CN116653086A - Pyrophyllite block compression molding device - Google Patents

Abstract

The invention discloses a pyrophyllite block compression molding device, which relates to the technical field of pyrophyllite block production and comprises a main body frame and a pushing component, wherein a first motor is arranged on the left side of the main body frame, a first transmission shaft is fixedly connected with the output end of the first motor, a transmission belt is sleeved on the outer wall of the first transmission shaft, and the pushing component for transmitting stones is arranged at one end, far away from the first transmission shaft, of the transmission belt. This pyrophyllite piece compression molding device makes push subassembly control push rod horizontal displacement about the base plate top surface through driving first motor, can be after the hydraulic press is to the pyrophyllite piece suppression in the mould, push the ejection of compact department with fashioned pyrophyllite piece to at this in-process, first motor also can drive sliding component simultaneously, make the push rod at the in-process of pushing away the material, lifting die cooperates it to accomplish the pushing away the material, avoided the staff in actual production, manual process of taking out the pyrophyllite piece from the mould, saved the cost of labor, improved production efficiency.

Description

Pyrophyllite block compression molding device

Technical Field

The invention relates to the technical field of pyrophyllite block production, in particular to a pyrophyllite block compression molding device.

Background

The pyrophyllite has the advantages of fine texture, softness and greasiness, has the characteristics of good machining performance, white powder color, high oil absorption rate, good coverage rate and the like, has the purposes closely related to the characteristics, and is mainly used as a refractory material, a ceramic material and an engraving raw material; and is also used as filler and carrier for rubber products, cosmetics, pesticides, etc.

Pyrophyllite blocks are widely applied to industrial production due to the good performances of pressure maintaining, pressure transmission, sealing, heat resistance, heat preservation and insulation, and are integrally in a square structure and mainly composed of a dolomite ring and pyrophyllite blocks, and the pyrophyllite blocks are generally obtained by pressing and molding pyrophyllite raw materials and dolomite rings.

In the production stage, the pyrophyllite blocks formed by compression are generally taken out from the mould manually by a worker, the worker stretches hands into a compression point in the middle of the machine to take out the compression part, the process of manually taking out the pyrophyllite blocks from the mould is low in safety and easy to generate potential safety hazards, the worker repeatedly realizes the process more laboriously, the working efficiency is reduced, the danger is easy to generate, the labor cost is increased, and the production and development of enterprises are not facilitated.

Therefore, it is necessary to design a pyrophyllite block compression molding device with a pushing function so as to solve the defects in the prior art.

Disclosure of Invention

The invention aims to provide a pyrophyllite block compression molding device, which aims to solve the problems that in the background technology, the pyrophyllite block is usually taken out from a mold manually by a worker, the worker stretches hands into a pressing point in the middle of a machine to take out a pressed part, and the pyrophyllite block is taken out from the mold manually.

In order to achieve the above purpose, the present invention provides the following technical solutions: the pyrophyllite block compression molding device comprises a main body frame and a pushing component, wherein a first motor is arranged on the left side of the main body frame, a first transmission shaft is fixedly connected with the output end of the first motor, a transmission belt is sleeved on the outer wall of the first transmission shaft, and the pushing component for transmitting the stones is arranged at one end, far away from the first transmission shaft, of the transmission belt;

the pushing assembly comprises a second transmission shaft, a second screw rod, a second sliding block, a first bearing, a push rod, a third sliding block, a second limiting rod and a stop block, wherein the second screw rod is fixedly connected with the outer wall of the second transmission shaft, the second sliding block is sleeved on the outer wall of the second screw rod, the first bearings are arranged on two sides of the second sliding block and are rotationally connected with the second screw rod, the first bearings are fixedly connected with the outer wall of the main body frame, the push rod is fixedly connected with the outer wall of the second sliding block, the third sliding block is arranged at one end, far away from the second sliding block, of the push rod, the second sliding block and the third sliding block are at the same horizontal height, the second limiting rod is arranged in the middle of the third sliding block, the stop blocks are arranged at two ends of the second limiting rod, and the stop block is fixedly connected with the outer wall of the main body frame.

Further, the first transmission shaft is kept away from first motor one side and is equipped with the slip subassembly that is used for controlling elevating movement, slip subassembly includes first lead screw, first slider, guide rail board and track groove, first lead screw outer wall cover is equipped with first slider, first slider outer wall is equipped with the guide rail board, the track groove has been seted up with first slider correspondence department to the guide rail board.

Further, the sliding assembly further comprises a limiting plate, a first limiting rod and a limiting groove, wherein the limiting plate is fixedly connected to the front side of the first sliding block, the first limiting rod is arranged on the front side of the limiting plate, and the limiting groove is formed in the position, corresponding to the first limiting rod, of the limiting plate.

Further, the sliding component further comprises a first connecting rod and a sleeve, the first connecting rod is sleeved on the outer wall of the first limiting rod, the first connecting rod is formed by welding a hollow rod-shaped structure at the bottom and a solid rod body, the first connecting rod is of a T-shaped structural design, the sleeve is arranged on the outer wall of the first connecting rod, a connecting piece is fixedly connected to the rear side of the sleeve, and the sleeve is fixedly connected with a guide rail plate.

Further, one end of the first limiting rod, which is far away from the limiting plate, is fixedly connected with a die, a substrate is arranged below the die, and the substrate is fixedly connected with the main body frame.

Further, a hydraulic machine is fixedly connected to the top of the inner wall of the main body frame, a hydraulic rod is arranged at the output end of the hydraulic machine, and the hydraulic rod and the die are distributed in the same vertical line.

Further, a discharging barrel is arranged on the left side of the hydraulic machine, and a material adding port is formed in the outer wall of the discharging barrel.

Further, the spiral blade is arranged in the discharging barrel, a second motor is arranged on the left side of the discharging barrel, and the output end of the second motor and the spiral She Gujie are arranged.

Further, the observation window has been seted up to main part frame outer wall, second motor top outer wall is equipped with the second connecting rod, the discharge gate has been seted up to one side that the second motor was kept away from to the ejection of compact bucket.

The invention provides a pyrophyllite block compression molding device, which has the following beneficial effects:

1. according to the invention, the pushing component is driven to control the push rod to transversely move left and right on the top surface of the substrate, the molded pyrophyllite blocks can be pushed to the discharging position after the hydraulic press is used for pressing the pyrophyllite blocks in the die, and in the process, the first motor can also drive the sliding component, so that the push rod can lift the die to complete pushing in the pushing process, the process that staff takes out the pyrophyllite blocks from the die manually in actual production is avoided, the labor cost is saved, the production efficiency is improved, and the production safety is improved;

2. according to the invention, the lifting of the first limiting rod is controlled by the sliding component to drive the lifting of the die, the pressing work of the hydraulic press is matched, after the hydraulic rod completes the pressing task, the die is lifted up first and then lifted up, the situation that pyrophyllite blocks are adhered to the die after being pressed and molded is solved by controlling the lifting time difference of the die lifting and the hydraulic rod, meanwhile, the pushing work of the pushing component is matched, the working efficiency is improved, and the time cost is saved;

3. through add the spiral leaf to the ejection of compact bucket, make second motor drive spiral leaf add the material to the mould, can realize adding the material automatically in the pyrophyllite block compression molding in-process, avoided artifical manual process of adding the material to the mould, reduced the human cost, indirectly promoted production efficiency.

Drawings

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

FIG. 2 is a schematic perspective view of the present invention;

FIG. 3 is a schematic perspective view of the present invention;

FIG. 4 is a schematic perspective view of the present invention;

FIG. 5 is a schematic view of a three-dimensional structure of a limiting plate according to the present invention;

FIG. 6 is a schematic diagram of a second screw rod perspective structure according to the present invention;

FIG. 7 is a schematic perspective view of a track plate of the present invention;

FIG. 8 is a schematic cross-sectional view of the discharge vessel of the present invention.

In the figure: 1. a main body frame; 2. a first motor; 3. a first drive shaft; 4. a sliding assembly; 401. a first screw rod; 402. a first slider; 403. a guide rail plate; 404. a track groove; 405. a limiting plate; 406. a first stop lever; 407. a limit groove; 408. a first connecting rod; 409. a sleeve; 5. a mold; 6. a transmission belt; 7. a pushing assembly; 701. a second drive shaft; 702. a second screw rod; 703. a second slider; 704. a first bearing; 705. a push rod; 706. a third slider; 707. a second limit rod; 708. a stop block; 8. a hydraulic press; 9. a hydraulic rod; 10. an observation window; 11. a second motor; 12. spiral leaves; 13. discharging barrels; 14. a material adding port; 15. a discharge port; 16. a second connecting rod; 17. a substrate.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, based on the embodiments of the invention, which are apparent to those of ordinary skill in the art without undue burden are within the scope of the invention

Referring to fig. 1, 4 and 6, a pyrophyllite block compression molding device comprises a main body frame 1 and a pushing component 7, wherein a first motor 2 is arranged on the left side of the main body frame 1, a first transmission shaft 3 is fixedly connected with the output end of the first motor 2, a transmission belt 6 is sleeved on the outer wall of the first transmission shaft 3, and the pushing component 7 for transmitting the pyrophyllite block is arranged at one end, far away from the first transmission shaft 3, of the transmission belt 6;

the method comprises the following steps of firstly driving a first motor 2 to operate, driving a first transmission shaft 3 to rotate, driving a pushing assembly 7 to operate through a transmission belt 6, and enabling a sliding assembly 4 and the pushing assembly 7 to operate simultaneously through a set of power mechanism;

referring to fig. 1-8, the pushing assembly 7 includes a second transmission shaft 701, a second lead screw 702, a second sliding block 703, a first bearing 704, a push rod 705, a third sliding block 706, a second limiting rod 707 and a stop block 708, wherein the second lead screw 702 is fixedly connected to the outer wall of the second transmission shaft 701, the second sliding block 703 is sleeved on the outer wall of the second lead screw 702, the first bearing 704 is rotatably connected to the second lead screw 702, the first bearing 704 is fixedly connected to the outer wall of the main body frame 1, the push rod 705 is fixedly connected to the outer wall of the second sliding block 703, the third sliding block 706 is arranged at one end of the push rod 705 far away from the second sliding block 703, the second sliding block 703 and the third sliding block 706 are at a uniform horizontal height, the second limiting rod 707 is arranged in the middle of the third sliding block 706, the stop blocks 708 are arranged at two ends of the second limiting rod 707, and the stop block 708 is fixedly connected to the outer wall of the main body frame 1;

the method comprises the specific operation that a first motor 2 is driven to rotate, a first transmission shaft 3 is driven to rotate, a transmission belt 6 is used for driving a second transmission shaft 701 to rotate, at the moment, a second screw rod 702 fixedly connected with the second transmission shaft 701 also rotates in a first bearing 704, namely a second sliding block 703 sleeved on the outer wall of the second screw rod 702 transversely moves left and right along the second screw rod 702, at the moment, a push rod 705 fixedly connected with the second screw rod 702 also moves along, namely the push rod 705 finishes pressing pyrophyllite blocks in a die 5 through a hydraulic press 8, and after the die 5 and a hydraulic rod 9 are lifted, the pyrophyllite blocks formed on the top surface of a substrate 17 are pushed to left and right discharge positions.

Wherein, the third slide block 706 and the second slide block 703 are at the same horizontal height, the second limiting rod 707 and the second screw rod 702 are at corresponding positions, the stop block 708 limits the third slide block 706, and the first bearing 704 limits the second slide block 703;

referring to fig. 2, 3, 5 and 7, a sliding assembly 4 for controlling lifting movement is arranged on one side, away from the first motor 2, of the first transmission shaft 3, the sliding assembly 4 comprises a first screw rod 401, a first slider 402, a guide rail plate 403 and a track groove 404, the first slider 402 is sleeved on the outer wall of the first screw rod 401, the guide rail plate 403 is arranged on the outer wall of the first slider 402, and the track groove 404 is formed at the position, corresponding to the first slider 402, of the guide rail plate 403;

the specific operation is that the first motor 2 is driven to drive the first transmission shaft 3 to rotate, the first transmission shaft 3 drives the first screw rod 401 to rotate, and at the moment, the first sliding block 402 sleeved on the outer wall of the first screw rod 401 slides left and right in the track groove 404 in the guide rail plate 403;

referring to fig. 5-7, the sliding component 4 further includes a limiting plate 405, a first limiting rod 406 and a limiting groove 407, the front side of the first sliding block 402 is fixedly connected with the limiting plate 405, the front side of the limiting plate 405 is provided with the first limiting rod 406, the corresponding part of the limiting plate 405 and the first limiting rod 406 is provided with the limiting groove 407, the sliding component 4 further includes a first connecting rod 408 and a sleeve 409, the outer wall of the first limiting rod 406 is sleeved with the first connecting rod 408, the first connecting rod 408 is formed by welding a hollow rod-shaped structure at the bottom and a solid rod body, the first connecting rod 408 is of a T-shaped structure design, the outer wall of the first connecting rod 408 is provided with a sleeve 409, the rear side of the sleeve 409 is fixedly connected with a connecting piece, the sleeve 409 is fixedly connected with the guide rail plate 403, one end of the first limiting rod 406 away from the limiting plate 405 is fixedly connected with a die 5, the lower part of the die 5 is provided with a substrate 17, and the substrate 17 is fixedly connected with the main body frame 1;

the invention controls the lifting of the mould 5 through the sliding component 4, cooperates with the pressing work of the hydraulic press 8, solves the adhesion situation between the molded pyrophyllite block and the mould 5 through the lifting time difference of the hydraulic rod 9, and cooperates with the pushing work of the pushing component 7, thereby improving the working efficiency and saving the time cost;

when the mold 5 needs to be injected and pressed, the first stop lever 406 drives the mold 5 to cling to the top surface of the base plate 17, after the pressing is finished, the mold 5 is lifted before the hydraulic rod 9, the stop slot 407 on the outer wall of the stop plate 405 is of a parallelogram structure, the first stop lever 406 is in a stable state when moving to an up-down track position, and is in a lifting state when moving to the left-right track slot 404, namely, the first stop lever 406 performs intermittent lifting movement when moving in the stop slot 407;

the inner wall of the driving belt 6 is designed in a latch-shaped structure, and gears are arranged near the corresponding positions of the first driving shaft 3, the second driving shaft 701 and the driving belt 6, so that the driving belt 6 drives the second driving shaft 701 to synchronously drive.

Referring to fig. 1, 2 and 8, a hydraulic machine 8 is fixedly connected to the top of the inner wall of a main body frame 1, a hydraulic rod 9 is arranged at the output end of the hydraulic machine 8, the hydraulic rod 9 and a die 5 are distributed in the same vertical line, a discharge barrel 13 is arranged at the left side of the hydraulic machine 8, a material adding port 14 is arranged at the outer wall of the discharge barrel 13, a spiral blade 12 is arranged in the discharge barrel 13, a second motor 11 is arranged at the left side of the discharge barrel 13, the output end of the second motor 11 is fixedly connected with the spiral blade 12, an observation window 10 is arranged at the outer wall of the main body frame 1, a second connecting rod 16 is arranged at the outer wall above the second motor 11, and a discharge port 15 is arranged at one side of the discharge barrel 13 far away from the second motor 11;

the method comprises the following specific operations that firstly, a material adding port 14 is opened, material is added into a discharging barrel 13, after the step is completed, a second motor 11 is driven to drive a spiral blade 12 to rotate, at the moment, processing material in the discharging barrel 13 is discharged into a die 5 from a material outlet 15, after material is added into the die 5, the second motor 11 stops running, at the moment, a hydraulic press 8 runs, a hydraulic rod 9 presses the processing material in the die 5, the hydraulic rod 9 rises after press forming, a press formed pyrophyllite block is conveyed away by a push rod 705, then the operation flow is repeated, automatic material adding in the press forming process of the pyrophyllite block can be realized by adding the spiral blade 12 into the discharging barrel 13, the manual material adding process of the die 5 is avoided, the labor cost is reduced, and the production efficiency is indirectly improved.

Wherein the second motor 11 and the discharging barrel 13 are fixedly connected with the second connecting rod 16 respectively, the centers of the second motor 11 and the discharging barrel 13 are at a uniform horizontal height, and workers can observe from the observation window 10 in the whole production process;

and the material adding port 14 of the discharging barrel 13 can be externally connected with a charging box, so that uninterrupted material supply is realized.

Working principle: firstly, a material adding port 14 is opened to add materials into a material discharging barrel 13, after the step is completed, a second motor 11 is driven to drive a spiral blade 12 to rotate, at the moment, the processed materials in the material discharging barrel 13 are discharged into a die 5 from a material discharging port 15, after the material is added into the die 5, the second motor 11 stops running, at the moment, a hydraulic press 8 runs, a hydraulic rod 9 presses the processed materials in the die 5, the hydraulic rod 9 rises after press forming, a first motor 2 is driven to drive a first transmission shaft 3 to rotate, the first transmission shaft 3 drives a first screw rod 401 to rotate, at the moment, a first sliding block 402 sleeved on the outer wall of the first screw rod 401 slides left and right in a track groove 404 in a guide rail plate 403, a limiting plate 405 fixedly connected with the first sliding block 402 also moves along with the action of the limiting groove 407 of the first limiting rod 406, at the moment, intermittent lifting movement is started, and a first connecting rod and a sleeve 409 enable the first limiting rod 406 to be vertically stable, the mould 5 fixedly connected with the first limiting rod 406 also moves along with the mould in an intermittent lifting manner, before the hydraulic rod 9 is lifted, the mould 5 is lifted off the surface of the base plate 17 at first, the first motor 2 is driven to rotate, the second transmission shaft 701 is driven to rotate through the transmission belt 6, at the moment, the second screw rod 702 fixedly connected with the second transmission shaft 701 also rotates in the first bearing 704, namely, the second sliding block 703 sleeved on the outer wall of the second screw rod 702 moves transversely left and right along the second screw rod 702, at the moment, the push rod 705 fixedly connected with the second screw rod 702 also moves along with the second screw rod 702, the third sliding block 706 and the second sliding block 703 are at the same level, the second limiting rod 707 and the second screw rod 702 are at corresponding positions, the stop block 708 limits the third sliding block 706, the first bearing 704 limits the second sliding block 703, namely, the push rod 705 presses the pyrophyllite block in the mould 5 at the hydraulic press 8, after the mould 5 and the hydraulic rod 9 are lifted, the pyrophyllite block molded on the top surface of the base plate 17 is pushed to left and right discharging positions, the subsequent production is repeated, the mould 5 is firstly added, then the hydraulic machine 8 presses the pyrophyllite block for molding, then the mould 5 is lifted, and finally the push rod 705 pushes the pyrophyllite block.

According to the technical scheme, the pushing component 7 with the push rod 705 is arranged, the sliding component 4 is correspondingly arranged to be matched with the pushing component, the simple mechanical structure is not utilized, the compression molding and the automatic pushing of the workpiece can be completed, the production efficiency is effectively improved, and the use is more convenient.

It is noted that relational terms such as first and second, and the like are used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Moreover, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The foregoing is merely a preferred embodiment of the present invention, and it should be noted that it will be apparent to those skilled in the art that several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the scope of the invention.

Claims (10)

1. The pyrophyllite block compression molding device is characterized by comprising a main body frame (1) and a pushing assembly (7), wherein a first motor (2) is arranged on the left side of the main body frame (1), a first transmission shaft (3) is fixedly arranged at the output end of the first motor (2), a transmission belt (6) is sleeved on the outer wall of the first transmission shaft (3), and the pushing assembly (7) for transmitting a stone block is arranged at one end, far away from the first transmission shaft (3), of the transmission belt (6);

the pushing assembly (7) comprises a second transmission shaft (701), a second screw rod (702), a second sliding block (703), a first bearing (704), a push rod (705), a third sliding block (706), a second limiting rod (707) and a stop block (708), wherein the second screw rod (702) is fixedly connected with the outer wall of the second transmission shaft (701), the second sliding block (703) is sleeved on the outer wall of the second screw rod (702), the first bearings (704) are rotatably connected with the second screw rod (702), the first bearings (704) are fixedly connected with the outer wall of the main body frame (1), the push rod (705) is fixedly connected with the outer wall of the second sliding block (703), one end, far away from the second sliding block (703), of the push rod (705) is provided with the third sliding block (706), the second sliding block (703) and the third sliding block (706) are at the same horizontal height, the middle part of the third sliding block (706) is provided with the second limiting rod (703), the two ends of the second limiting rod (707) are provided with the stop block (708), and the main body frame (1) is fixedly connected with the stop block (708).

2. The pyrophyllite block compression molding device according to claim 1, wherein a sliding assembly (4) for controlling lifting movement is arranged on one side, away from the first motor (2), of the first transmission shaft (3), the sliding assembly (4) comprises a first screw rod (401), a first sliding block (402), a guide rail plate (403) and a rail groove (404), the first sliding block (402) is sleeved on the outer wall of the first screw rod (401), the guide rail plate (403) is arranged on the outer wall of the first sliding block (402), and the rail groove (404) is formed in the position, corresponding to the first sliding block (402), of the guide rail plate (403).

3. A pyrophyllite block compression molding apparatus as claimed in claim 2, wherein the slide assembly (4) further comprises a limiting plate (405), a first limiting rod (406) and a limiting groove (407),

the front side rigid coupling of first slider (402) is equipped with limiting plate (405), limiting plate (405) front side is equipped with first gag lever post (406), limiting plate (405) are equipped with spacing groove (407) with first gag lever post (406) corresponding department.

4. A pyrophyllite block compression molding device according to claim 3, wherein the sliding component (4) further comprises a first connecting rod (408) and a sleeve (409), the first connecting rod (408) is sleeved on the outer wall of the first limiting rod (406), the first connecting rod (408) is formed by welding a hollow rod-shaped structure at the bottom and a solid rod body, the first connecting rod (408) is of a T-shaped structural design, the sleeve (409) is arranged on the outer wall of the first limiting rod (408), a connecting piece is fixedly connected to the rear side of the sleeve (409), and the sleeve (409) is fixedly connected with the guide rail plate (403).

5. A pyrophyllite block compression molding device according to claim 3, wherein one end of the first limiting rod (406) far away from the limiting plate (405) is fixedly connected with a mold (5), a substrate (17) is arranged below the mold (5), and the substrate (17) is fixedly connected with the main body frame (1).

6. The pyrophyllite block compression molding device according to claim 5, wherein a hydraulic machine (8) is fixedly connected to the top of the inner wall of the main body frame (1), a hydraulic rod (9) is arranged at the output end of the hydraulic machine (8), and the hydraulic rod (9) and the die (5) are distributed in the same vertical line.

7. The pyrophyllite block compression molding device according to claim 6, wherein a discharge barrel (13) is arranged on the left side of the hydraulic machine (8), and a material adding port (14) is formed in the outer wall of the discharge barrel (13).

8. The pyrophyllite block compression molding device according to claim 7, wherein a spiral blade (12) is arranged in the discharging barrel (13), a second motor (11) is arranged on the left side of the discharging barrel (13), and the output end of the second motor (11) is fixedly connected with the spiral blade (12).

9. A pyrophyllite block compression molding apparatus as claimed in claim 1, wherein the outer wall of the main body frame (1) is provided with an observation window (10).

10. The pyrophyllite block compression molding device according to claim 8, wherein a second connecting rod (16) is arranged on the outer wall above the second motor (11), and a discharge port (15) is formed in one side, far away from the second motor (11), of the discharge barrel (13).