CN113532072A

CN113532072A - Drying device for ceramic blank making

Info

Publication number: CN113532072A
Application number: CN202110822460.2A
Authority: CN
Inventors: 邹湘科
Original assignee: Liling Xiangke Fireworks Machinery Co ltd
Current assignee: Liling Xinchuangyi Automation Equipment Co ltd
Priority date: 2021-07-21
Filing date: 2021-07-21
Publication date: 2021-10-22
Anticipated expiration: 2041-07-21
Also published as: CN113532072B

Abstract

The invention discloses a drying device for ceramic blank making, which comprises a disc workbench driven by a power device to rotate intermittently, a heating plate, a shell and a heating device, wherein the heating plate is arranged on the disc workbench, has a diameter smaller than that of the disc workbench and rotates along with the disc workbench, the shell is fixed relative to the disc workbench and is arranged on the disc workbench to cover the heating plate, and the heating device is used for providing hot air into the shell; the circle center part of the disc workbench is fixedly provided with a hot air main pipe which is communicated with the heat supply device and is vertically arranged, and the heating disc is provided with a hot air chamber communicated with the hot air main pipe; the bottom parts of the heating plates except the heating plate at the lowest layer are provided with hot air ports communicated with the hot air chamber; and a plaster mold exchange port corresponding to each layer of heating plate is arranged on the side surface of the shell. The invention has the advantages of small occupied area, compact and simple structure, stable production, high efficiency and good green body drying effect.

Description

Drying device for ceramic blank making

Technical Field

The invention belongs to ceramic production equipment, and particularly relates to a drying device for ceramic blank making.

Background

Ceramics are widely used as a living vessel, and the production process comprises the steps of using clay viscous materials, and carrying out the procedures of batching, forming, drying, roasting and the like for firing and forming. At present, the drying device of publicly known domestic ceramics base making, all set up longer length according to the assembly line and guarantee stoving time and effect, body shaping in the gypsum forming die is divided into two kinds of transfer methods with stoving conveying process basically, one kind is that conveyer belt straight line conveyer divides single row, arrange more than biserial and multiseriate, set up conversion equipment between every row, another kind is to adopt sprocket chain oval dish long distance conveyer, no matter which kind of mode all is that the individual layer arranges subaerial, cause area big, transmission distance is long, conveyer belt or chain drive structure are complicated, poor stability, later stage operation maintenance cost is high, gypsum forming die bottom can not be heated and local humidity influences the stoving effect. Therefore, there is a need for a new blank making apparatus that solves the problems of the prior art.

Disclosure of Invention

The invention aims to provide the drying device for ceramic blank making, which has the advantages of small occupied area, high production efficiency and good blank body drying effect.

The technical scheme adopted for realizing the purpose of the invention is as follows:

the invention provides a drying device for ceramic blanks, which comprises a disc workbench driven by a power device to rotate intermittently, at least two layers of heating plates, a shell and a heating device, wherein the heating plates are arranged on the disc workbench, the diameters of the heating plates are smaller than those of the disc workbench, the heating plates rotate along with the disc workbench, the shell is fixed relative to the disc workbench and is arranged on the disc workbench, the shell covers the heating plates, and the heating device provides hot air into the shell; the circle center part of the disc workbench is fixedly provided with a hot air main pipe which is communicated with the heat supply device and is vertically arranged, and the heating disc is provided with a hot air chamber communicated with the hot air main pipe; the bottom parts of the heating plates except the heating plate at the lowest layer are provided with hot air ports communicated with the hot air chamber; a plaster mold exchange port corresponding to each layer of heating disc is arranged on the side surface of the shell; the diameter of the disc worktable is 1.5 to 20 meters.

The hot air chamber of the heating plate is a hollow hot air chamber or an annular hot air chamber.

The heating device is an electric heating dryer, and comprises a fan for providing positive pressure gas, an electric heating element for heating the gas, and a hot air pipe for conveying hot gas, wherein the air outlet of the hot air pipe is coaxial with the hot air main pipe and sleeved in the hot air main pipe, and when the disc workbench rotates, the hot air main pipe can rotate relative to the air outlet of the hot air pipe.

The power device comprises a motor, a speed reducer connected with the motor, and a driving gear connected with the speed reducer, wherein the lower surface of the disc workbench is meshed with the driving gear through a fixed gear ring, and the motor drives the disc workbench, the heating plate and the hot air main pipe to rotate together in a clearance mode.

The part close to the excircle on the disc workbench is provided with fixing stations of the plaster molds in an annular uniform distribution manner, and the fixing stations of the plaster molds are provided with positioning through holes for placing the plaster molds.

The heating plate is provided with a placing station of the plaster molds according to the annular uniform distribution on the rest heating plates except the uppermost layer, and the placing station of each plaster mold is provided with a positioning boss matched and positioned with the concave pit at the bottom of the plaster mold.

The hot air port at the bottom of the heating plate corresponds to the placement station of the plaster mold on the lower heating plate.

The heating plate is fixed on the disc workbench through a supporting component.

Advantageous effects

The invention adopts the disc workbench and the drying device with the multilayer heating plates to solve the problems of large occupied area and poor drying effect in the prior art, adopts the mechanical hand device to complete the procedures of ceramic clay briquetting die loading, wet blank molding, wet blank drying, dry blank discharging and the like by matching with the disc workbench and the heating plates, and has the advantages of greatly reduced occupied area, compact and simple structure, stable production, high efficiency and good blank drying effect.

The technical scheme of the invention is further explained by combining the attached drawings.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Fig. 2 is a top view of the present invention with the housing removed.

Fig. 3 is a cross-sectional view of the present invention.

Fig. 4 is a schematic view of the present invention with the outer shell removed.

Fig. 5 is a schematic view of a six-axis robot of the present invention.

Detailed Description

Referring to fig. 1 to 5, the drying apparatus for ceramic blanks provided by the present invention includes a disc table 1 driven by a power device to rotate intermittently, 6 layers of heating plates 8 (generally 2 to 8 layers of drying plates 8) arranged on the disc table 1 and having a diameter smaller than that of the disc table 1 and rotating with the disc table 1, a casing 6 fixed relative to the disc table 1 and arranged on the disc table 1 to cover the heating plates 8, and a heating device 13 for supplying hot air into the casing 6; a hot air main pipe 14 which is communicated with the heat supply device 13 and is vertically arranged is fixedly arranged at the circle center part of the disc workbench 1, and the heating disc 8 is provided with a hot air chamber communicated with the hot air main pipe 14; the bottom parts of the heating plates 8 except the heating plate 8 at the lowest layer are provided with hot air ports 804 communicated with the hot air chamber; the side of the shell 6 is provided with a plaster mold exchange port 601 corresponding to each layer of heating plate 8, the lower side of the shell 6 is provided with a plurality of supporting legs 602 which span the periphery of the disc workbench 1 and are fixedly arranged on the ground (see fig. 3), and the diameter of the disc workbench 1 is 1.5-20 meters, generally 2-5 meters.

Referring to fig. 2 and 3, the hot air chamber 802 is of an annular structure and is communicated with the hot air main pipe 14 through a hot air connecting pipe 803.

The hot air chamber 802 may also be a hollow structure and directly connected to the main hot air pipe 14, and a partition may be disposed in the hot air chamber to divide the hot air chamber into a plurality of sectors.

Referring to fig. 3, the heating device is an electric heating dryer 13, and includes a blower for providing positive pressure gas, an electric heating element for heating the gas, and a hot air duct 1301 for conveying hot gas, and an air outlet 1302 of the hot air duct 1301 is coaxial with the hot air main pipe 14 and is sleeved in the hot air main pipe 14. When the disc table 1 rotates, the hot air main pipe 14 can rotate relative to the air outlet 1302 of the hot air pipe 1301.

The part close to the excircle on the disc workbench 1 is provided with fixing stations of the plaster molds 7 in an annular uniform distribution manner, and the fixing stations of the plaster molds 7 are provided with positioning through holes 101 for placing the plaster molds 7.

Except the uppermost layer, the rest heating plates 8 are uniformly distributed with placing stations of the plaster molds 7 in an annular shape, and the placing station of each plaster mold 7 is provided with a positioning boss 801 matched and positioned with a pit at the bottom of the plaster mold 7.

The hot air port 804 at the bottom of the heating plate 8 corresponds to the placement station of the plaster mold 7 on the lower heating plate 8.

The heating plate 8 is fixed on the disc table 1 through a support member 12.

The power device comprises a motor 11 installed on the machine base 10, a speed reducer connected with the motor 11 and a driving gear 1101 connected with the speed reducer, wherein the lower surface of the disc workbench 1 is meshed with the driving gear 1101 through a fixed gear ring 1102, and the motor 11 drives the disc workbench 1, the heating plate 8 and the hot air main pipe 14 to rotate together in a clearance mode through the driving gear 1101.

A ceramic blank making device adopting the drying device, as shown in fig. 1-5, comprises an automatic mud feeder 5 arranged beside a disc worktable 1 of the drying device in sequence, a lifting rotating mechanism 202 arranged below the disc worktable 1 and corresponding to a positioning through hole 101 for placing a plaster mold 7 on the disc worktable 1, a rotary blank rolling forming machine 2 arranged above the disc worktable 1 and corresponding to the positioning through hole 101 for placing the plaster mold 7 on the disc worktable 1, a blank taking manipulator 4 for taking out a dry blank 702 in the plaster mold 7 in the positioning through hole 101 of the disc worktable 1, and a plaster mold exchanging manipulator device arranged between the rotary blank rolling forming machine 2 and the blank taking manipulator 4 for exchanging the plaster mold on the disc worktable and the plaster mold on each drying disc; the plaster mold exchanging manipulator device adopts the existing six-axis manipulator 3 and comprises a clamping jaw assembly which can rotate and is composed of a first clamping jaw 301 and a second clamping jaw 302 which are symmetrical; the automatic mud feeder 5, the lifting and rotating mechanism 202, the rotary blank rolling forming machine 2 and the blank taking manipulator 4 adopt the known technology in the field.

Referring to fig. 1-5, when the ceramic blank making equipment works, the power device drives the disc worktable 1, the heating plate 8 and the hot air main pipe 14 to rotate intermittently, the plaster mold 7 is placed in the positioning through hole 101 on the fixed station of the plaster mold 7, and meanwhile, hot gas provided by the electric heating dryer 13 enters the hot air main pipe 14 of the drying device through the hot air pipe 1301 and is distributed to the heating plate 8 of each layer through the hot air main pipe 14. When the disc workbench 1 stops rotating, the automatic mud feeding machine 5 cuts the wet porcelain clay 9 into a section of porcelain clay clusters 901 for blank making by a proper amount, the porcelain clay clusters are conveyed by the mud feeding mechanical arm 501 and are fed into the gypsum mold 7, the disc workbench 1 rotates anticlockwise to transfer the gypsum mold 7 containing the porcelain clay clusters 901 to a corresponding station below the rotary blank rolling forming machine 2 to stop rotating, the lifting rotating mechanism 202 arranged below the disc workbench 1 jacks up and supports the gypsum mold 7 to rotate, then the rolling molds 201 of the rotary blank rolling forming machine 2 stretch into the porcelain clay clusters 901 in the gypsum mold 7 to rotate, and the porcelain clay clusters 901 are rolled and formed into the ceramic ware wet blank 701. And then, the gypsum mold exchanging manipulator device starts exchanging work, and before the exchanging work, the heating plates 8 of all layers are fully distributed with the empty gypsum molds 7. The second clamping jaw 302 of the clamping jaw assembly of the six-axis manipulator 3 clamps a plaster mold 7 containing a wet blank 701 on the disc workbench 1 and moves upwards and rotates 180 degrees to the horizontal position of the first layer heating plate 8, the first clamping jaw 301 clamps the plaster mold 7 empty above the heating plate 8 from the plaster mold exchange port 601 of the shell 6, and the clamping jaw assembly rotates 180 degrees again; the second clamping jaw 302 sends the plaster mold 7 containing the wet blank 701 to the placing station of the plaster mold 7 which is just vacated by the heating plate 8, so that the bottom of the plaster mold 7 is sleeved on the positioning boss 801 to prevent rotation, throwing and displacement, and then the first clamping jaw 301 of the six-axis manipulator 3 descends to the disc workbench 1 by clamping the empty plaster mold 7 to place the empty plaster mold 7 in the positioning through hole 101 on the fixing station of the plaster mold 7 vacated by the disc workbench 1 to complete the primary plaster mold exchanging process. The disc workbench 1 continues to rotate a fixed station of the plaster mold 7, and the six-shaft mechanical arm 3 finishes the next transfer of the plaster mold 7 containing the wet blank 701 on the disc workbench 1 to the first layer heating plate 8 until all the plaster molds are exchanged. After the heating plate 8 of the first layer is exchanged to finish the plaster mold 7 containing the wet blank 701, the six-shaft mechanical arm 3 starts to exchange the plaster mold 7 containing the wet blank 701 to the heating plate 8 of the second layer, and the circulation is carried out until the heating plates 8 of the layers are exchanged to finish the plaster mold 7 containing the wet blank 701. After the heating plate 8 is placed on the gypsum mold 7 containing the wet blank 701, because be full of hot gas in the heating plate 8, on the one hand the heating plate 8 heats the gypsum mold 7 bottom containing the wet blank 701, on the other hand the hot gas blows the gypsum mold 7 containing the wet blank 701 on the lower heating plate 8 from the hot blast hole 804 of heating plate 8 bottom, and the gypsum mold 7 is heated simultaneously from top to bottom like this for the wet blank 701 is dried more fast, and the thermal efficiency is higher, and is more energy-conserving. After the wet blank 701 in the housing 6 is dried into a dry blank 702, the dry blank 702 in the housing 6 is transferred to the disc worktable 1 by the six-axis manipulator 3, and the working process is as follows: the second clamping jaw 302 of the clamping jaw assembly of the six-axis manipulator 3 clamps a gypsum mold 7 containing a wet blank 701 on the disc workbench 1, the gypsum mold 7 moves upwards and rotates 180 degrees to the horizontal position of the first layer heating plate 8, the first clamping jaw 301 clamps the heating plate 8 from the gypsum mold exchange port 601 of the shell 6, the gypsum mold 7 containing a dry blank 702 is dried, the clamping jaw assembly rotates 180 degrees again, the second clamping jaw 302 sends the gypsum mold 7 containing the wet blank 701 to the placing station just vacated by the heating plate 8, the bottom of the gypsum mold 7 is sleeved on the positioning boss 801 to prevent rotation, throwing and displacement, then the first clamping jaw 301 of the six-axis manipulator 3 clamps the gypsum mold 7 containing the dry blank 702 to move downwards to the disc workbench 1, the gypsum mold 7 containing the dry blank 702 is placed in the fixing station vacated by the disc workbench 1, and the disc workbench 1 continues to rotate a fixing station of the gypsum mold 7 to circularly exchange the gypsum mold 7. When the gypsum mold 7 containing the dry blank 702 rotates to the position below the blank taking mechanical arm 4 along with the disc workbench 1, the blank taking mechanical arm 4 takes out the dry blank 702 in the gypsum mold 7. After the dry blank 702 is taken out, the empty gypsum mold 7 rotates to the automatic mud feeder 5 along with the disc workbench 1 to receive the porcelain clay lumps 9. The six-axis robot 3 sequentially exchanges the plaster mold 7 containing the dry blank 702 on the first-layer heating pan 8 with the plaster mold 7 containing the wet blank 701 on the disc table 1. And then the plaster molds 7 containing the dry blanks 702 of the heating plates 8 of all the layers are exchanged with the plaster molds 7 containing the wet blanks 701 on the disc worktable 1 upwards in sequence to finish an exchange period, and then the circulation of the next period is carried out.

The gypsum mold exchange manipulator device can also adopt other existing manipulator devices with multidimensional movement, the manipulator devices can adopt the clamping jaw assembly consisting of two clamping jaws, and can also adopt a mode of a single clamping jaw and a transfer platform, and the single clamping jaw can put the gypsum molds 7 filled with wet blanks 701 onto the heating plate 8 from the disc workbench 1 one by one; when exchanging the dry blank 702 and the wet blank 701, the plaster mold 7 containing the dry blank 702 is taken out and placed on the transfer platform, then the plaster mold 7 containing the wet blank 701 on the disc worktable 1 is placed on the heating plate 8, and then the plaster mold 7 containing the dry blank 702 on the transfer platform is placed on the disc worktable 1.

The heat supply device 13 may also adopt a kiln, and the waste heat of the kiln is transferred to the hot air main pipe 14 through a special hot air pipeline to provide hot air.

Claims

1. A drying device for ceramic blank making comprises a disc workbench which is rotatably arranged on a machine base and driven by a power device to rotate intermittently, at least two layers of heating plates which are arranged on the disc workbench and have the diameter smaller than that of the disc workbench and rotate along with the disc workbench, a shell which is fixed relative to the disc workbench and is arranged on the disc workbench and covers the heating plates, and a heat supply device for supplying hot air into the shell; the circle center part of the disc workbench is fixedly provided with a hot air main pipe which is communicated with the heat supply device and is vertically arranged, and the heating disc is provided with a hot air chamber communicated with the hot air main pipe; the bottom parts of the heating plates except the heating plate at the lowest layer are provided with hot air ports communicated with the hot air chamber; a plaster mold exchange port corresponding to each layer of heating disc is arranged on the side surface of the shell; the diameter of the disc worktable is 1.5 to 20 meters.

2. The drying apparatus for ceramic blanks as recited in claim 1, wherein said hot-air chamber of said heating plate is a hollow hot-air chamber or a ring-shaped hot-air chamber.

3. The drying apparatus according to claim 1 or 2, wherein the heating apparatus is an electric heating dryer, and comprises a blower for supplying positive pressure gas, an electric heating element for heating the gas, and a hot air duct for transporting hot gas, wherein an air outlet of the hot air duct is coaxial with the hot air main duct and is sleeved in the hot air main duct, and when the disc table rotates, the hot air main duct can rotate relative to the air outlet of the hot air duct.

4. The drying device for the ceramic blanks as recited in claim 3, wherein the power device comprises a motor, a speed reducer connected with the motor, and a driving gear connected with the speed reducer, the lower surface of the disc worktable is engaged with the driving gear through a fixed gear ring, and the motor drives the disc worktable, the heating plate and the hot air main pipe to rotate together at intervals through the driving gear.

5. The drying apparatus for ceramic blanks as recited in claim 1, wherein fixing stations for placing the plaster molds are uniformly arranged on the outer circumference of the disc table in a ring shape, and the fixing stations for placing the plaster molds are provided with positioning through holes.

6. The drying apparatus for ceramic blanks as recited in claim 1, wherein said heating plates are provided with a plurality of gypsum mold placing stations distributed uniformly in a ring shape except for the uppermost heating plate, and each gypsum mold placing station is provided with a positioning boss positioned in cooperation with a concave pit at the bottom of the gypsum mold.

7. The drying apparatus for ceramic blanks as recited in claim 6, wherein said hot air port at the bottom of said heating plate corresponds to a placement station of a plaster mold on the lower heating plate.

8. The drying apparatus for ceramic preforms according to claim 1, wherein the heating plate is fixed to the disc table by a support member.