CN110871499B - Ceramic clay kneading method - Google Patents

Abstract

A ceramic clay kneading method relates to the technical field of ceramic processing, and ceramic clay processing equipment mainly comprises a frame, a workbench, a turntable, an upper pressing plate, a left pressing plate and a right pressing plate. The ceramic clay processing method comprises the following steps: (1) placing ceramic clay on a turntable; (2) making the upper pressing plate move in an elliptic shape, and pressing the ceramic clay by using the upper pressing plate and a turntable; (3) the turntable is moved up and down, and the ceramic clay is pressed and processed by matching with the upper pressing plate; (4) the left pressing plate and the right pressing plate are mutually opened and closed, and the ceramic clay is pressed and processed; (5) making the turnplate rotate in one direction in one grid to rotate the ceramic clay; the steps (2) to (5) can be arranged and combined in different orders to realize different processing actions. In the invention, the turntable, the upper pressing plate, the left pressing plate and the right pressing plate can be mutually matched in different modes, so that various processing actions are realized, and the ceramic clay can be mixed more uniformly and more finely.

Description

Ceramic clay kneading method

Technical Field

The invention relates to the technical field of ceramic processing, in particular to a ceramic clay kneading method.

Background

The ceramic clay is a ceramic processing material formed by uniformly mixing various raw materials according to a certain proportion, and the uniform mixing of the various raw materials in the manufacturing process of the ceramic clay is an important working procedure. The existing mixing action is single, the mixing is not uniform, and fine clods still exist after mixing. Therefore, it is necessary to design a ceramic clay processing apparatus for uniformly mixing and kneading the ceramic clay.

Disclosure of Invention

The invention provides a ceramic clay kneading method, which aims to overcome the problems of the existing ceramic clay processing equipment.

The technical scheme adopted by the invention is as follows:

a method for kneading ceramic clay comprises a ceramic clay processing device, wherein the ceramic clay processing device comprises a frame, a workbench, a rotary table, an upper pressing plate, a left pressing plate and a right pressing plate, the workbench is horizontally arranged on the frame through a numerical control sliding table, the rotary table is horizontally and rotatably embedded in the workbench, and a ratchet drive mechanism for enabling the rotary table to rotate in a single direction is assembled; the left pressing plate and the right pressing plate are arranged on the rack in a manner of moving left and right through the screw rod sliding table driving mechanism, and the left pressing plate and the right pressing plate are oppositely distributed on the left side and the right side of the turntable; the upper pressure plate is movably arranged on the frame through a multi-connecting-rod driving mechanism and is positioned above the turntable; the ceramic clay processing method comprises the following steps:

(1) stacking a proper amount of ceramic clay on a turntable;

(2) the upper pressure plate is driven to move by a multi-connecting-rod driving mechanism, the motion trail of the upper pressure plate is approximately elliptic, and the ceramic clay is pressed and processed by the upper pressure plate matching with a turntable;

(3) the turntable is moved up and down through the numerical control sliding table, so that the distance between the turntable and the upper pressing plate is adjusted, and the ceramic clay is pressed and processed by matching with the upper pressing plate;

(4) the left pressing plate and the right pressing plate are mutually opened and closed by a screw rod sliding table driving mechanism to press and process the ceramic clay;

(5) the ratchet wheel driving mechanism makes the turnplate rotate in one direction in one grid to rotate the ceramic clay;

the steps (2) to (5) can be arranged and combined in different orders to realize different processing actions.

Further, the steps (2) and (3) can be simultaneously and repeatedly performed, namely, the upper pressing plate and the rotary table are repeatedly opened and closed mutually.

Further, the steps (3) and (5) can be simultaneously and repeatedly carried out, namely, the turnplate moves up and down and is matched with the upper pressing plate to press and process the ceramic clay, and the turnplate rotates in a single direction one by one.

Further, the steps (2), (3) and (5) can be simultaneously and repeatedly carried out, namely the upper pressing plate and the rotary table are repeatedly opened and closed mutually, and the rotary table rotates in a single direction one by one.

Further, the steps (4) and (5) can be repeated in a certain sequence, namely, the left pressing plate and the right pressing plate are opened and closed once when the turntable rotates one grid.

Further, the steps (2), (4) and (5) can be repeated in a certain sequence, namely, when the turntable rotates one cell, the left pressing plate and the right pressing plate are opened and closed once, and when the left pressing plate and the right pressing plate are opened each time, the upper pressing plate runs at least one circle.

Further, the steps (2), (3), (4) and (5) can be repeated according to a certain sequence, namely the left pressing plate and the right pressing plate are opened and closed once when the rotary disc 3 rotates one grid, and the upper pressing plate and the rotary disc are opened and closed at least once when the left pressing plate and the right pressing plate are opened each time.

Further, the multi-link driving mechanism comprises a driven shaft, a driving shaft, a left upper arm, a right upper arm, a left lower arm, a right lower arm, an upper connecting arm, a lower connecting arm and a first motor; the upper end of the left upper arm is hinged to a driven shaft of the rack, the upper end of the right upper arm is hinged to a driving shaft of the rack, and a first motor for enabling the driving shaft to rotate is assembled on the driving shaft; one end of the upper connecting arm is fixedly connected to the driving shaft, and the other end of the upper connecting arm is hinged to the upper end of the left lower arm; mutually hinging the lower end of the left upper arm, the middle part of the left lower arm and the left end of the lower connecting arm; the lower end of the right upper arm, the upper end of the right lower arm and the right end of the lower connecting arm are hinged with each other; and the lower ends of the left lower arm and the right lower arm are respectively hinged to the left end and the right end of the upper pressure plate.

Further, the screw rod sliding table driving mechanism comprises a screw rod, a left sliding block, a left connecting rod, a right sliding block, a right connecting rod and a second motor, and the screw rod is arranged on the rack and is provided with the second motor for rotating the screw rod; assembling a left sliding block and a right sliding block on a screw rod, connecting a left pressure plate to the left sliding block through a left connecting rod, and connecting a right pressure plate to the right sliding block through a right connecting rod; the ratchet driving mechanism comprises a ratchet, a swing rod, a driving pawl and a braking pawl, the upper end of a transmission shaft of the ratchet is fixedly connected to the rotary table, the lower end of the transmission shaft is hinged to the swing rod, the free end of the swing rod extends to the motion track of the right connecting rod, the driving pawl is hinged to the swing rod, and the braking pawl is rotatably arranged on the workbench;

in the step (5), the right connecting rod is moved by a small amplitude by the screw rod sliding table driving mechanism, the swing rod is shifted by the right connecting rod, and then the ratchet driving mechanism is triggered, and finally the rotary disc rotates in a single direction.

Compared with the prior art, the invention has the advantages that:

in the ceramic clay processing equipment used by the invention, the upper pressure plate is movably arranged on the frame in a mode that the motion track is approximately elliptic through the multi-connecting-rod driving mechanism, the upper pressure plate vertically extrudes the ceramic clay placed on the turntable and simultaneously has horizontal displacement, the action similar to manual kneading is formed, the ceramic clay can be effectively mixed, and fine soil blocks in the ceramic clay are crushed; in addition, the carousel can rotate, can rotate the carousel when the top board suppression ceramic clay, also can rotate certain angle with the carousel before or after the top board suppression ceramic clay at every turn, let the top board can follow the direction suppression ceramic clay of difference next time, let faster, more even that ceramic clay can mix, the tiny clod of more effective breakage. The left pressing plate and the right pressing plate are arranged on two sides of the rotary table oppositely, the left pressing plate and the right pressing plate are close to the center of the rotary table simultaneously, ceramic clay squashed by the upper pressing plate can be gathered again, and certain mixing and crushing effects can be started simultaneously. In order to gather the ceramic clay more intensively, the turntable may be rotated by a certain angle after each time the left and right press plates press the ceramic clay. Therefore, the turntable, the upper pressing plate, the left pressing plate and the right pressing plate can be mutually matched in different modes to finish different processing actions so as to achieve a better processing effect. In addition, the workstation can reciprocate through numerical control slip table set up in the frame, can adjust the workstation, change the distance between workstation and the holding down plate, and then the adjustment holding down plate is to the dynamics of action of ceramic clay, can also make the workstation move up when holding down plate downstream, make the workstation move down when holding down plate upstream, so "open and shut" ground is processed ceramic clay so repeatedly to holding down plate and workstation, with further strengthening machining efficiency, improve the processing effect.

Secondly, in the ceramic clay processing equipment used by the invention, the free end of the swing rod extends to the motion track of the right connecting rod, and the ratchet driving mechanism is triggered by the lead screw sliding table driving mechanism.

Drawings

FIG. 1 is a schematic view showing the construction of a ceramic clay processing apparatus according to the present invention.

FIG. 2 is a schematic view of a ratchet drive mechanism according to the present invention.

Detailed Description

The following describes embodiments of the present invention with reference to the drawings. Numerous details are set forth below in order to provide a thorough understanding of the present invention, but it will be apparent to those skilled in the art that the present invention may be practiced without these details.

Referring to fig. 1 and 2, a ceramic clay processing apparatus includes a frame 1, a table 2, a turntable 3, an upper press plate 4, a screw-sliding table driving mechanism 5, a multi-link driving mechanism 6, a ratchet driving mechanism 7, a left press plate 8, and a right press plate 9. Install numerical control slip table 10 in the pole setting of frame 1, both ends all set up in frame 1 through numerical control slip table 10 with reciprocating about workstation 2. The middle part of the upper end surface of the working table 2 is a horizontal plane, and the left side and the right side are inclined planes.

Referring to fig. 1 and 2, a turntable 3 is embedded in the middle of the upper end surface of the table 2, and a ratchet drive mechanism 7 for rotating the turntable 3 in one direction is provided.

Referring to fig. 1 and 2, the upper platen 4 is movably disposed on the frame 1 via a multi-link driving mechanism 5 in a manner that a motion trajectory is substantially elliptical and is located above the turntable 3.

Referring to fig. 1 and 2, a left pressing plate 8 and a right pressing plate 9 are arranged on the frame 1 through the screw rod sliding table driving mechanism 5 in a manner of moving left and right, the left pressing plate 8 and the right pressing plate 9 are oppositely distributed on the left side and the right side of the turntable 3, and the lower end surfaces of the left pressing plate 8 and the right pressing plate 9 are in contact with the upper end surface of the workbench 2.

Referring to fig. 1 and 2, specifically, the screw sliding table driving mechanism 5 includes a screw 51, a left slider 52, a left connecting rod 53, a right slider 54, a right connecting rod 55, and a second motor 56, and both ends of the screw 51 are horizontally and rotatably disposed on the sliders of one numerical control sliding table 10, respectively, and the second motor 56 for operating the screw 51 is provided. The left half of the screw 51 is a right-hand thread section and is provided with a left slider 52. The left connecting rod 53 can be vertically moved and penetrate through the left sliding block 52, the upper end of the left connecting rod 53 is connected to the left pressing plate 8, a left disc is fixedly arranged at the lower end of the left connecting rod 53, and a left compression spring 57 which enables the left connecting rod 53 to move downwards is arranged between the left disc and the left sliding block 52. The right half of the screw 51 is a reverse threaded section and is provided with a right slider 54. The right connecting rod 55 is vertically movably inserted into the right slider 54, the upper end of the right connecting rod 55 is connected to the right pressing plate 9, the lower end of the right connecting rod 55 is fixedly provided with a right disc, and a right compression spring 58 for making the right connecting rod 55 move downwards is arranged between the right disc and the right slider 52. In order to make the left pressing plate 8 and the right pressing plate 9 more stable, the front end and the rear end of the workbench 2 of the processing equipment are respectively provided with a screw rod sliding table driving mechanism 5, and the two screw rod sliding table driving mechanisms 5 are synchronous through a transmission shaft (not shown in the figure). The two left connecting rods 53 are connected to the front and rear ends of the left press plate 8, and the two right connecting rods 55 are connected to the front and rear ends of the right press plate 9.

Referring to fig. 1 and 2, specifically, the ratchet drive mechanism 7 specifically includes a ratchet 71, a swing lever 72, a drive pawl 73, a brake pawl 74, a torsion spring, and a spring 75. Wherein, the transmission shaft 711 of the ratchet 71 is rotatably disposed on the working platform 2, the upper end of the transmission shaft 711 is fixedly connected to the bottom of the rotating disc 3, and the upper end of the transmission shaft 711 is hinged with a swing link 72 (an elastic member, such as a torsion spring, is assembled between the swing link and the transmission shaft for restoring the swing link). The free end of the swing link 72 extends to the motion track of the right connecting rod 55, and the swing link 72 is shifted by the right connecting rod 55, so as to trigger the ratchet driving mechanism 7. The driving pawl 73 is hinged to the swing lever 72 and provided with the above-described torsion spring (not shown) for bringing the same into close contact with the ratchet, and the braking pawl 74 is rotatably provided on the table 2 and provided with a spring 75 for bringing the same into close contact with the ratchet.

Referring to fig. 1 and 2, specifically, the multi-link drive mechanism 6 includes a driven shaft 61, a drive shaft 62, a left upper arm 63, a right upper arm 64, a left lower arm 65, a right lower arm 66, an upper connecting arm 67, a lower connecting arm 68, and a first motor 69. Wherein the driven shaft 61 and the driving shaft 62 are both rotatably provided on the frame 1, and the driving shaft 62 is equipped with a first motor 69 that rotates it. The upper end of the left upper arm 63 is hinged with the driven shaft 61, and the upper end of the right upper arm 64 is hinged with the driving shaft 62. The upper connecting arm 67 has one end fixedly connected to the driving shaft 62 and the other end hinged to the upper end of the left lower arm 65. The lower end of the left upper arm 63, the middle of the left lower arm 65, and the left end of the lower connecting arm 68 are hinged to each other. The lower end of the right upper arm 64, the upper end of the right lower arm 66, and the right end of the lower connecting arm 68 are hinged to each other. The left lower arm 65 is hinged to the left end of the upper end face of the upper platen 4, and the right lower arm 66 is hinged to the right end of the upper end face of the upper platen 4.

Referring to fig. 1 and 2, a specific method of ceramic clay processing using the above ceramic clay processing apparatus:

(1) an appropriate amount of ceramic clay to be processed is piled up at the center of the turntable 3.

(2) The first motor 69 is used as a power source, the upper pressing plate 4 is driven to move through the multi-connecting-rod driving mechanism 6, the movement track of the upper pressing plate 4 is approximately elliptic, and the upper pressing plate 4 is matched with the rotary table 3 to press and process the ceramic clay.

(3) The turntable 3 is moved up and down through the numerical control sliding table 10, so that the distance between the turntable 3 and the upper pressing plate 4 is adjusted, and the upper pressing plate 4 is matched to press and process the ceramic clay.

(4) And a second motor 56 is used as a power source, and the left pressing plate 8 and the right pressing plate 9 are mutually opened and closed through the screw rod sliding table driving mechanism 5, so that the ceramic clay is pressed and processed.

(5) The second motor 56 is used as a power source, the right connecting rod 55 is moved in a small range through the screw rod sliding table driving mechanism 5, the swing rod 72 is shifted by the right connecting rod 55, and then the ratchet driving mechanism 7 is triggered, so that the rotary disc 3 rotates in a one-way mode in one grid to rotate the ceramic clay.

The steps (2), (3), (4) and (5) can be arranged and combined in different orders to realize different processing actions. For example:

step one, step (2) and step (3) can be carried out simultaneously and repeatedly, make upper platen 4 and rotary table 3 open and shut each other repeatedly; the elliptical motion of the upper platen 4 causes the ceramic clay to flow vertically, i.e., the bottom ceramic clay gradually moves upward and the top ceramic clay gradually moves downward.

Step (3) and step (5) can be carried out simultaneously and repeatedly, when the rotary table 3 moves up and down to press the ceramic clay, the rotary table 3 rotates unidirectionally, at the same time, the rotation of the rotary table 3 can make the ceramic clay flow horizontally, even if the ceramic clay on the left side gradually moves towards the right, and the ceramic clay on the right side gradually moves towards the left.

Step (2), (3) and (5) can be performed simultaneously and repeatedly, and the specific principle refers to the above.

And fourthly, the steps (4) and (5) can be arranged in sequence and repeated, and the left pressing plate 8 and the right pressing plate 9 are opened and closed once each rotating cell of the turntable 3, so that the ceramic clay at different positions can be processed, and all the ceramic clay can be gathered again and positioned at the central position of the turntable.

And fifthly, the steps (2), (4) and (5) can be arranged in sequence and repeated, namely, the rotary disc 3 opens and closes the left pressing plate 8 and the right pressing plate 9 once per rotation, and the upper pressing plate 4 rotates at least one circle when the left pressing plate 8 and the right pressing plate 9 open each time.

Sixthly, the steps (2), (3), (4) and (5) can be arranged in sequence and repeated, namely, the rotary disc 3 opens and closes the left pressing plate 8 and the right pressing plate 9 once when rotating one cell, and the upper pressing plate 4 and the rotary disc 3 open and close at least once when the left pressing plate 8 and the right pressing plate 9 open each time.

The combination of the steps (2), (3), (4) and (5) is not limited to the above, and cannot be listed here, as long as the processing equipment can be ensured to operate normally.

The above description is only an embodiment of the present invention, but the design concept of the present invention is not limited thereto, and any insubstantial modifications made by using the design concept should fall within the scope of infringing the present invention.

Claims (8)

1. A ceramic clay kneading method is characterized in that: the ceramic clay processing equipment comprises a rack, a workbench, a rotary table, an upper pressing plate, a left pressing plate and a right pressing plate, wherein the workbench is horizontally arranged on the rack through a numerical control sliding table, and the rotary table is horizontally and rotatably embedded in the workbench and is assembled with a ratchet driving mechanism which enables the rotary table to rotate in a single direction; the left pressing plate and the right pressing plate are arranged on the rack in a manner of moving left and right through the screw rod sliding table driving mechanism, and the left pressing plate and the right pressing plate are oppositely distributed on the left side and the right side of the turntable; the upper pressure plate is movably arranged on the frame through a multi-connecting-rod driving mechanism and is positioned above the turntable; the multi-connecting-rod driving mechanism comprises a driven shaft, a driving shaft, a left upper arm, a right upper arm, a left lower arm, a right lower arm, an upper connecting arm, a lower connecting arm and a first motor; the upper end of the left upper arm is hinged to a driven shaft of the rack, the upper end of the right upper arm is hinged to a driving shaft of the rack, and a first motor for enabling the driving shaft to rotate is assembled on the driving shaft; one end of the upper connecting arm is fixedly connected to the driving shaft, and the other end of the upper connecting arm is hinged to the upper end of the left lower arm; mutually hinging the lower end of the left upper arm, the middle part of the left lower arm and the left end of the lower connecting arm; the lower end of the right upper arm, the upper end of the right lower arm and the right end of the lower connecting arm are hinged with each other; the lower ends of the left lower arm and the right lower arm are respectively hinged to the left end and the right end of the upper pressure plate; the ceramic clay processing method comprises the following steps:

(1) stacking a proper amount of ceramic clay on a turntable;

(2) the upper pressure plate is driven to move by a multi-connecting-rod driving mechanism, the motion trail of the upper pressure plate is approximately elliptic, and the ceramic clay is pressed and processed by the upper pressure plate matching with a turntable;

(3) the turntable is moved up and down through the numerical control sliding table, so that the distance between the turntable and the upper pressing plate is adjusted, and the ceramic clay is pressed and processed by matching with the upper pressing plate;

(4) the left pressing plate and the right pressing plate are mutually opened and closed by a screw rod sliding table driving mechanism to press and process the ceramic clay;

(5) the ratchet wheel driving mechanism makes the turnplate rotate in one direction in one grid to rotate the ceramic clay;

the steps (2) to (5) can be arranged and combined in different orders to realize different processing actions.

2. The ceramic clay kneading method according to claim 1, characterized in that: the steps (2) and (3) can be carried out simultaneously and repeatedly, namely the upper pressing plate and the rotary table are mutually opened and closed repeatedly.

3. The ceramic clay kneading method according to claim 1, characterized in that: the steps (3) and (5) can be simultaneously and repeatedly carried out, namely, the turnplate moves up and down and is matched with the upper pressing plate to press and process the ceramic clay, and the turnplate rotates in a single direction one by one.

4. The ceramic clay kneading method according to claim 1, characterized in that: the steps (2), (3) and (5) can be simultaneously and repeatedly carried out, namely the upper pressing plate and the rotary table are repeatedly opened and closed mutually, and the rotary table rotates in a single direction one by one.

5. A ceramic clay kneading method according to claim 1, wherein: the steps (4) and (5) can be repeated in a certain sequence, namely, the left pressing plate and the right pressing plate are opened and closed once when the turntable rotates one grid.

6. The ceramic clay kneading method according to claim 1, characterized in that: the steps (2), (4) and (5) can be repeated in a certain sequence, namely, the left pressing plate and the right pressing plate are opened and closed once when the turntable rotates one grid, and the upper pressing plate runs for at least one circle when the left pressing plate and the right pressing plate are opened each time.

7. The ceramic clay kneading method according to claim 1, characterized in that: the steps (2), (3), (4) and (5) can be repeated according to a certain sequence, namely the left pressing plate and the right pressing plate are opened and closed once when the turntable rotates one grid, and the upper pressing plate and the turntable are opened and closed at least once when the left pressing plate and the right pressing plate are opened each time.

8. The ceramic clay kneading method according to claim 1, characterized in that: the screw rod sliding table driving mechanism comprises a screw rod, a left sliding block, a left connecting rod, a right sliding block, a right connecting rod and a second motor, and the screw rod is arranged on the rack and is provided with the second motor for rotating the screw rod; assembling a left sliding block and a right sliding block on a screw rod, connecting a left pressure plate to the left sliding block through a left connecting rod, and connecting a right pressure plate to the right sliding block through a right connecting rod; the ratchet driving mechanism comprises a ratchet, a swing rod, a driving pawl and a braking pawl, the upper end of a transmission shaft of the ratchet is fixedly connected to the rotary table, the lower end of the transmission shaft is hinged to the swing rod, the free end of the swing rod extends to the motion track of the right connecting rod, the driving pawl is hinged to the swing rod, and the braking pawl is rotatably arranged on the workbench;

in the step (5), the right connecting rod is moved by a small amplitude by the screw rod sliding table driving mechanism, the swing rod is shifted by the right connecting rod, and then the ratchet driving mechanism is triggered, and finally the rotary disc rotates in a single direction.

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