CN107984606B

CN107984606B - Piezoelectric ceramic production equipment with impurity removal function and capable of intelligently feeding

Info

Publication number: CN107984606B
Application number: CN201711093017.6A
Authority: CN
Inventors: 蒙泽喜
Original assignee: Tongxiang Qingfeng Technology Co Ltd
Current assignee: Tongxiang Qingfeng Technology Co., Ltd
Priority date: 2017-11-08
Filing date: 2017-11-08
Publication date: 2020-06-12
Anticipated expiration: 2037-11-08
Also published as: CN107984606A

Abstract

The invention relates to a piezoelectric ceramic production device with impurity removal function and capable of intelligently feeding, which comprises a shell, wherein a batching chamber, a grid plate, a vibration mechanism, a material storage chamber and at least two first springs are arranged in the shell, the vibration mechanism comprises a driving assembly, a connecting plate, a vibration assembly, a clamping assembly and two connecting wires, the vibrating mechanism shakes the batching chamber through the vibration mechanism to filter out sundries in the batching chamber through the grid plate, compared with the traditional vibration mechanism, the vibration mechanism realizes vibration through the first springs, so that the vibration frequency is higher, the vibration duration is longer, the height of a nozzle is adjusted through the feeding mechanism, so that an additive is added in the middle of batching, the quality of piezoelectric ceramic is improved, compared with the traditional feeding mechanism, the piezoelectric ceramic production device with impurity removal function is more stable in operation due to the action of a wire guide ring, the practicability of the piezoelectric ceramic production equipment is greatly improved.

Description

Piezoelectric ceramic production equipment with impurity removal function and capable of intelligently feeding

Technical Field

The invention relates to the field of piezoelectric ceramic production equipment, in particular to piezoelectric ceramic production equipment with an impurity removal function and capable of intelligently feeding.

Background

Piezoelectric ceramics are ceramic materials capable of converting mechanical energy and electrical energy into each other, have dielectric properties, elasticity and the like in addition to piezoelectric properties, and have been widely used in medical imaging, acoustic sensors, acoustic transducers, ultrasonic motors and the like. The piezoelectric ceramic is manufactured by utilizing the piezoelectric effect that the material causes the relative displacement of the centers of positive and negative charges in the material under the action of mechanical stress to generate polarization, so that bound charges with opposite signs appear on the surfaces of two ends of the material, and the piezoelectric ceramic has sensitive characteristics.

The impurity in the batching can't be got rid of effectively to present piezoceramics production facility will influence final fashioned piezoceramics's quality greatly, and at the batching in-process, need pour into a small amount of additive into in the middle of the big material into, the position of pouring into of additive will influence piezoceramics's quality, and present additive pours into the rigidity into, and when the batching is less, there is the deviation in the position of pouring into of additive, has reduced piezoceramics's quality to greatly reduced piezoceramics production facility's practicality.

Disclosure of Invention

The technical problem to be solved by the invention is as follows: in order to overcome the defects of the prior art, the intelligent charging piezoelectric ceramic production equipment with the impurity removal function is provided.

The technical scheme adopted by the invention for solving the technical problems is as follows: the piezoelectric ceramic production equipment with the impurity removal function and capable of intelligently feeding comprises a shell, wherein a batching chamber, a grid plate, a vibration mechanism, a storage chamber and at least two first springs are arranged in the shell, the first springs are uniformly distributed on two opposite side surfaces of the batching chamber and the bottom of the batching chamber avoiding the grid plate, a first opening is formed in the bottom of the batching chamber, the grid plate is fixed below the first opening and matched with the first opening, the vibration mechanism is arranged at the top in the shell, the storage chamber is fixed above the batching chamber, and a feeding mechanism is arranged in the batching chamber;

the vibration mechanism comprises a driving assembly, a connecting plate, a vibration assembly, clamping assemblies and two connecting wires, the driving assembly is arranged at the top in the shell, the connecting plate is positioned below the driving assembly, the two connecting wires are respectively positioned at two sides of the driving assembly, the vibration assembly is arranged below the connecting plate, the driving assembly is in transmission connection with the connecting plate, the top ends of the connecting wires are fixedly connected with the top in the shell, the bottom ends of the connecting wires are fixedly connected with the connecting plate, the connecting wires are in a loose state, the clamping assemblies are arranged at two sides of the vibration assembly, and the clamping assemblies are in transmission connection with the vibration assembly;

the vibration component comprises a buffer block, a connecting block, two second springs, two third springs, at least two first ratchets, two connecting rods and at least two second ratchets, the two second springs are respectively arranged at two sides below the connecting plate, the two third springs are respectively arranged at two sides below the buffer block, the top end of the second spring is fixed below the connecting plate, the bottom end of the second spring is fixedly connected with the buffer block, the top end of the third spring is fixed below the connecting plate, the bottom end of the third spring is fixedly connected with the connecting block, the first ratchets are uniformly distributed on two sides of the connecting block, the two connecting rods are respectively arranged on two sides of the connecting block, the second ratchets are uniformly distributed on one side, close to the connecting block, of the connecting rod, the first ratchets are matched with the second ratchets, and the clamping assembly is in transmission connection with the connecting rod;

the feeding mechanism comprises a lifting assembly and a feeding assembly, the lifting assembly is arranged on one side in the batching chamber, and the lifting assembly is in transmission connection with the feeding assembly;

the feeding assembly comprises a lifting block, a first motor, a lead screw, a moving block, two guide rods and at least two nozzles, the first motor is fixed to one side of the lifting block, the first motor is located in a batching chamber, the lead screw is horizontally arranged, the lead screw is located on one side, away from the lifting block, of the first motor, the first motor is in transmission connection with the lead screw, the two guide rods are respectively arranged on two sides of the lead screw, one end of each guide rod is fixed to the lifting block, the moving block is sleeved on the lead screw and the guide rods, internal threads are arranged in the moving block, external threads are arranged on the lead screw, internal threads in the moving block are matched with the external threads on the lead screw, the nozzles are evenly distributed on two sides of the moving block, and the nozzles are communicated.

Preferably, in order to control the loosening or clamping of the two connecting rods, the clamping assembly comprises a second motor, a first gear, a first connecting rod and two clamping units, the second motor is fixed on the inner wall of the shell, the second motor is in transmission connection with the first gear, the two clamping units are respectively arranged on two sides of the first gear, each clamping unit comprises a first rack, a chute, a cross rod, a vertical rod, a second connecting rod and a clamping block, the first rack is arranged in the chute, the first rack is in sliding connection with the chute, one of the two chutes is fixed on the inner wall of the shell, the other chute is fixedly connected with the inner wall of the shell through the first connecting rod, one end of the cross rod is fixedly connected with one end of the first rack, the other end of the cross rod is fixedly connected with the top end of the vertical rod, and the bottom end of the vertical rod is fixedly connected with one end of the second connecting rod, the other end of the second connecting rod is fixedly connected with the clamping block, and the clamping block is fixedly connected with the connecting rod.

Preferably, for more accurate drive connecting block, drive assembly includes air pump, cylinder and piston, the top in the shell is fixed to the air pump, air pump and cylinder intercommunication, the vertical setting of piston, the top setting of piston is in the cylinder, the bottom and the connecting plate fixed connection of piston.

Preferably, in order to adjust the height of the lifting block, the lifting assembly comprises a third motor, a half gear, a movable frame, two guide rings and two second racks, the third motor is fixed on the inner wall of the shell, the third motor is in transmission connection with the half gear, the two second racks are respectively fixed on two sides of the movable frame, the half gear is located between the two second racks, the half gear is meshed with the second racks, the guide rings are fixed on the inner wall of the shell, the guide rings are sleeved on the movable frame, the two guide rods are respectively arranged at the top and the bottom of the movable frame, and the lifting block is fixedly connected with the movable frame.

Preferably, the half gear is made of stainless steel in order to prolong the service life of the half gear.

Preferably, in order to improve the accuracy of the first motor, the second motor and the third motor, the first motor, the second motor and the third motor are all servo motors.

Preferably, in order to make the first rack move more stably, the sliding groove is a dovetail groove.

Preferably, in order to prolong the service life of the connecting wire, the connecting wire is a nylon wire.

Preferably, the first spring, the second spring, and the third spring are all extension springs in order to increase restoring forces of the first spring, the second spring, and the third spring.

Preferably, the two sliding grooves are arranged in parallel in order to ensure that the clamping block runs more stably when driving the connecting rod.

The piezoelectric ceramic production equipment with the impurity removal function and the intelligent feeding function has the advantages that the vibration mechanism shakes the batching chamber to filter impurities in the batching chamber through the grid plate, compared with the traditional vibration mechanism, the vibration mechanism realizes vibration through the first spring, so that the vibration frequency is higher, the vibration duration is longer, the height of the nozzle is adjusted through the feeding mechanism, so that an additive is added in the middle of batching, and the quality of piezoelectric ceramic is improved.

Drawings

The invention is further illustrated with reference to the following figures and examples.

FIG. 1 is a schematic structural diagram of a piezoelectric ceramic production device with impurity removal function and capable of intelligent charging according to the present invention;

FIG. 2 is a schematic view of a connection structure of a driving assembly, a connection plate and a connection line of the intelligent charging piezoelectric ceramic production equipment with impurity removal function of the invention;

FIG. 3 is a schematic view of a connection structure of a vibration assembly and a clamping block of the intelligent charging piezoelectric ceramic production equipment with impurity removal function of the invention;

FIG. 4 is a schematic structural diagram of a lifting assembly of the intelligent charging piezoelectric ceramic production equipment with impurity removal function according to the invention;

FIG. 5 is a schematic structural diagram of a charging assembly of the intelligent charging piezoelectric ceramic production equipment with impurity removal function according to the invention;

FIG. 6 is a schematic structural diagram of a clamping assembly of the intelligent charging piezoelectric ceramic production equipment with impurity removal function according to the invention;

FIG. 7 is a schematic view of a connection structure of a first rack and a chute of the intelligent charging piezoelectric ceramic production equipment with impurity removal function of the present invention;

in the figure: 1. the automatic feeding device comprises a shell, 2, a batching chamber, 3, a grid plate, 4, a first spring, 5, a storage chamber, 6, an air pump, 7, an air cylinder, 8, a piston, 9, a connecting plate, 10, a connecting wire, 11, a second spring, 12, a buffer block, 13, a third spring, 14, a connecting block, 15, a first ratchet, 16, a second ratchet, 17, a connecting rod, 18, a lifting block, 19, a first motor, 20, a guide rod, 21, a lead screw, 22, a moving block, 23, a nozzle, 24, a second motor, 25, a first gear, 26, a first rack, 27, a sliding chute, 28, a cross rod, 29, a vertical rod, 30, a second connecting rod, 31, a clamping block, 32, a first connecting rod, 33, a third motor, 34, a half gear, 35, a second rack, 36, a moving frame and 37, and a guide ring.

Detailed Description

The present invention will now be described in further detail with reference to the accompanying drawings. These drawings are simplified schematic views illustrating only the basic structure of the present invention in a schematic manner, and thus show only the constitution related to the present invention.

As shown in fig. 1, a piezoelectric ceramic production device with impurity removal function and capable of intelligently feeding comprises a housing 1, wherein a batching chamber 2, a grid plate 3, a vibration mechanism, a material storage chamber 5 and at least two first springs 4 are arranged in the housing 1, the first springs 4 are uniformly distributed on two opposite side surfaces of the batching chamber 2 and the bottom of the batching chamber 2 avoiding the grid plate 3, a first opening is formed in the bottom of the batching chamber 2, the grid plate 3 is fixed below the first opening, the grid plate 3 is matched with the first opening, the vibration mechanism is arranged at the top in the housing 1, the material storage chamber 5 is fixed above the batching chamber 2, and the feeding mechanism is arranged in the batching chamber 2;

through shaking mechanism shake batching room 2, the debris that will batching in the room 2 pass through the filtering of grid tray 3, compare with traditional shaking mechanism, this shaking mechanism realizes vibrations through first spring 4, make vibration frequency higher, vibrations duration is more of a specified duration, height through reinforced mechanism adjusting nozzle 23, make the additive add in the middle of the batching, thereby piezoceramics's quality has been improved, compare with traditional reinforced mechanism, this reinforced mechanism is because wire ring 37's effect, it is more steady when the operation, make this piezoceramics production facility's practicality improve greatly.

As shown in fig. 2-3, the vibration mechanism includes a driving assembly, a connecting plate 9, a vibration assembly, a clamping assembly and two connecting wires 10, the driving assembly is disposed at the top of the housing 1, the connecting plate 9 is disposed below the driving assembly, the two connecting wires 10 are disposed at two sides of the driving assembly respectively, the vibration assembly is disposed below the connecting plate 9, the driving assembly is in transmission connection with the connecting plate 9, the top end of the connecting wire 10 is fixedly connected with the top of the housing 1, the bottom end of the connecting wire 10 is fixedly connected with the connecting plate 9, the connecting wire 10 is in a loose state, the clamping assembly is disposed at two sides of the vibration assembly, and the clamping assembly is in transmission connection with the vibration assembly;

the vibration component comprises a buffer block 12, a connecting block 14, two second springs 11, two third springs 13, at least two first ratchets 15, two connecting rods 17 and at least two second ratchets 16, wherein the two second springs 11 are respectively arranged at two sides below the connecting plate 9, the two third springs 13 are respectively arranged at two sides below the buffer block 12, the top ends of the second springs 11 are fixed below the connecting plate 9, the bottom ends of the second springs 11 are fixedly connected with the buffer block 12, the top ends of the third springs 13 are fixed below the connecting plate 9, the bottom ends of the third springs 13 are fixedly connected with the connecting block 14, the first ratchets 15 are uniformly distributed at two sides of the connecting block 14, the two connecting rods 17 are respectively arranged at two sides of the connecting block 14, the second ratchets 16 are uniformly distributed at one side of the connecting rods 17 close to the connecting block 14, and the first ratchets 15 are matched with the second ratchets 16, the clamping assembly is in transmission connection with a connecting rod 17;

the drive assembly drives the connecting plate 9 to move up and down, when the connecting plate 9 moves downwards, the second spring 11 and the third spring 13 are compressed ceaselessly, the connecting plate 9 continues to move downwards to drive the connecting block 14 to move downwards, after the material mixing chamber 2 is pressed down by the connecting block 14, the first spring 4 is compressed, under the limitation of the second ratchet 16, the connecting block 14 is prevented from moving upwards due to the restoring force of the first spring 4, and the connecting wire 10 is used for preventing the connecting plate 9 from being separated from the piston 8 during vibration.

As shown in fig. 4-5, the charging mechanism comprises a lifting assembly and a charging assembly, the lifting assembly is arranged at one side in the batching chamber 2, and the lifting assembly is in transmission connection with the charging assembly;

the charging component comprises a lifting block 18, a first motor 19, a screw rod 21, a moving block 22, two guide rods 20 and at least two nozzles 23, the first motor 19 is fixed on one side of the lifting block 18, the first motor 19 is positioned in the batching chamber 2, the screw rod 21 is horizontally arranged, the screw rod 21 is positioned on one side of the first motor 19 far away from the lifting block 18, the first motor 19 is in transmission connection with a screw rod 21, two guide rods 20 are respectively arranged at two sides of the screw rod 21, one end of the guide rod 20 is fixed on the lifting block 18, the moving block 22 is sleeved on the screw rod 21 and the guide rod 20, an internal thread is arranged in the moving block 22, an external thread is arranged on the screw rod 21, the internal thread in the moving block 22 is matched with the external thread on the screw rod 21, the nozzles 23 are uniformly distributed on two sides of the moving block 22, and the nozzles 23 are communicated with the storage chamber 5;

the lifting assembly drives the lifting block 18 to lift, so that the nozzle 23 lifts, the height of the nozzle 23 is adjusted, the first motor 19 drives the screw rod 21 to rotate, the guide rod 20 limits the rotation of the moving block 22, the moving block 22 moves left and right along the screw rod 21, the nozzle 23 is driven to move left and right, and additives are sprayed into the ingredients.

As shown in fig. 6, the clamping assembly includes a second motor 24, a first gear 25, a first link 32 and two clamping units, the second motor 24 is fixed on the inner wall of the housing 1, the second motor 24 is in transmission connection with the first gear 25, the two clamping units are respectively disposed on two sides of the first gear 25, the clamping units include a first rack 26, a sliding groove 27, a cross bar 28, a vertical bar 29, a second link 30 and a clamping block 31, the first rack 26 is disposed in the sliding groove 27, the first rack 26 is in sliding connection with the sliding groove 27, one of the sliding grooves 27 is fixed on the inner wall of the housing 1, the other sliding groove 27 is fixedly connected with the inner wall of the housing 1 through the first link 32, one end of the cross bar 28 is fixedly connected with one end of the first rack 26, the other end of the cross bar 28 is fixedly connected with the top end of the vertical bar 29, the bottom end of the vertical bar 29 is fixedly connected with one end of the second link 30, the other end of the second connecting rod 30 is fixedly connected with a clamping block 31, the clamping block 31 is fixedly connected with a connecting rod 17, the second motor 24 drives the first gear 25 to rotate, the first gear 25 drives the cross rod 28 to move horizontally through the two first racks 26, the cross rod 28 drives the clamping block 31 to move left and right, when the first gear 25 rotates clockwise, the two clamping blocks 31 move back to back, when the first gear 25 rotates counterclockwise, the two clamping blocks 31 move oppositely, when the connecting block 14 presses down, the first spring 4 is compressed to the limit, the two clamping blocks 31 move back to back, the connecting rod 17 moves back to back, the first pawl 15 is not limited by the second pawl 16, the batching chamber 2 shakes under the action of the first spring 4, impurities in the batching chamber 2 leave the batching chamber 2 along the grid plate 3, and the purpose of impurity removal is achieved.

As shown in fig. 2, drive assembly includes air pump 6, cylinder 7 and piston 8, the top in shell 1 is fixed to air pump 6, air pump 6 and cylinder 7 intercommunication, the vertical setting of piston 8, the top setting of piston 8 is in cylinder 7, the bottom and the connecting plate 9 fixed connection of piston 8, air pump 6 and cylinder 7 are the piston motion through pneumatic drive piston 8, and piston 8 drives connecting plate 9 and reciprocates, and through the size of control atmospheric pressure, can control piston 8's flexible volume accurately to control connecting plate 9 more accurately.

Preferably, in order to adjust the height of the lifting block 18, the lifting assembly includes a third motor 33, a half gear 34, a moving frame 36, two guide rings 37, and two second racks 35, the third motor 33 is fixed on the inner wall of the housing 1, the third motor 33 is in transmission connection with the half gear 34, the two second racks 35 are respectively fixed on two sides in the moving frame 36, the half gear 34 is located between the two second racks 35, the half gear 34 is engaged with the second racks 35, the guide rings 37 are fixed on the inner wall of the housing 1, the guide rings 37 are sleeved on the moving frame 36, the two guide rods 20 are respectively arranged on the top and the bottom of the moving frame 36, the lifting block 18 is fixedly connected with the moving frame 36, the third motor 33 drives the half gear 34 to rotate, the half gear 34 drives the moving frame 36 to move up and down along the two guide rings 37 through the two second racks 25, thereby drive the reinforced subassembly and reciprocate, adjust the height of reinforced subassembly.

Preferably, in order to prolong the service life of the half gear 34, the half gear 34 is made of stainless steel, which has good corrosion resistance, and the corrosion rate of the half gear 34 can be reduced, thereby prolonging the service life of the half gear 34.

Preferably, in order to improve the accuracy of the first motor 19, the second motor 24 and the third motor 33, the first motor 19, the second motor 24 and the third motor 33 are all servo motors, the servo motors can control the speed and position accuracy accurately, and the voltage signals can be converted into torque and rotation speed to drive the controlled object, so that the accuracy of the first motor 19, the second motor 24 and the third motor 33 is improved.

Preferably, the sliding groove 27 is a dovetail groove in order to make the first rack 26 move more stably.

Preferably, in order to prolong the service life of the connection line 10, the connection line 10 is made of nylon, and the nylon has good wear resistance, so that the loss of the connection line 10 in the using process can be reduced, and the service life of the connection line 10 can be prolonged.

Preferably, in order to increase the restoring force of the first spring 4, the second spring 11 and the third spring 13, the first spring 4, the second spring 11 and the third spring 13 are all extension springs, the extension springs can bear larger axial stress, and before the yield strength is not reached, the axial stress can be borne more than that of a common spring, so that the restoring force of the first spring 4, the second spring 11 and the third spring 13 is stronger.

Preferably, in order to make the movement smoother when the gripping block 31 drives the connecting rod 17, the two sliding grooves 27 are arranged in parallel, so that the component force of the first rack 26 in the direction perpendicular to the moving direction can be reduced, thereby making the first rack 26 less displaced in other directions, and making the movement smoother when the gripping block 31 drives the connecting rod 17.

Drive assembly will shake the subassembly and push down, shake the subassembly and drive batching room 2 and push down, kinetic energy is stored to first spring 4, press from both sides and get the subassembly and loosen after shaking the subassembly, batching room 2 shakes under the effect of the restoring force of first spring 4, debris in the room 2 that will batching passes through grid tray 3 filtering, compare with traditional vibrations mechanism, this vibrations mechanism realizes vibrations through first spring 4, make frequency of vibrations higher, the vibrations duration is more of a specified duration, the reinforced subassembly of lifting unit drive goes up and down, adjust the height of reinforced subassembly, make the additive add in the middle of the batching, thereby piezoceramics's quality has been improved, compare with traditional reinforced mechanism, this reinforced mechanism is because wire ring 37's effect, it is more steady when the operation, make this piezoceramics production facility's practicality improve greatly.

Compared with the prior art, this can intelligent reinforced piezoceramics production facility with edulcoration function, shake batching room 2 through vibration mechanism, debris in the room 2 that will batching pass through grid tray 3 filtering, compare with traditional vibration mechanism, this vibrations mechanism realizes vibrations through first spring 4, make vibration frequency higher, vibrations duration is more of a specified duration, height through reinforced mechanism adjusting nozzle 23, make the additive add in the middle of the batching, thereby piezoceramics's quality has been improved, compare with traditional reinforced mechanism, this reinforced mechanism is because wire ring 37's effect, it is more steady when the operation, make this piezoceramics production facility's practicality improve greatly.

In light of the foregoing description of the preferred embodiment of the present invention, many modifications and variations will be apparent to those skilled in the art without departing from the spirit and scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims

1. The piezoelectric ceramic production equipment with the impurity removing function and capable of intelligently feeding comprises a shell (1) and is characterized in that a batching chamber (2), a grid plate (3), a vibration mechanism, a storage chamber (5) and at least two first springs (4) are arranged in the shell (1), the first springs (4) are uniformly distributed on two opposite side faces of the batching chamber (2) and the bottom of the batching chamber (2) which avoids the grid plate (3), a first opening is formed in the bottom of the batching chamber (2), the grid plate (3) is fixed below the first opening, the grid plate (3) is matched with the first opening, the vibration mechanism is arranged at the top in the shell (1), the storage chamber (5) is fixed above the batching chamber (2), and the feeding mechanism is arranged in the batching chamber (2);

the vibration mechanism comprises a driving assembly, a connecting plate (9), a vibration assembly, a clamping assembly and two connecting wires (10), the driving assembly is arranged at the top of the shell (1), the connecting plate (9) is located below the driving assembly, the two connecting wires (10) are respectively located at two sides of the driving assembly, the vibration assembly is arranged below the connecting plate (9), the driving assembly is in transmission connection with the connecting plate (9), the top end of the connecting wire (10) is fixedly connected with the top of the shell (1), the bottom end of the connecting wire (10) is fixedly connected with the connecting plate (9), the connecting wire (10) is in a loose state, the clamping assembly is arranged at two sides of the vibration assembly, and the clamping assembly is in transmission connection with the vibration assembly;

the vibration component comprises a buffer block (12), a connecting block (14), two second springs (11), two third springs (13), at least two first ratchets (15), two connecting rods (17) and at least two second ratchets (16), the two second springs (11) are respectively arranged on two sides below the connecting plate (9), the two third springs (13) are respectively arranged on two sides below the buffer block (12), the top ends of the second springs (11) are fixed below the connecting plate (9), the bottom ends of the second springs (11) are fixedly connected with the buffer block (12), the top ends of the third springs (13) are fixed below the connecting plate (9), the bottom ends of the third springs (13) are fixedly connected with the connecting block (14), the first ratchets (15) are uniformly distributed on two sides of the connecting block (14), the two connecting rods (17) are respectively arranged on two sides of the connecting block (14), the second ratchet teeth (16) are uniformly distributed on one side, close to the connecting block (14), of the connecting rod (17), the first ratchet teeth (15) are matched with the second ratchet teeth (16), and the clamping assembly is in transmission connection with the connecting rod (17);

the feeding mechanism comprises a lifting assembly and a feeding assembly, the lifting assembly is arranged on one side in the batching chamber (2), and the lifting assembly is in transmission connection with the feeding assembly;

the feeding assembly comprises a lifting block (18), a first motor (19), a screw rod (21), a moving block (22), two guide rods (20) and at least two nozzles (23), the first motor (19) is fixed on one side of the lifting block (18), the first motor (19) is located in the batching chamber (2), the screw rod (21) is horizontally arranged, the screw rod (21) is located on one side, far away from the lifting block (18), of the first motor (19), the first motor (19) is in transmission connection with the screw rod (21), the two guide rods (20) are respectively arranged on two sides of the screw rod (21), one end of each guide rod (20) is fixed on the lifting block (18), the moving block (22) is sleeved on the screw rod (21) and the guide rods (20), internal threads are arranged in the moving block (22), external threads are arranged on the screw rod (21), and the internal threads in the moving block (22) are matched with the external threads on the screw rod (21), the nozzles (23) are uniformly distributed on two sides of the moving block (22), and the nozzles (23) are communicated with the storage chamber (5).

2. The piezoelectric ceramic production equipment with impurity removal function and intelligent charging function as claimed in claim 1, wherein the clamping assembly comprises a second motor (24), a first gear (25), a first connecting rod (32) and two clamping units, the second motor (24) is fixed on the inner wall of the housing (1), the second motor (24) is in transmission connection with the first gear (25), the two clamping units are respectively arranged at two sides of the first gear (25), the clamping units comprise a first rack (26), a sliding groove (27), a cross rod (28), a vertical rod (29), a second connecting rod (30) and a clamping block (31), the first rack (26) is arranged in the sliding groove (27), the first rack (26) is in sliding connection with the sliding groove (27), and one of the two sliding grooves (27) is fixed on the inner wall of the housing (1), inner wall fixed connection of another spout (27) through first connecting rod (32) and shell (1), the one end of horizontal pole (28) and the one end fixed connection of first rack (26), the other end of horizontal pole (28) and the top fixed connection of montant (29), the bottom of montant (29) and the one end fixed connection of second connecting rod (30), the other end and the clamp of second connecting rod (30) are got piece (31) fixed connection, it gets piece (31) and connecting rod (17) fixed connection to press from both sides.

3. The intelligent charging piezoelectric ceramic production equipment with impurity removing function according to claim 1, wherein the driving assembly comprises an air pump (6), an air cylinder (7) and a piston (8), the air pump (6) is fixed at the top of the inside of the shell (1), the air pump (6) is communicated with the air cylinder (7), the piston (8) is vertically arranged, the top end of the piston (8) is arranged in the air cylinder (7), and the bottom end of the piston (8) is fixedly connected with the connecting plate (9).

4. The intelligent charging piezoelectric ceramic production equipment with impurity removing function according to claim 2, wherein the lifting assembly comprises a third motor (33), a half gear (34), a moving frame (36), two guide rings (37) and two second racks (35), the third motor (33) is fixed on the inner wall of the housing (1), the third motor (33) is in transmission connection with the half gear (34), the two second racks (35) are respectively fixed on two sides in the moving frame (36), the half gear (34) is located between the two second racks (35), the half gear (34) is meshed with the second racks (35), the guide rings (37) are fixed on the inner wall of the housing (1), the guide rings (37) are sleeved on the moving frame (36), and the two guide rods (20) are respectively arranged at the top and the bottom of the moving frame (36), the lifting block (18) is fixedly connected with the movable frame (36).

5. The intelligent charging piezoelectric ceramic production equipment with impurity removal function as claimed in claim 4, wherein the half gear (34) is made of stainless steel.

6. The intelligent charging piezoelectric ceramic production equipment with impurity removal function according to claim 4, wherein the first motor (19), the second motor (24) and the third motor (33) are all servo motors.

7. The piezoelectric ceramic production device with impurity removal function and intelligent charging function as claimed in claim 2, wherein the sliding groove (27) is a dovetail groove.

8. The intelligent charging-capable piezoelectric ceramic production equipment with impurity removal function according to claim 1, wherein the connecting line (10) is a nylon line.

9. The intelligent charging piezoelectric ceramic production equipment with impurity removal function according to claim 1, wherein the first spring (4), the second spring (11) and the third spring (13) are all extension springs.

10. The intelligent charging piezoelectric ceramic production equipment with impurity removal function according to claim 2, wherein the two chutes (27) are arranged in parallel.