (105), be provided with two one-level crushing gyro wheels (102) on frame I (101), the one end of every one-level crushing gyro wheel (102) is all rotated and is connected on frame I (101), the equal fixedly connected with gear I (103) of every one-level crushing gyro wheel (102), it is connected with drive gear I (104) to rotate on frame I (101), two gears I (103) all are connected with the meshing between drive gear I (104), fixedly connected with bevel gear I (105) on drive gear I (104), bevel gear I (105) are connected with power device (5) transmission, the below fixedly connected with sieving mechanism (2) of frame I (101).

3. A cement processing plant according to claim 2, characterized in that: screening device (2) are including frame II (201), shale shaker (202), connecting rod (203), bevel gear II (204) and bent axle (205), sliding connection has shale shaker (202) on frame II (201), be provided with the spring between shale shaker (202) and frame II (201), it is connected with bent axle (205) to rotate on frame II (201), be connected through connecting rod (203) transmission between bent axle (205) and shale shaker (202), the one end fixedly connected with bevel gear II (204) of bent axle (205), bevel gear II (204) rotate with power device (5) and are connected, frame II (201) fixed connection is in the below of frame I (101), the below fixedly connected with secondary crushing device (3) of frame II (201).

4. A cement processing plant according to claim 3, characterized in that: two-stage crushing device (3) are including frame III (301), second grade crushing gyro wheel (302), gear II (303), bevel gear III (304) and drive gear II (305), frame III (301) fixed connection is in the below of frame II (201), be provided with two second grade crushing gyro wheels (302) on frame III (301), the equal fixedly connected with gear II (303) of one end of every second grade crushing gyro wheel (302), it is connected with drive gear II (305) to rotate on frame III (301), two gears II (303) all are connected with the meshing between drive gear II (305), fixedly connected with bevel gear III (304) on drive gear II (305), bevel gear III (304) are connected with power device (5) transmission.

5. A cement processing plant according to claim 4, characterized in that: lifting device (4) are including frame IV (401), drive wheel (402), motor II (403), hopper (404) and drive belt (405), frame IV (401) fixed connection is in frame III (301), be provided with two drive wheel (402) on frame IV (401), every drive wheel (402) all rotates to be connected on frame IV (401), the one end fixed connection of one of them drive wheel (402) is on the output shaft of motor II (403), motor II (403) fixed connection is on frame IV (401), two drive wheel (402) are connected through drive belt (405) transmission, fixedly connected with a plurality of hopper (404) on drive belt (405).

6. A cement processing plant according to claim 5, characterized in that: power device (5) are including motor I (501), axle (502) and bevel gear IV (503), motor I (501) fixed connection is on frame III (301), fixedly connected with axle (502) on the output shaft of motor I (501), the one end of axle (502) is rotated and is connected on frame I (101), the other one end fixed connection of axle (502) is on frame III (301), set up three bevel gear IV (503) of fixedly connected with on axle (502), three bevel gear IV (503) are respectively in bevel gear I (105), bevel gear II (204) and bevel gear III (304) meshing connection.