CN114888932B - Automatic die assembly centering device for manufacturing ceramic pot - Google Patents

Abstract

The invention belongs to the technical field of equipment for opening and closing a model, and discloses an automatic mold closing and centering device for manufacturing a ceramic pot, which comprises a mold, wherein the mold comprises a bottom mold and two side molds, and also comprises a driving piece for driving the side molds to move, the driving piece comprises two threaded rods which are respectively positioned at one sides of the two side molds, the threaded rods are in threaded connection with sliding blocks, driving rods are fixed on the sliding blocks, and one ends of the driving rods, far away from the sliding blocks, are fixed with the side molds; still including the parcel outside the mould shell, the threaded rod rotates to be connected on the shell, slider sliding connection is on the shell, still is fixed with the motor in the shell, rotates to be connected with two drive shafts, all is equipped with the belt between drive shaft and the threaded rod, is fixed with drive bevel gear on the output shaft of motor, all is fixed with the driven bevel gear with the drive bevel gear meshing on the drive shaft. The invention solves the problems that the blank body is tightly adhered to the inner wall of the die after the molding of the existing die is finished and the die is not easy to be demoulded.

Description

Automatic die assembly centering device for manufacturing ceramic pot

Technical Field

The invention belongs to the technical field of equipment for opening and closing a model, and particularly relates to an automatic mold closing and centering device for manufacturing a ceramic pot.

Background

The pottery pot is made of pottery clay through the processes of clay selection, modeling, glazing and sintering, and is often used as a pottery container for containing liquid or food. During the manufacturing process, modeling is a very important ring. During modeling, a ceramic-pot-shaped mold is needed, the raw materials for modeling are put into the mold, and modeling is performed in the mold by using modeling rolling blocks. After the molding is finished, the molded green body is tightly adhered to the mold, and the demolding is not easy to happen.

Disclosure of Invention

The invention aims to provide an automatic mold closing and centering device for manufacturing a ceramic pot, which aims to solve the problems that after the existing mold is molded, a blank body is tightly adhered to the inner wall of the mold and the mold is difficult to demould.

In order to achieve the above purpose, the invention adopts the following technical scheme: the automatic mold closing and centering device for the ceramic pot manufacturing comprises a mold, wherein the mold comprises a bottom mold and two side molds, and further comprises a driving piece for driving the side molds to move, the driving piece comprises two threaded rods which are respectively positioned at one sides of the two side molds, a sliding block is connected to the threaded rods in a threaded manner, a driving rod is fixed on the sliding block, and one end, far away from the sliding block, of the driving rod is fixed with the side molds; still including the parcel outside the mould shell, the threaded rod rotates to be connected on the shell, slider sliding connection is on the shell, still is fixed with the motor in the shell, rotates to be connected with two drive shafts, all is equipped with the belt between drive shaft and the threaded rod, is fixed with drive bevel gear on the output shaft of motor, all is fixed with the driven bevel gear with the drive bevel gear meshing on the drive shaft.

In the technical scheme, the die is arranged to be a bottom die and two side dies can be spliced to be in the shape of the die, so that the ceramic pot can be molded conveniently. The driving piece can drive the side die to move, so that the side die can be separated from a formed blank body after the forming is completed, and the blank body is conveniently taken out. Compared with the prior art, the demolding is convenient.

In a preferred embodiment of the invention, the periphery of the bottom die is provided with a chute, and the side die is provided with a limiting block which can be inserted into the chute.

In a preferred embodiment of the invention, the side mould comprises an outer wrapping layer and a modeling layer positioned on the inner side of the wrapping layer, the inner side of the wrapping layer is provided with a sliding groove, the sliding grooves on the two wrapping layers can be communicated, the outer side of the modeling layer is provided with a sliding block positioned in the sliding groove, and the limiting block is arranged on the modeling layer.

In a preferred embodiment of the invention, the portion of the slider located in the sliding groove is spherical.

In a preferred embodiment of the invention, a rotating shaft is coaxially fixed at the bottom of the bottom die and is rotatably connected to the shell, a driven gear is coaxially arranged on the rotating shaft, a one-way bearing is arranged between the driven gear and the rotating shaft, and a driving gear meshed with the driven gear is fixed on an output shaft of the motor; the drive shaft is also provided with a one-way bearing between the driven bevel gear and the drive shaft.

In another preferred embodiment of the invention, the limiting piece comprises a limiting ring fixed outside the driving shaft, a plurality of limiting teeth are uniformly arranged on the outer ring of the limiting ring, a limiting clamping block which can be inserted between adjacent limiting teeth is vertically and slidably connected at the bottom of the shell, a connecting sleeve and a winding ring which is wrapped outside the connecting sleeve are coaxially arranged on the output shaft of the motor, unidirectional bearings are arranged between the connecting sleeve and the output shaft of the motor and between the connecting sleeve and the winding ring, a pull rope is wound on the winding ring, the bottom of the shell is also transversely and slidably connected with a sliding rod, the bottom of the limiting clamping block is a wedge surface, a spring is arranged between the sliding rod and the side surface of the shell, and one end of the pull rope, which is far away from the winding ring, is fixed with the sliding rod; still including running through the shell and with the vertical sliding connection's of shell footboard, be fixed with the rack on the footboard, still rotate in the shell and be connected with two axis of rotation, the axis of rotation is fixed with the drive gear with rack toothing, all is fixed with first bar magnet in the axis of rotation, one side that the slide bar kept away from mutually all is equipped with the second bar magnet.

In another preferred embodiment of the invention, the drive shaft is sleeved with a torsion spring, one end of which is fixed with the drive shaft and the other end of which is fixed with the housing.

Additional aspects and advantages of the invention will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the invention.

Drawings

The foregoing and/or additional aspects and advantages of the invention will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

fig. 1 is a longitudinal cross-sectional view of an embodiment of the present application.

Fig. 2 is an enlarged view of a portion a in fig. 1.

Reference numerals in the drawings of the specification include: the device comprises a shell 1, a bottom die 2, a wrapping layer 3, a modeling layer 4, a sliding block 5, a limiting block 6, a threaded rod 7, a sliding block 8, a driving rod 9, a driving shaft 10, a motor 11, a driving bevel gear 12, a driven bevel gear 13, a torsion spring 14, a limiting ring 15, limiting teeth 16, a limiting clamping block 17, a connecting sleeve 18, a winding ring 19, a pull rope 20, a sliding rod 21, a first bar magnet 22, a second bar magnet 23, a pedal 24, a transmission gear 25, a rack 26, a rotating shaft 27, a driving gear 28 and a driven gear 29.

Detailed Description

Embodiments of the present invention are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the invention.

In the description of the present invention, it should be understood that the terms "longitudinal," "transverse," "vertical," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," and the like indicate or are based on the orientation or positional relationship shown in the drawings, merely to facilitate description of the invention and to simplify the description, and do not indicate or imply that the devices or elements referred to must have a particular orientation, be configured and operated in a particular orientation, and thus should not be construed as limiting the invention.

In the description of the present invention, unless otherwise specified and defined, it should be noted that the terms "mounted," "connected," and "coupled" are to be construed broadly, and may be, for example, mechanical or electrical, or may be in communication with each other between two elements, directly or indirectly through intermediaries, as would be understood by those skilled in the art, in view of the specific meaning of the terms described above.

The invention provides an automatic mold closing and centering device for manufacturing a ceramic pot, which is shown in fig. 1, and in a preferred embodiment of the invention, the automatic mold closing and centering device comprises a shell 1, a mold wrapped in the shell 1 and a driving piece arranged in the shell 1. The mould comprises a bottom mould 2 and two side moulds. The side mould all includes the parcel layer 3 in the outside and is located the molding layer 4 of parcel layer 3 inboard, and when the mould compound die, the both sides of two parcel layers 3 paste mutually, and the both sides of two molding layers 4 paste mutually.

The inner side of the wrapping layer 3 is provided with sliding grooves, and when the mold is closed, two ends of the two sliding grooves are communicated to form an annular groove. The outside of molding layer 4 all is fixed with slider 5, and slider 5 is located the sliding tray, can realize that molding layer 4 takes place to rotate for parcel layer 3. One end of the sliding block 5 positioned in the sliding groove is spherical, so that the sliding smoothness of the sliding block 5 can be increased. The inner side of the wrapping layer 3 and the outer side of the modeling layer 4 are both provided with magnetic layers, and the two magnetic layers are mutually attracted.

The periphery of die block 2 is provided with the spout, is provided with two spouts in this embodiment, and two spouts are about die block 2's central symmetry. The bottoms of the two modeling layers 4 are provided with limiting blocks 6 matched with the sliding grooves, and when the limiting blocks 6 are inserted into the sliding grooves, the centering and closing of the die can be realized.

The driving piece comprises two threaded rods 7 which are respectively connected to the left and right inner walls of the shell 1 in a rotating mode and a sliding block 8 which is connected to the threaded rods 7 in a threaded mode, the sliding block 8 is connected with the inner side top surface of the shell 1 in a sliding mode in the transverse mode, a driving rod 9 is fixed on one side, close to the side die, of the sliding block 8, and the driving rod 9 is fixed with the side die.

The lower part of the threaded rod 7 in the shell 1 is also rotationally connected with two driving shafts 10, the driving shafts 10 are parallel to the threaded rod 7, and belts are arranged between the two threaded rods 7 and the two driving shafts 10 respectively, so that synchronous rotation of the driving shafts 10 and the threaded rods 7 can be realized.

The bottom of the shell 1 is fixed with a motor 11, an output shaft of the motor 11 is coaxially fixed with a drive bevel gear 12, two opposite ends of the two driving shafts 10 are respectively provided with a driven bevel gear 13 meshed with the drive bevel gear 12, and a one-way bearing is arranged between the driven bevel gear 13 and the driving shafts 10. When the motor 11 rotates positively, the driven bevel gear 13 can drive the driving shaft 10 to rotate, and when the motor 11 rotates reversely, the driving shaft 10 cannot rotate under the action of the unidirectional bearing. The driving shaft 10 is sleeved with a torsion spring 14, one end of the torsion spring 14 is fixed on the driving shaft 10, and the other end is fixed on the shell 1.

The limiting piece comprises a limiting ring 15 fixed outside the driving shaft 10, a plurality of limiting teeth 16 are uniformly arranged on the periphery of the limiting ring 15, and the number of the limiting teeth 16 is selected according to actual requirements. The bottom of the shell 1 is vertically and slidably connected with a limiting clamping block 17, and the limiting clamping block 17 can be inserted between adjacent limiting teeth 16, so that the limiting teeth 16 are clamped, the limiting ring 15 is prevented from rotating, and the driving shaft 10 is prevented from rotating.

The lower side of the middle part of the shell 1 is provided with a groove, the motor 11 is positioned in the groove, and the bottom of the limiting clamping block 17 can also slide into the groove. The output shaft of the motor 11 is also coaxially provided with a connecting sleeve 18 and a winding ring 19 wrapped outside the connecting sleeve 18, a pull rope 20 is wound on the winding ring 19, unidirectional bearings are arranged between the connecting sleeve 18 and the output shaft of the motor 11 and between the connecting sleeve 18 and the winding ring 19, and when the motor 11 rotates positively, the connecting sleeve 18 and the winding ring 19 are driven to rotate synchronously, so that the pull rope 20 is wound; when the motor 11 rotates reversely, the connecting sleeve 18 cannot rotate along with the motor under the action of the one-way bearing, and when the winding ring 19 receives the reverse rotation force, the winding ring 19 can rotate reversely.

The groove is also transversely connected with a sliding rod 21 in a sliding manner, one end of the pull rope 20, which is far away from the winding ring 19, is fixed with the sliding rod 21, a spring is arranged between one side, which is far away from the sliding rod 21, and the groove, and one side, which is opposite to the limiting clamping block 17, is a wedge surface, so that when the sliding rod 21 moves in the opposite direction, the limiting clamping block 17 is driven to move upwards. As shown in fig. 2, the sliding rod 21 is further provided with a second bar magnet 23 on the side away from it. The rear side of the shell 1 is also provided with a vertical bar-shaped groove, a pedal 24 is vertically connected in the bar-shaped groove in a sliding manner, the pedal 24 is positioned outside the shell 1, one end of the pedal 24 positioned in the shell 1 is provided with a rack 26, and the rack 26 and the bottom of the shell 1 are provided with springs. Two rotating shafts are also rotatably connected in the shell 1, the rear ends of the rotating shafts are respectively fixed with a transmission gear 25 meshed with a rack 26, and the front ends of the rotating shafts are fixed with a first bar magnet 22.

The bottom of the bottom die 2 is coaxially fixed with a rotating shaft 27, the rotating shaft 27 is rotatably connected to the housing 1, a driven gear 29 is coaxially arranged on the rotating shaft 27, a one-way bearing is arranged between the driven gear 29 and the rotating shaft 27, and a driving gear 28 meshed with the driven gear 29 is fixed on an output shaft of the motor 11.

The specific implementation process is as follows:

the pedal 24 is stepped on by a worker, the rack 26 is driven to move downwards, and the first bar magnet 22 is driven to rotate by the rotating shaft through the transmission of the transmission gear 25, so that the first bar magnet 22 rotates to the same magnetic pole at one side opposite to the second bar magnet 23, the first bar magnet 22 repels the second bar magnet 23, the sliding rod 21 slides relatively, and therefore the limit clamping block 17 cannot be limited, and the limit clamping block 17 slides downwards.

The motor 11 is started, the motor 11 positively rotates to drive the drive bevel gear 12 to rotate, synchronous rotation of the driving shafts 10 is realized through transmission of the driven bevel gear 13, and rotation directions of the two driving shafts 10 are opposite, and rotation of the two threaded rods 7 in opposite directions is realized through belt transmission, so that the sliding blocks 8 on the threaded rods 7 can relatively move to drive the two side dies to approach each other. When the side die gradually approaches the bottom die 2, a limiting block 6 on the side die can be inserted into a chute at the periphery of the bottom die 2, so that the bottom and the side die are fixed.

In the process, the motor 11 drives the connecting sleeve 18 and the winding ring 19 to synchronously rotate, so that the pull rope 20 is wound.

When the side die is tightly attached to the bottom die 2, automatic centering die assembly is completed, raw materials are put into the die, the modeling rolling block is enabled to rotate, and modeling is completed. At this time, the reverse motor 11 rotates the rotation shaft 27 in the opposite direction to the molding rolling pin by the driving gear 28 and the driven gear 29, and further drives the mold to rotate as a whole, thereby improving the molding effect.

When the motor 11 rotates reversely, under the action of the one-way bearing, the connecting sleeve 18 and the winding ring 19 cannot rotate along with the connecting sleeve, the sliding rod 21 can slide in the opposite direction under the action of the attraction of the spring and the first bar magnet 22 (at the moment, a worker does not tread the pedal 24 any more, and the rotating shaft drives the first bar magnet 22 to rotate reversely), so that the limiting clamping block 17 is extruded, the limiting clamping block 17 slides upwards and is inserted between the adjacent limiting teeth 16, the limitation of the driving shaft 10 is completed, the inversion of the driving shaft 10 is avoided, and the die can be kept in a die clamping state.

After the modeling is completed, the motor 11 is turned off, the worker tramples the pedal 24 again, the first bar magnet 22 repels the second bar magnet 23, the sliding rod 21 slides relatively, the limiting clamping block 17 slides downwards under the action of gravity and withdraws from between the adjacent limiting teeth 16, the driving shaft 10 rotates reversely under the action of the torsion spring 14, the threaded rod 7 rotates reversely, the sliding block 8 drives the side die to move in the opposite direction, and the side die is separated from the molded ceramic pot blank body, so that the molded blank body is convenient to take down.

In the description of the present specification, reference to the terms "preferred implementation," "one embodiment," "some embodiments," "example," "a particular example" or "some examples" and the like means that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, schematic representations of the above terms do not necessarily refer to the same embodiments or examples. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the present invention have been shown and described, it will be understood by those of ordinary skill in the art that: many changes, modifications, substitutions and variations may be made to the embodiments without departing from the spirit and principles of the invention, the scope of which is defined by the claims and their equivalents.

Claims (3)

1. Automatic compound die centering device of gallipot preparation, including mould, its characterized in that: the die comprises a bottom die, two side dies and a driving piece for driving the side dies to move, wherein the driving piece comprises two threaded rods which are respectively positioned at one sides of the two side dies, the threaded rods are in threaded connection with sliding blocks, driving rods are fixed on the sliding blocks, and one ends of the driving rods, which are far away from the sliding blocks, are fixed with the side dies; the device comprises a die, a threaded rod, a motor, a driving bevel gear and a driving bevel gear, wherein the die is arranged on the die;

the periphery of the bottom die is provided with a chute, and the side die is provided with a limiting block which can be inserted into the chute;

the side mold comprises an outer wrapping layer and a modeling layer positioned at the inner side of the wrapping layer, the inner side of the wrapping layer is provided with sliding grooves, the sliding grooves on the two wrapping layers can be communicated, the outer side of the modeling layer is provided with sliding blocks positioned in the sliding grooves, and the limiting block is arranged on the modeling layer; the bottom of the bottom die is coaxially fixed with a rotating shaft, the rotating shaft is rotationally connected to the shell, a driven gear is coaxially arranged on the rotating shaft, a one-way bearing is arranged between the driven gear and the rotating shaft, and a driving gear meshed with the driven gear is fixed on an output shaft of the motor; the device also comprises a limiting piece for preventing the driving shaft from reversing, and a one-way bearing is arranged between the driven bevel gear and the driving shaft;

the limiting piece comprises a limiting ring fixed outside the driving shaft, a plurality of limiting teeth are uniformly arranged on the outer ring of the limiting ring, a limiting clamping block which can be inserted between adjacent limiting teeth is vertically and slidably connected to the bottom of the shell, a connecting sleeve and a winding ring which is wrapped outside the connecting sleeve are coaxially arranged on the output shaft of the motor, unidirectional bearings are arranged between the connecting sleeve and the output shaft of the motor, a pull rope is wound on the winding ring, a sliding rod is also transversely and slidably connected to the bottom of the shell, the bottom of the limiting clamping block is a wedge surface, a spring is arranged between the sliding rod and the side surface of the shell, and one end of the pull rope, far away from the winding ring, is fixed with the sliding rod; still including running through the shell and with the vertical sliding connection's of shell footboard, be fixed with the rack on the footboard, still rotate in the shell and be connected with two axis of rotation, the axis of rotation is fixed with the drive gear with rack toothing, all is fixed with first bar magnet in the axis of rotation, one side that the slide bar kept away from mutually all is equipped with the second bar magnet.

2. The automatic mold closing and centering device for manufacturing the gallipot according to claim 1, wherein: the part of the sliding block in the sliding groove is spherical.

3. The automatic mold closing and centering device for manufacturing the gallipot according to claim 1, wherein: the driving shaft is sleeved with a torsion spring, one end of the torsion spring is fixed with the driving shaft, and the other end of the torsion spring is fixed with the shell.