CN109304804B

CN109304804B - Automatic slip casting device for ceramic blank

Info

Publication number: CN109304804B
Application number: CN201811489025.7A
Authority: CN
Inventors: 陈少志
Original assignee: Guangdong Yixiou Sanitary Ware Co ltd
Current assignee: Guangdong Yixiou Sanitary Ware Co ltd
Priority date: 2018-12-06
Filing date: 2018-12-06
Publication date: 2024-05-07
Anticipated expiration: 2038-12-06
Also published as: CN109304804A

Abstract

The invention relates to an automatic grouting forming device for ceramic blanks, which comprises a main frame, and an upper die station, a grouting station, a pouring station and a demolding station which are arranged on the main frame, wherein the upper die station is arranged on the main frame; the main frame comprises a base and a rotating frame, and the rotating frame is assembled on the base in a fixed-axis rotating manner; the periphery of the rotating frame is provided with a plurality of die carrying tables for carrying dies, the die carrying tables are assembled on the rotating frame in a fixed shaft rotating way through a driving shaft, the rotating frame is provided with a driving mechanism for the rotation of the driving shaft, and the die carrying tables are provided with die pressing plates for limiting the dies in a pressing way; and assembling the mould on the mould loading station to the mould loading station, grouting the mould on the mould loading station on the grouting station, pouring out the redundant slurry in the mould at the grouting station, and unloading the mould for loading the blank body at the mould unloading station. The forming device can automatically and intelligently complete the working procedures of mould feeding, grouting, pouring and mould stripping, can obtain more standardized ceramic blanks, and has high production efficiency.

Description

Automatic slip casting device for ceramic blank

Technical Field

The invention relates to the field of ceramic body preparation, in particular to an automatic slip casting device for ceramic bodies.

Background

At present, the preparation of ceramic blanks is mostly to inject slurry into a gypsum mold with a required cavity, guide out surplus slurry after the gypsum mold absorbs water of the slurry contacted with the gypsum mold to solidify, so as to form the required blanks on the inner wall of the cavity, and then to demold and take out the blanks after the blanks are completely solidified. The existing grouting process is realized by manual operation, however, when mass production is carried out manually, the timely grouting treatment is difficult to carry out according to the grouting sequence, and the grouting time is controlled only through manual experience, so that the thickness of the manufactured blank is uneven, standardized production cannot be carried out, the production efficiency is low, the rejection rate is high, and the production cost is high.

Disclosure of Invention

The invention provides an automatic slip casting device for ceramic blanks, which aims to solve the problems that the conventional ceramic blank preparation cannot be produced in a standardized way, the thickness of the blank is uneven, the production efficiency is low and the like.

The invention adopts the following technical scheme:

The ceramic body automatic grouting forming device comprises a main frame, and an upper die station, a grouting station, a slurry pouring station and a die stripping station which are arranged on the main frame; the main frame comprises a base and a rotating frame, and the rotating frame is assembled on the base in a fixed-axis rotating manner; the periphery of the rotating frame is provided with a plurality of die carrying tables for carrying dies, the die carrying tables are assembled on the rotating frame in a fixed shaft rotating way through driving shafts, the rotating frame is provided with a driving mechanism for the driving shafts to rotate, and the die carrying tables are provided with die pressing plates for limiting the dies in a pressing way. The molds are assembled onto a carrier at the upper mold station, which is provided with an input conveyor belt for supplying empty molds to the carrier. When the mould on the mould carrying platform is injected on the grouting station, the main frame is provided with an automatic grouting mechanism, the automatic grouting mechanism comprises a detector, a main grouting pipe and a grouting pipe, slurry is pumped from the slurry barrel to the main grouting pipe by a pump, then is injected into the corresponding mould by the grouting pipe, the grouting pipe is provided with a valve, the valve drives the rotation direction and the rotation angle of the valve to control the opening and closing of the valve by a grouting motor, the valve and the opening and closing motor can also be arranged on the main grouting pipe, the detector is used for detecting that the grouting motor is started to perform grouting when the mould carrying platform rotates to a set position, and the grouting motor is closed in a delayed mode or is triggered to close the valve according to the output flow to the set value. And pouring out the surplus slurry in the mould at the slurry pouring station, wherein the slurry pouring station is provided with a slurry receiving groove, and the slurry receiving groove is arranged right below the mould carrying table and is used for receiving and collecting the slurry. And unloading the die for carrying the blank at the demolding station, wherein the demolding station is provided with an output conveyer belt for receiving the die output by the die carrying platform.

The driving mechanism is preferably configured in two configurations:

The first, the driving mechanism includes driving motor and reduction gearbox, the driving motor drives the above-mentioned drive shaft to rotate through the reduction gearbox; each of the above-mentioned mold carrying tables is independently provided with the driving mechanism. Each of the above-mentioned carrying mold platforms is equipped with an infrared thickness measurer for detecting the dry thickness of the slurry in the mold, and when the dry thickness of the slurry reaches a set value, the above-mentioned driving motor drives the above-mentioned carrying mold platform to make rotary slurry pouring action.

The second driving mechanism comprises a driving wheel, a limiting wheel and a guide rail, wherein the driving wheel is fixedly assembled on the driving shaft, the limiting wheel is coaxially assembled on the eccentric position of the driving wheel, the guide rail is fixedly assembled on the main frame, and the limiting wheel is limited to slide along with the extension of the guide rail; the guide rail of the slurry pouring station is provided with at least one crest section and at least one trough section, and the guide rails of other stations extend along the horizontal direction.

The die carrying table comprises a table frame and a die carrying conveying belt assembled on the table frame, the die is carried on the die carrying conveying belt, the conveying direction of the die carrying conveying belt and the axial direction of the driving shaft are arranged in the same direction, and the die pressing plate is assembled on the table frame in a lifting manner. The die plate is fixedly provided with at least two lifting rods, the lifting rods are distributed on two sides of the width direction of the die carrying conveyor belt, the table frame is fixedly provided with limiting cylinders corresponding to the lifting rods one by one, and the lower ends of the lifting rods penetrate through the limiting cylinders; the lifting rod is sleeved with a limiting seat and a pressure spring, the limiting seat is arranged above the limiting cylinder in a lifting and adjusting mode, and the pressure spring is clamped between the limiting cylinder and the bottom end of the lifting rod. In addition, the die plate is of a diversion trench structure with an upward opening, the extending direction of the diversion trench is axially and vertically distributed with the driving shaft, and a grouting hole matched with the die is formed in the bottom of the diversion trench. The structure setting of this pressure template makes thick liquids can be by drainage, water conservancy diversion to connect in the thick liquids groove when deriving, and thick liquids pollution carrier die platform and main frame etc. when avoiding the back pulp guarantee the clean and tidy nature and the stability of equipment operation.

The upper die station and the demolding station are respectively provided with a driving platform, wherein the driving platform comprises a lifting platform and a lifting driving device, and the lifting driving device is used for driving the lifting platform to perform lifting action of setting travel; the lifting platform is provided with at least one driving roller, when the lifting platform is lifted to be abutted against the carrying platform, the lifting platform upwards pushes the bottom end of the lifting rod to lift the carrying platform, the driving roller drives the carrying conveying belt to carry out conveying motion in a set direction, and the bottom end of the lifting rod is lower than the bottom surface of the carrying conveying belt, namely the lifting platform firstly lifts the lifting rod and then drives the carrying conveying belt to operate.

A hot air drying box is arranged between the grouting station and the demolding station, is fixedly assembled on the base or the ground and carries out hot air drying treatment on the passing mold carrying platform.

The top surface of the base is provided with a circular guide rail, the bottom of the rotating frame is provided with a plurality of pulleys, the pulleys directionally slide along the guide rail, and the base is provided with a hydraulic motor for driving the rotating frame to rotate.

As can be seen from the above description of the structure of the present invention, compared with the prior art, the present invention has the following advantages: the automatic grouting forming device can automatically and intelligently complete the working procedures of mould feeding, grouting, pouring and mould stripping of the mould, and can produce more standardized ceramic blanks, and has the advantages of high production efficiency, low defective rate, simple structure and effectively reduced production cost.

The grouting time of the carrying die table can be monitored in real time through the configuration of the infrared thickness measurer, and the grouting treatment can be timely carried out in a designated area by combining the rotation speed of the rotating frame and the matching of the driving motor of the carrying die table, so that the thickness of a blank body can be effectively controlled, and standardized production is realized.

The structure setting of this pressure template makes thick liquids can be by drainage, water conservancy diversion to connect in the thick liquids groove when deriving, and thick liquids pollution carrier die platform and main frame etc. when avoiding the back pulp guarantee the clean and tidy nature and the stability of equipment operation.

The configuration of the driving platform can effectively simplify the configuration of a driving power source of a carrier conveying belt of the carrier platform, reduce the weight of the carrier platform and occupied space, further reduce the bearing load of a driving shaft and prolong the service life of the driving shaft; and the operation process of the driving platform also synchronously carries out lifting action on the pressing die plate.

The die mechanism composed of the limiting seat, the lifting rod and the pressure spring is arranged, so that the lowest descending position of the die plate can be adaptively set according to various die sizes, the pressing pressure of the die plate to the die can be effectively selected, the structure is quite simple, and the production cost is low.

Drawings

Fig. 1 is a schematic plan view and a partial enlarged view of a molding apparatus according to the first embodiment.

Fig. 2 is a schematic perspective view of a driving stage and a mold carrying stage according to the present invention.

Fig. 3 is a schematic structural view of an automatic pressing structure of a lifter according to the present invention.

Fig. 4 is a schematic plan view and a partial enlarged view of a molding apparatus according to the second embodiment.

Fig. 5 is a schematic diagram of a movement track of the driving wheel at the slurry pouring station according to the second embodiment.

Detailed Description

Specific embodiments of the present invention will be described below with reference to the accompanying drawings.

Embodiment one

Referring to fig. 1,2 and 3, the present embodiment relates to an automatic grouting forming device for ceramic green bodies, which comprises a main frame 1, and an upper mold station a, a grouting station B, a pouring station C and a demolding station D which are arranged on the main frame 1; the main frame 1 includes a base 11 and a rotating frame 12, and the rotating frame 12 is mounted on the base 11 so as to rotate about a fixed axis; the top surface of the base 11 is provided with a circular guide rail 111, the bottom of the rotating frame 12 is provided with a plurality of pulleys 121, the pulleys 121 directionally slide along the guide rail 111, and the base 11 is provided with a hydraulic motor for driving the rotating frame 12 to rotate. The rotary frame 12 has ten die-carrying tables 13 for carrying dies on the peripheral surface thereof, the die-carrying tables 13 are mounted on the rotary frame 12 so as to be pivotable by a drive shaft 131, the rotary frame 12 is provided with a drive mechanism 14 for pivoting the drive shaft 131, and the die-carrying tables 13 are provided with a die plate 15 for limiting the pressing of the dies. The molds are assembled onto the mold stage 13 at the upper mold station a, which is provided with an input conveyor 16 for supplying the empty molds to the mold stage 13. When the mould on the carrying platform 13 is grouted at the grouting station B, the main frame 1 is provided with an automatic grouting mechanism 2, the automatic grouting mechanism 2 comprises a detector, a main grouting pipe 21 and a grouting pipe 22, slurry is pumped from a slurry barrel to the main grouting pipe 21 by a pump, then is injected into a corresponding mould by the grouting pipe 22, the grouting pipe 22 is provided with a valve, the valve is driven by a grouting motor 23 to control the opening and closing of the valve through the rotating direction and the rotating angle of the valve, the valve and the opening and closing motor can be also arranged on the main grouting pipe 21, the detector is used for detecting that the grouting motor 23 is started to perform grouting when the carrying platform 13 rotates to a set position, and the grouting motor 23 is closed in a delayed mode or the valve is triggered to be closed according to the output flow to the set value. Excess slurry in the mold is poured out at the slurry pouring station C, the slurry pouring station C is provided with a slurry receiving groove 17, the slurry receiving groove 17 is arranged right below the mold carrying table 13, and the slurry receiving groove 17 receives and collects the slurry. The die for placing the green body is removed at the die-stripping station D, and the die-stripping station D is provided with an output conveyor 18 for receiving the die output from the die-placing table 13.

With continued reference to fig. 1, the driving mechanism 14 includes a driving motor 141 and a reduction gearbox 142, and the driving motor 141 drives the driving shaft 131 to rotate through the reduction gearbox 142; the driving mechanism 14 is independently disposed on each of the die carriers 13. Each of the above-mentioned mold carriers 13 is provided with an infrared thickness measuring device for detecting the dry thickness of the slurry in the mold, which is a measuring device conventionally used in the market, such as Kurabo infrared thickness measuring device supplied by Kurabo international trade company, as above. When the thickness of the slurry in the adjacent mold reaches a set value, the driving motor 141 drives the mold stage 13 to perform a rotary slurry pouring operation. The grouting time of the carrying die table 13 can be monitored in real time through the configuration of the infrared thickness measurer, and grouting treatment can be timely carried out in a designated area by combining the rotation speed of the rotating frame 12 and the matching of the driving motor 141 of the carrying die table 13, so that the thickness of a blank body can be effectively controlled, and standardized production is realized.

With continued reference to fig. 1 and 2, the die carrier 13 includes a frame 132 and a die carrier belt 133 mounted on the frame 132, the die is carried on the die carrier belt 133, the direction of conveyance of the die carrier belt 133 is in the same direction as the axial direction of the drive shaft 131, and the die plate 15 is mounted on the frame 132 so as to be movable up and down. With continued reference to fig. 1 to 3, the pressing plate 15 is fixedly provided with two lifting rods 134, the two lifting rods 134 are distributed on two sides of the width direction of the carrier belt 133, the table frame 132 is fixedly provided with limiting cylinders 135 corresponding to the lifting rods 134 one by one, and the lower ends of the lifting rods 134 penetrate through the limiting cylinders 135; the lifting rod 134 is sleeved with the limiting seat 136 and the pressure spring 137, the limiting seat 136 is provided with the locking bolt 138, when the locking bolt 138 pushes against the lifting rod 134, the limiting seat 136 is locked, the limiting seat 136 is arranged above the limiting cylinder 135 in a lifting and adjusting mode, the lowest descending position of the die plate 15 can be adaptively set according to various die sizes through the configuration of the limiting seat 136, the pressing pressure of the die plate 15 to the die can be effectively selected, the structure is quite simple, and the production cost is low. The compression spring 137 is sandwiched between the limiting cylinder 135 and the bottom end of the lifting rod 134. In addition, with continued reference to fig. 1 to 3, the pressing plate 15 has a structure of a guide groove with an upward opening, the extending direction of the guide groove is perpendicular to the axial direction of the driving shaft 131, and the bottom of the guide groove is provided with a grouting hole 150 matching with the mold. The structural arrangement of the pressing die plate 15 enables slurry to be guided and guided into the slurry receiving groove 17 during guiding out, avoids slurry from polluting the mold carrying table 13, the main frame 1 and the like during slurry pouring, and ensures the cleanliness and stability of equipment operation.

With continued reference to fig. 2, the upper die station a and the demolding station D are respectively provided with a driving table 3, the driving table 3 includes a lifting table 31 and a lifting driving device 32, and the lifting driving device 32 is used for driving the lifting table 31 to perform a lifting operation with a set stroke; the lift driving device 32 is preferably a cylinder driving device, and as shown in fig. 2, a set of synchronous lift driving devices 32 are respectively arranged at two ends of the lift table 31 to drive the lift table to stably lift. The elevating table 31 is equipped with three driving rollers 311 and a motor 312 for driving the driving rollers 311 to operate. When the lifting table 31 is lifted to be in contact with the die carrying table 13, the lifting table 31 pushes up the bottom end of the lifting rod 134 to lift the die carrying table, the driving roller 311 drives the die carrying conveyor belt 133 to carry in a set direction, and the bottom end of the lifting rod 134 is lower than the bottom surface of the die carrying conveyor belt 133, that is, the lifting table 31 lifts the lifting rod 134 first and then drives the die carrying conveyor belt 133 to move. The configuration of the driving platform 3 can effectively simplify the configuration of the driving power source of the carrier conveying belt 133 of the carrier platform 13, reduce the weight and occupied space of the carrier platform 13, further reduce the bearing load of the driving shaft 131 and prolong the service life of the driving shaft 131; and the operation of the driving table 3 also synchronously carries out lifting action on the pressing plate 15.

With continued reference to fig. 1, a hot air drying box 4 is disposed between the grouting station B and the demolding station D, and the hot air drying box 4 is fixedly mounted on the base 11 or the ground and performs a hot air drying process on the passing mold carrying table 13. The hot air drying box 4 can be started to assist drying for the die with slower slurry drying speed in the die, and the hot air drying box 4 can be stopped for the die with faster slurry drying speed.

Second embodiment

The ceramic body automatic slip casting device of the present embodiment differs from the automatic slip casting device of the first embodiment in that: referring to fig. 4 and 5, the driving mechanism 14 adopted in the present embodiment is a simple manner with low cost, the driving mechanism 14 in the present embodiment includes a driving wheel 143, a limiting wheel 144 and a guiding rail 145, the driving wheel 143 is fixedly assembled on the driving shaft 131, the limiting wheel 144 is coaxially assembled on an eccentric position of the driving wheel 143, the guiding rail 145 is fixedly assembled on the main frame 1, the guiding rail 145 is preferably in an upper and lower parallel arrangement structure, the limiting wheel 144 is assembled between the two guiding rails 145, and the limiting wheel 144 is limited to slide along with the extension of the guiding rail 145; the guide rail 145 of the pouring station C has at least one crest section 146 and at least one trough section 147, and the rotation angle of the die carrier 13 is changed when the limit wheel 144 passes through the crest section 146 and the trough section 147 as shown in fig. 5 (arrow v indicates the moving direction of the rotating frame 12, and arrow r indicates the rotating direction of the driving wheel 143), so that 360 ° clockwise rotation of the driving shaft 131 is achieved. The guide rails 145 of the other stations extend in the horizontal direction, that is, the mold carrying tables 13 are kept in the vertically upward state. The molding device of the present embodiment has relatively fixed time for the upper mold, grouting, pouring and demolding steps of each mold carrier 13, and can realize the automatic grouting step as well, and has a simple structure and greatly reduced production cost compared with the first embodiment.

The foregoing is merely illustrative of specific embodiments of the present invention, but the design concept of the present invention is not limited thereto, and any insubstantial modification of the present invention by using the design concept shall fall within the scope of the present invention.

Claims

1. The ceramic body automatic grouting forming device comprises a main frame, and an upper die station, a grouting station, a slurry pouring station and a die stripping station which are arranged on the main frame; the method is characterized in that: the main frame comprises a base and a rotating frame, and the rotating frame is assembled on the base in a fixed-axis rotating manner; the periphery of the rotating frame is provided with a plurality of die carrying tables for carrying dies, the die carrying tables are assembled on the rotating frame in a fixed shaft rotating way through a driving shaft, the rotating frame is provided with a driving mechanism for the rotation of the driving shaft, and the die carrying tables are provided with die pressing plates for limiting the dies in a pressing way; the mould is assembled to the mould carrying platform at the mould feeding station, the mould on the mould carrying platform is injected at the grouting station, the superfluous slurry in the mould is poured out at the slurry pouring station, and the mould carrying the blank body is detached at the mould unloading station;

The driving mechanism comprises a driving wheel, a limiting wheel and a guide rail, wherein the driving wheel is fixedly assembled on the driving shaft, the limiting wheel is coaxially assembled on the eccentric position of the driving wheel, the guide rail is fixedly assembled on the main frame, and the limiting wheel is limited to slide along with the extension of the guide rail; the guide rail of the slurry pouring station is provided with at least one crest section and at least one trough section, and the guide rails of other stations extend along the horizontal direction;

The die carrying table comprises a table frame and a die carrying conveying belt assembled on the table frame, a die is carried on the die carrying conveying belt, the conveying direction of the die carrying conveying belt and the axial direction of the driving shaft are arranged in the same direction, and the die pressing plate is assembled on the table frame in a lifting manner;

The pressing die plate is of a diversion trench structure with an upward opening, the extending direction of the diversion trench is axially and vertically distributed with the driving shaft, and the bottom of the diversion trench is provided with a grouting hole matched with the die;

the die plate is fixedly provided with at least two lifting rods, the lifting rods are distributed on two sides of the carrier die in the direction of the conveying belt width, the table frame is fixedly provided with limiting cylinders corresponding to the lifting rods one by one, and the lower ends of the lifting rods penetrate through the limiting cylinders; the lifting rod is sleeved with a limiting seat and a pressure spring, the limiting seat is arranged above the limiting cylinder in a lifting and adjusting manner, and the pressure spring is clamped between the limiting cylinder and the bottom end of the lifting rod;

The upper die station and the demolding station are respectively provided with a driving platform, wherein the driving platform comprises a lifting platform and a lifting driving device, and the lifting driving device is used for driving the lifting platform to perform lifting action of setting travel; the lifting platform is provided with at least one driving roller, when the lifting platform is lifted to be abutted against the carrier module platform, the lifting platform upwards lifts the lifting rod, and the driving roller drives the carrier module conveying belt to perform conveying motion in a set direction.

2. The automatic slip casting device for ceramic green bodies according to claim 1, wherein: the driving mechanism comprises a driving motor and a reduction gearbox, and the driving motor drives the driving shaft to rotate through the reduction gearbox; each die carrying platform is independently provided with the driving mechanism.

3. The automatic slip casting device for ceramic green bodies according to claim 2, wherein: each carrying die platform is provided with an infrared thickness measurer for detecting the dry thickness of the slurry in the die, and when the dry thickness of the slurry reaches a set value, the driving motor drives the carrying die platform to perform rotary slurry pouring.

4. The automatic slip casting device for ceramic green bodies according to claim 1, wherein: a hot air drying box is arranged between the grouting station and the demolding station, and is fixedly assembled on the base and used for carrying out hot air drying treatment on the passing mold carrying table.

5. The automatic slip casting device for ceramic green bodies according to claim 1, wherein: the top surface of the base is provided with a guide rail which is in a circular ring shape, the bottom of the rotating frame is provided with a plurality of pulleys, the pulleys directionally slide along the guide rail, and the base is provided with a hydraulic motor for driving the rotating frame to rotate.