CN210732771U - Mould drying and blank removing machine capable of recovering waste heat of kiln - Google Patents

Abstract

The utility model relates to a domestic ceramics production facility field, concretely relates to mould stoving knockout machine of recoverable kiln waste heat, adsorb transfer device and body conveyor including drying furnace, mould conveyer, mould separator, mould positioner, body to and the control method that the mould stoving knockout machine of utilizing recoverable kiln waste heat carries out the body stoving drawing of patterns. The utility model provides a mould stoving of recoverable kiln waste heat takes off base machine has following beneficial effect: 1. the waste heat of the kiln is used for heating the green body drying furnace, so that the energy consumption is greatly reduced; 2. the square-shaped branch air inlet pipeline and the square-shaped branch air outlet pipeline surround the drying furnace and extend to the lower part of the mold, so that the mold is heated uniformly in the drying process, and green bodies are prevented from cracking; 3. the positioning and the separation of the die are automatically completed, manual demoulding is omitted, and the production efficiency is greatly improved.

Description

Mould drying and blank removing machine capable of recovering waste heat of kiln

Technical Field

The utility model relates to a domestic ceramics production facility field, specificly relate to a mould stoving knockout machine of recoverable kiln waste heat.

Background

The slip casting is a method of selecting a proper dispergator to uniformly suspend the powdery raw material in a solution, preparing into slurry, then pouring into a model (generally a plaster model) with water absorption to absorb water, and forming a blank according to the model. The method is commonly used for manufacturing daily ceramics and architectural ceramics with complex shapes and low precision requirements. Based on the physical characteristic that a porous gypsum mold can absorb moisture, ceramic powder is prepared into slurry with fluidity and then injected into the porous mold (mainly a gypsum mold), a uniform mud layer with certain thickness is formed after the moisture is absorbed by the mold (gypsum), and a green body with certain strength is formed in the dehydration and drying process, so that the method is called slip casting. The steps of grouting forming sequentially comprise grouting, pouring, throwing slurry, drying and blank taking. The existing drying step adopts a single heat source to supply hot air, so that the energy consumption and the production cost are high, the waste gas afterheat in the kiln can not be utilized, and if the kiln afterheat can be applied to the drying step, the energy consumption is greatly saved; in addition, in the prior art, blank taking needs to be completed manually, the labor cost is high, and the production efficiency is low.

In view of this, the utility model discloses the people have researched and developed a mould stoving knockout base machine of recoverable kiln waste heat very much, have solved above-mentioned problem, and the present case produces from this.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to provide a mould stoving knockout machine of recoverable kiln waste heat to solve the problem that provides in the background art.

In order to solve the technical problem, the utility model discloses a technical scheme as follows: the utility model provides a mould stoving knockout machine of recoverable kiln waste heat which characterized in that includes:

the kiln waste heat recovery device comprises a drying furnace, wherein a feeding end of the drying furnace is provided with a main air inlet pipeline, a return air inlet branch pipeline and a capillary air inlet pipeline which are sequentially communicated, the main air inlet pipeline is communicated with a waste heat recovery pipeline of the kiln, a discharging end of the drying furnace is provided with a main air exhaust pipeline, a return air exhaust branch pipeline and a capillary air exhaust pipeline which are sequentially communicated, the lower sections of the return air inlet branch pipeline and the return air exhaust branch pipeline are positioned in a cavity of the drying furnace, the lower sections of the return air inlet branch pipeline and the return air exhaust branch pipeline are provided with air outlets, and the capillary air inlet pipeline and the capillary air exhaust pipeline are communicated with the cavity of the drying furnace;

the mould conveying device is provided with conveying vehicles at equal intervals, a mould guide sleeve is rotatably arranged on each conveying vehicle, a gypsum mould is sleeved in each mould guide sleeve and comprises a left mould and a right mould, a guide groove for preventing the gypsum mould from rotating in the axial direction in each mould guide sleeve is formed in the inner wall of each mould guide sleeve, and a guide strip matched with the guide groove is arranged on each gypsum mould;

the mould separation device comprises a mould separation base, a mould lifting driving unit arranged on the mould separation base, a lifting base driven to lift by the mould lifting driving unit, a left separation driving unit and a right separation driving unit arranged on the lifting base, and the left/right moulds can be separated or combined under the driving of the left/right separation driving unit;

the mould positioning device comprises a contact seat arranged at the bottom of a mould guide sleeve, a liftable annular positioning base sleeved outside the mould separation device, a positioning lifting driving unit for driving the annular positioning base to lift, an annular contact disc rotatably arranged on the annular positioning base and matched with the contact seat, a positioning motor arranged on the annular positioning base and used for driving the annular contact disc to rotate, a positioning block arranged at the outer edge of the mould guide sleeve, a baffle matched with the positioning block and used for limiting the mould guide sleeve to rotate, and a baffle driving servo motor for driving the baffle to be close to the mould guide sleeve;

the green body adsorption transfer device comprises a transfer support, a transfer seat arranged on the transfer support in a sliding mode, a transverse moving driving unit for driving the transfer seat to move, a green body taking lifting driving unit arranged on the transfer seat and a sucker arranged at the output end of the green body taking lifting driving unit.

Preferably, the main air inlet pipeline and the main exhaust pipeline are provided with air blowers, and the number of the return type branch air inlet pipelines and the number of the return type branch exhaust pipelines are 3.

Preferably, the outer wall of the plaster mold is provided with a metal shell.

Preferably, the inner wall of the mould guide sleeve and the outer wall of the plaster mould are provided with conical surfaces which correspond to each other and are used for enabling the left mould and the right mould to be tightly matched in the mould guide sleeve.

Preferably, the output end of the left/right separation driving unit is provided with a separation positioning claw for being clamped with the left/right mold and a supporting plate for supporting the left/right mold, and the bottom of the left/right mold is provided with a separation positioning groove matched with the separation positioning claw.

Preferably, the baffle driving servo motor is connected with the baffle through a divider, and the baffle rotates under the driving of the divider.

Preferably, the device further comprises a green body conveying device, and the green body conveying device and the die conveying device are arranged side by side.

The control method of the mold drying and blank removing machine capable of recycling the waste heat of the kiln is characterized by comprising the following steps of:

a. drying: the gypsum mould injected with the slurry is conveyed into a drying furnace by a conveying vehicle on a mould conveying device, waste heat generated by the furnace enters a cavity of the drying furnace through a main air inlet pipeline, a return air inlet branch pipeline and a capillary air inlet pipeline in sequence under the pressurization of an air blower, the capillary air inlet pipeline surrounds the cavity to ensure that the gypsum mould is uniformly heated up, down, left and right, an exhaust port at the lower section of the return air inlet branch pipeline is positioned at the bottom of the cavity to ensure that the bottom of the drying furnace is kept warm and heat loss is avoided, hot air in the drying furnace is discharged through the capillary air outlet pipeline, the return air outlet branch pipeline and the main air outlet pipeline in sequence, and the gypsum mould is gradually dried;

b. positioning: after the gypsum mold dried by the drying oven reaches a demolding station, the baffle drives the servo motor to drive the baffle to be close to the gypsum mold, the positioning lifting driving unit drives the annular positioning base and the annular contact disc to ascend until the annular positioning base and the annular contact disc are in contact fit with the contact seat at the bottom of the mold guide sleeve, the positioning motor drives the annular contact disc to rotate and drives the mold guide sleeve and the gypsum mold to rotate through friction force until the positioning block at the outer edge of the mold guide sleeve abuts against the baffle, the gypsum mold does not rotate any longer, at the moment, the left/right mold corresponds to the left/right separation driving unit in position, namely, the separation positioning claw corresponds to the separation positioning groove in position in the longitudinal direction, the baffle rotates away from the gypsum mold, and the.

c. Lifting the mold: the mould lifting driving unit drives the lifting base to ascend, the separation positioning claw enters the separation positioning groove, the supporting plate is abutted to the bottom of the gypsum mould, and the gypsum mould ascends along with the lifting base under the support of the supporting plate until the gypsum mould is separated from the mould guide sleeve;

d. adsorption of the mold: the blank taking lifting driving unit drives the sucker to descend and adsorb the bottom in the blank body;

e. separating the mold: the left/right mould is separated by the left separation driving unit and the right separation driving unit, and the green body is kept still under the adsorption of the sucker and is separated from the left/right mould;

f. blank taking: the mould lifting driving unit drives the green body to rise through the sucking disc, and the transverse moving driving unit drives the transfer seat and the green body to move to the green body conveying device.

According to the above description, the utility model provides a mould stoving of recoverable kiln waste heat takes off base machine has following beneficial effect: 1. the waste heat of the kiln is used for heating the green body drying furnace, so that the energy consumption is greatly reduced; 2. the square-shaped branch air inlet pipeline and the square-shaped branch air outlet pipeline surround the drying furnace and extend to the lower part of the mold, so that the mold is heated uniformly in the drying process, and green bodies are prevented from cracking; 3. the die positioning and the die releasing are automatically completed, manual die releasing is omitted, and the production efficiency is greatly improved.

Drawings

Fig. 1 is a schematic view of the three-dimensional structure of the mold drying and blank removing machine capable of recovering the waste heat of the kiln.

Fig. 2 is a schematic perspective view of the drying oven.

Fig. 3 is a side view of fig. 2.

Fig. 4 is a schematic view of the transportation of the mold drying and blank removing machine capable of recovering the waste heat of the kiln.

Fig. 5 is the die separation schematic diagram of the die drying and blank removing machine capable of recovering the waste heat of the kiln.

Fig. 6 is a schematic view of the transportation of the mold drying and blank removing machine capable of recovering the waste heat of the kiln.

Fig. 7 is a sectional view a-a of fig. 6.

Fig. 8 is the die positioning schematic diagram of the die drying and blank removing machine capable of recovering the waste heat of the kiln.

Fig. 9 is a sectional view B-B of fig. 8.

Fig. 10 is a schematic view of the mold separation of the mold drying and blank removing machine capable of recovering the waste heat of the kiln.

Fig. 11 is a cross-sectional view C-C of fig. 10.

Detailed Description

The present invention will be further described with reference to the following detailed description.

The utility model discloses a mould stoving knockout machine of recoverable kiln waste heat, include: the device comprises a drying furnace 1, a mould conveying device 2, a mould separating device, a mould positioning device, a green body adsorption and transfer device 5, a green body conveying device 6 and a PLC.

Drying furnace 1: referring to fig. 1 to 3, a main air inlet pipe 11, a branch return air inlet pipe 12 and a capillary air inlet pipe 13 are sequentially connected to a feed end of a drying furnace 1, the main air inlet pipe 11 is connected to a waste heat recovery pipe of the furnace, a main exhaust pipe 14, a branch return exhaust pipe 15 and a capillary exhaust pipe 16 are sequentially connected to a discharge end of the drying furnace 1, lower sections of the branch return air inlet pipe 12 and the branch return exhaust pipe 15 are located in a cavity of the drying furnace 1, lower sections of the branch return air inlet pipe 12 and the branch return exhaust pipe 15 are provided with air outlets, the capillary air inlet pipe 13 and the capillary exhaust pipe 16 are connected to the cavity of the drying furnace 1, the main air inlet pipe 11 and the main exhaust pipe 14 are provided with air blowers for respectively inputting residual heat air of the waste heat recovery pipe of the furnace into the drying furnace 1 and pumping away moisture in the drying furnace 1, 3 branch return air inlet pipes 12 and branch return exhaust pipes 15 are provided, are arranged at intervals.

The mold conveying device 2: as shown in fig. 7, a conveying vehicle 21 is provided on the mold transporting device 2 at equal intervals, a mold guide 22 is rotatably provided on the conveying vehicle 21, a gypsum mould is sleeved in the mould guide sleeve 22 and comprises a left mould 23 and a right mould 24, a guide groove 25 (shown in figure 11) for preventing the gypsum mould from rotating along the axial direction in the mould guide sleeve 22 is arranged on the inner wall of the mould guide sleeve 22, a guide strip 26 (shown in figure 10) matched with the guide groove 25 is arranged on the outer wall of the gypsum mould, the mould transportation device 2 is of an oblong chain conveyor, and is driven by a conveying servo motor, the figure omits the driving part of the long circular chain conveyer and the like, only displays the partial conveying section and the schematic diagram of the long circular chain conveyer, the inner wall of the die guide sleeve 22 and the outer wall of the plaster die are provided with conical surfaces which correspond to each other and are used for leading the left die 23 and the right die 24 to be tightly matched in the die guide sleeve 22, and the outer wall of the plaster die is provided with a metal shell.

A mold separation device: the mold separation device comprises a mold separation base 31, a mold lifting driving unit 32 arranged on the mold separation base 31, a lifting base 33 driven by the mold lifting driving unit 32 to lift, and a left separation driving unit 34 and a right separation driving unit 35 arranged on the lifting base 33, wherein the left/right molds 24 can be separated or combined under the driving of the left/right separation driving unit 35, the output end of the left/right separation driving unit 35 is provided with a separation positioning claw 36 used for being clamped with the left/right molds 24 and a supporting plate 37 used for supporting the left/right molds 24, the bottom of the left/right molds 24 is provided with a separation positioning groove 38 matched with the separation positioning claw 36, preferably, the separation positioning claw 36 is provided with a plurality of separation positioning fingers, and the separation positioning fingers and the separation positioning groove 38 are in a conical shape matched with each other.

A mold positioning device: the mold positioning device comprises a contact seat 41 arranged at the bottom of the mold guide sleeve 22, an annular positioning base 42 which is sleeved outside the mold separation device and can be lifted, a positioning lifting driving unit 43 for driving the annular positioning base 42 to lift, an annular contact disc 44 which is rotatably arranged on the annular positioning base 42 and is matched with the contact seat 41, a positioning motor 45 which is arranged on the annular positioning base 42 and drives the annular contact disc 44 to rotate, a positioning block 46 arranged at the outer edge of the mold guide sleeve 22, a baffle 47 which is matched with the positioning block 46 and is used for limiting the rotation of the mold guide sleeve 22, and a servo motor 48 which is driven by the baffle 47 close to the baffle 47 of the mold guide sleeve 22; the motor 45 drives the annular contact disc 44 to rotate through the gear reduction mechanism, the contact base 41 and the die guide sleeve 22 are integrally formed, the baffle 47 drives the servo motor 48 to be connected with the baffle 47 through the divider, the divider is a halving divider, the baffle 47 rotates under the driving of the divider, and when the baffle 47 moves to a station close to a gypsum die, the positioning block 46 of the rotating gypsum die is limited.

Green body adsorption transfer device 5: the green body adsorption transfer device 5 comprises a transfer bracket 51, a transfer seat 52 arranged on the transfer bracket 51 in a sliding manner, a transverse moving driving unit 53 for driving the transfer seat 52 to move, a green body taking lifting driving unit 54 arranged on the transfer seat 52 and a suction cup 55 arranged at the output end of the green body taking lifting driving unit 54, wherein the type of the suction cup 55 is a vacuum suction cup 55;

the blank conveying device 6: the blank conveying device 6 is arranged side by side with the mould transport device 2.

The PLC is in signal control connection with the execution units of the drying furnace 1, the mold conveying device 2, the mold separating device, the mold positioning device and the green body adsorption transfer device 5, and particularly, the PLC is in signal control connection with the air blower, the conveying servo motor, the mold lifting driving unit 32, the left/right separation driving unit 35, the positioning lifting driving unit 43, the positioning motor 45, the baffle 47 driving servo motor 48, the transverse moving driving unit 53, the green body taking lifting driving unit 54, the sucking disc 55 and the driving motor of the green body conveying device 6; the mold lifting drive unit 32, the left/right separation drive unit 35, the blank take-out lifting drive unit 54, and the positioning lifting drive unit 43 are of the type of air cylinders, and the traverse drive unit 53 is of the type of linear slide.

The utility model discloses recoverable kiln waste heat' S mould stoving knockout machine can select to use Siemens S7-200 series PLCCPU224XPCN, except PLC among the controlling means, still include touch-sensitive screen, servo controller and measurement feedback component, touch-sensitive screen, PLC, servo controller and each execution unit servo motor concatenate, servo controller and servo motor formation feedback circuit are connected respectively to the both ends of measuring feedback component, and the touch-sensitive screen is the man-machine conversation interface, and initial instruction information will be followed here and is inputed. The input information is transmitted to the PLC through the communication port. After operation, the PLC outputs an analog quantity and is connected to an analog quantity input port of the servo controller. The servo controller performs internal operation on the received analog quantity and then drives the servo motor to reach a corresponding rotating speed. The servo motor feeds the rotating speed information back to the servo controller through the speed measuring element to form a closed loop system, and the effect of stable rotating speed is achieved. The PLC provides signals to accurately control the movement of each execution unit/servo motor.

The control method of the mold drying and blank removing machine capable of recovering the waste heat of the kiln comprises the following steps:

a. drying: the gypsum mould injected with the slurry is conveyed into the drying furnace 1 by the conveying vehicle 21 on the mould conveying device 2, the waste heat of the hot air output by the kiln through the heat exchanger is pressurized by the air blower and then sequentially enters the cavity of the drying furnace 1 through the main air inlet pipeline 11, the return air inlet branch pipeline 12 and the air inlet capillary pipeline 13, the gypsum mould is uniformly heated up, down, left and right due to the fact that the air inlet capillary pipeline 13 surrounds the cavity, cracking of a blank body in the drying process is avoided, an exhaust port at the lower section of the return air inlet branch pipeline 12 is positioned at the bottom of the cavity, heat preservation is carried out at the bottom of the drying furnace 1, heat loss is avoided, hot air in the drying furnace 1 is sequentially exhausted through the exhaust capillary pipeline 16, the return exhaust branch pipeline 15 and the main exhaust pipeline 14, and the gypsum mould is gradually dried and;

b. positioning: as shown in fig. 8 and 9, since the gypsum mold is rotated and sluiced before entering the drying oven, the mold positioning is required in order to make the separation positioning claws 36 and the separation positioning grooves 38 correspond to each other in the longitudinal direction; after the gypsum mold dried by the drying oven 1 reaches the demolding station, the baffle 47 drives the servo motor 48 to drive the baffle 47 to be close to the gypsum mold, the positioning lifting driving unit 43 drives the annular positioning base 42 and the annular contact disc 44 to ascend until the annular positioning base and the annular contact disc 44 are in contact fit with the contact seat 41 at the bottom of the mold guide sleeve 22, the positioning motor 45 drives the annular contact disc 44 to rotate and drives the mold guide sleeve 22 and the gypsum mold to rotate through friction force until the positioning block 46 at the outer edge of the mold guide sleeve 22 is abutted to the baffle 47, the gypsum mold does not rotate any more, at the moment, the left/right mold 24 corresponds to the left/right separation driving unit 35 in position, namely, the separation positioning claw 36 corresponds to the separation positioning groove 38 in position in the longitudinal direction, the baffle 47 rotates away from the gypsum mold, and the positioning lifting. The stop of the positioning motor 45 after the positioning block 46 contacts the baffle 47 can be realized by the following steps: 1. after the positioning motor 45 is triggered to work each time, the number of rotation turns of the die guide sleeve 22 is set to be 1.5-2, and after the positioning block 46 at the outer edge of the die guide sleeve 22 is abutted to the baffle 47, the annular contact disc 44 and the contact seat 41 slide relatively for a period of time; 2. a trigger travel switch is arranged on the baffle plate 47, after the positioning block 46 abuts against the baffle plate 47, a signal is transmitted to the PLC, the PLC controls the positioning motor 45 to stop working, meanwhile, the baffle plate 47 drives the servo motor 48 to drive the baffle plate 47 to leave the plaster mold, and the positioning lifting driving unit 43 drives the annular positioning base 42 and the annular contact disc 44 to descend.

c. Lifting the mold: as shown in fig. 8 and 9, the mold lifting driving unit 32 drives the lifting base 33 to lift, the separation positioning claws 36 enter the separation positioning grooves 38, the supporting plate 37 abuts against the bottom of the gypsum mold, and the gypsum mold is lifted along with the lifting base 33 under the support of the supporting plate 37 until the gypsum mold is separated from the mold guide sleeve 22;

d. adsorption of the mold: as shown in fig. 10 and 11, the blank taking lifting driving unit 54 drives the suction cup 55 to descend and adsorb the bottom in the blank;

e. separating the mold: as shown in fig. 10 and 11, the left/right mold 24 is separated by the left separation driving unit 34 and the right separation driving unit 35, and the green body 100 is held by the suction of the suction cup 55 and separated from the left/right mold 24;

f. blank taking: the mold lifting driving unit 32 drives the green body 100 to ascend through the suction cup 55, the traverse driving unit 53 drives the transfer seat 52 and the green body 100 to move to the upper part of the green body conveying device 6, and the mold lifting driving unit 32 drives the green body 100 to descend through the suction cup 55 to the green body conveying device 6.

The utility model provides a mould stoving of recoverable kiln waste heat takes off base machine has following beneficial effect: 1. the green body drying furnace 1 is heated by using the waste heat of the kiln, so that the energy consumption is greatly reduced; 2. the square-shaped branch air inlet pipeline 12 and the square-shaped branch air outlet pipeline 15 encircle the drying furnace 1 and extend to the lower part of the mould, so that the mould is heated uniformly in the drying process, and a blank body is prevented from cracking; 3. the die positioning and the die releasing are automatically completed, manual die releasing is omitted, and the production efficiency is greatly improved.

The aforesaid is only a plurality of concrete implementation manners of the utility model, nevertheless the utility model discloses a design concept is not limited to this, and the ordinary use of this design is right the utility model discloses carry out immaterial change, all should belong to the act of infringement the protection scope of the utility model.

Claims (7)

1. The utility model provides a mould stoving knockout machine of recoverable kiln waste heat which characterized in that includes:

the kiln waste heat recovery device comprises a drying furnace, wherein a feeding end of the drying furnace is provided with a main air inlet pipeline, a return air inlet branch pipeline and a capillary air inlet pipeline which are sequentially communicated, the main air inlet pipeline is communicated with a waste heat recovery pipeline of the kiln, a discharging end of the drying furnace is provided with a main air exhaust pipeline, a return air exhaust branch pipeline and a capillary air exhaust pipeline which are sequentially communicated, the lower sections of the return air inlet branch pipeline and the return air exhaust branch pipeline are positioned in a cavity of the drying furnace, the lower sections of the return air inlet branch pipeline and the return air exhaust branch pipeline are provided with air outlets, and the capillary air inlet pipeline and the capillary air exhaust pipeline are communicated with the cavity of the drying furnace;

the mould conveying device is provided with conveying vehicles at equal intervals, a mould guide sleeve is rotatably arranged on each conveying vehicle, a gypsum mould is sleeved in each mould guide sleeve and comprises a left mould and a right mould, a guide groove for preventing the gypsum mould from rotating in the axial direction in each mould guide sleeve is formed in the inner wall of each mould guide sleeve, and a guide strip matched with the guide groove is arranged on each gypsum mould;

the mould separation device comprises a mould separation base, a mould lifting driving unit arranged on the mould separation base, a lifting base driven to lift by the mould lifting driving unit, a left separation driving unit and a right separation driving unit arranged on the lifting base, and the left/right moulds can be separated or combined under the driving of the left/right separation driving unit;

the mould positioning device comprises a contact seat arranged at the bottom of a mould guide sleeve, a liftable annular positioning base sleeved outside the mould separation device, a positioning lifting driving unit for driving the annular positioning base to lift, an annular contact disc rotatably arranged on the annular positioning base and matched with the contact seat, a positioning motor arranged on the annular positioning base and used for driving the annular contact disc to rotate, a positioning block arranged at the outer edge of the mould guide sleeve, a baffle matched with the positioning block and used for limiting the mould guide sleeve to rotate, and a baffle driving servo motor for driving the baffle to be close to the mould guide sleeve;

the green body adsorption transfer device comprises a transfer support, a transfer seat arranged on the transfer support in a sliding mode, a transverse moving driving unit for driving the transfer seat to move, a green body taking lifting driving unit arranged on the transfer seat and a sucker arranged at the output end of the green body taking lifting driving unit.

2. The mold drying and knockout machine capable of recovering the kiln waste heat as claimed in claim 1, wherein: the trunk line of admitting air and main exhaust line all are equipped with the air-blower, it all is equipped with 3 to return type branch pipeline of admitting air and return type branch pipeline of exhausting.

3. The mold drying and knockout machine capable of recovering the kiln waste heat as claimed in claim 1, wherein: and a metal shell is arranged on the outer wall of the gypsum mould.

4. The mold drying and knockout machine capable of recovering the kiln waste heat as claimed in claim 1, wherein: the inner wall of the mould guide sleeve and the outer wall of the plaster mould are provided with conical surfaces which correspond to each other and are used for enabling the left mould and the right mould to be tightly matched in the mould guide sleeve.

5. The mold drying and knockout machine capable of recovering the kiln waste heat as claimed in claim 1, wherein: the output end of the left/right separation driving unit is provided with a separation positioning claw used for being connected with a left/right mold in a clamped mode and a supporting plate used for supporting the left/right mold, and a separation positioning groove matched with the separation positioning claw is formed in the bottom of the left/right mold.

6. The mold drying and knockout machine capable of recovering the kiln waste heat as claimed in claim 1, wherein: the baffle driving servo motor is connected with the baffle through the divider, and the baffle rotates under the driving of the divider.

7. The mold drying and knockout machine capable of recovering the kiln waste heat as claimed in claim 1, wherein: the die conveying device is characterized by further comprising a blank conveying device, and the blank conveying device and the die conveying device are arranged side by side.

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