CN221026346U - Automatic receiving device for sintering control of thick film ceramic circuit board - Google Patents

Abstract

The utility model discloses an automatic material receiving device for sintering control of a thick film ceramic circuit board, which belongs to the technical field of automatic material receiving after sintering of a high-precision ceramic circuit board, and comprises an equipment main body and a feeding conveyor belt, wherein an adjustable adsorption assembly is arranged on the equipment main body; by the mode, the automatic material receiving function of the ceramic circuit board is realized, the material receiving working efficiency is greatly improved, the products are prevented from being damaged, the quality and the reliability of the products are improved, and the potential quality risks of the products caused by invisible damage of the products and the product bad risks caused by complete damage of the products are reduced.

Description

Automatic receiving device for sintering control of thick film ceramic circuit board

Technical Field

The utility model relates to the technical field of automatic material collection after sintering of a high-precision ceramic circuit board, in particular to an automatic material collection device for thick film ceramic circuit board sintering control.

Background

The processes of printing, via connection, sintering, laser resistance adjustment, etching, etc. in the production process of thick film printed ceramic circuit boards are typically performed on a large ceramic circuit substrate. The sintering process is very important in the production process of the thick film printed ceramic circuit board, and the automatic material receiving system can greatly save manpower and improve the production efficiency. The difficulty of the automatic material receiving system is that the traditional material receiving system is used for receiving ceramic plates on a sintering furnace chain onto a track through a material receiving fork, the ceramic plates are sometimes deflected when moving on the sintering furnace chain to contact the material receiving fork, and the deflected ceramic plates have risks of ceramic plate fragmentation or invisible damage when placed on the track, so that the invisible damage of the ceramic plates can lead to the risks of product quality reliability, and the enterprise reputation and the client application cost are seriously influenced. In order to prevent the risk, the automatic receiving device for sintering control of the thick film ceramic circuit board provided by the technical scheme is provided with the suction nozzle, the suction nozzle firstly sucks the ceramic sheet onto the receiving fork, and the receiving fork then places the ceramic sheet onto the track, so that the risks of cracking and invisible damage of the ceramic sheet can be greatly reduced, the reliability of products is greatly improved, the qualification rate of the products is improved, and meanwhile, the quality stability and reliability in the application of the products to customers are ensured. And the enterprise benefit and the social benefit are improved.

Based on the above, the utility model designs an automatic material receiving device for controlling the sintering of a thick film ceramic circuit board to solve the above problems.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model provides an automatic material receiving device for sintering control of a thick film ceramic circuit board.

In order to achieve the above purpose, the utility model is realized by the following technical scheme:

The utility model provides an automatic material collecting device of thick film ceramic circuit board sintering control, includes equipment main part and material loading conveyer belt, install adjustable adsorption component on the equipment main part, adjustable adsorption component's adsorption end is located adjustable adsorption component's top, adjustable adsorption component is used for absorbing the ceramic circuit board on the material loading conveyer belt, install on the equipment main part and transport drive assembly and unloading and transport the subassembly, transport drive assembly and unloading and transport the subassembly and connect, transport drive assembly and be used for transporting to unloading to transport the subassembly to adjustable adsorption component absorptive ceramic circuit board, unloading is transported the subassembly and is used for the unloading to the circuit board;

The transfer driving assembly comprises a driving assembly and a first transfer assembly, the driving assembly is arranged on the equipment main body, the first transfer assembly is movably connected with the driving assembly, and the first transfer assembly is connected with the blanking transfer assembly.

Still further, the equipment main part includes frame and mounting bracket, mounting bracket fixed mounting is in the upper end of frame, adjustable adsorption component, drive assembly, unloading are transported the subassembly and are all connected with the mounting bracket, the unloading is transported the subassembly and is installed on the frame, the tip of material loading conveyer belt extends to the top of frame.

Still further, adjustable adsorption component includes first adsorption component and adjusting part, first adsorption component has the multiunit, first adsorption component equidistant installs on adjusting part, adjusting part installs on the mounting bracket, first adsorption component's output is located the top of material loading conveyer belt.

Still further, first absorption subassembly includes suction nozzle, installation piece and first locating hole, suction nozzle fixed mounting is on the installation piece, and the suction nozzle is located the top of material conveyer belt, installation piece and adjusting part connect, set up the first locating hole that the cooperation adjusting part used on the installation piece.

Still further, the adjusting part includes mount table, second locating hole and bolt, mount table fixed mounting is in the inner of mounting bracket, mount table and installation piece contact connection, the second locating hole has been seted up on the mount table, second locating hole and first locating hole pass through bolt fixed connection.

Still further, the drive assembly includes motor, threaded rod and slide bar, motor fixed mounting is on the mounting bracket, the output fixed connection of threaded rod and motor, slide bar fixed mounting is on the mounting bracket and slide bar and threaded rod are parallel, slide bar, threaded rod all are connected with first transport subassembly.

Still further, first transfer subassembly includes mounting panel, sliding sleeve and connects the material fork, fixed mounting has the sliding sleeve on the mounting panel, sliding sleeve and slide bar sliding connection, mounting panel and threaded rod threaded connection, the lower extreme fixed mounting of mounting panel has connects the material fork, connect the material fork to use with unloading transfer subassembly cooperation.

Still further, unloading is transported subassembly and feed bin subassembly including unloading subassembly, second, unloading subassembly is installed on the frame, unloading subassembly and material receiving fork cooperation use, the data second is transported the subassembly and is all connected with frame and mounting bracket, feed bin subassembly and frame, unloading subassembly, second are transported the subassembly and are all connected.

Furthermore, the blanking assembly comprises a blanking conveying belt and a blocking fork, wherein the blanking conveying belt and the blocking fork are fixedly arranged at the upper end of the frame, the blocking fork is positioned at one side of the blanking conveying belt, which is close to the feeding conveying belt, and the blocking fork and the receiving fork are matched for sliding use;

the storage bin assembly comprises a jig main body and a chute, the jig main body is fixedly connected with the frame, the chute is arranged on the jig main body, and the second transfer assembly is connected with the chute;

The second transport assembly comprises an electric sliding rail, a first electric cylinder, an electric clamping jaw, a second electric cylinder and a push plate, wherein the electric sliding rail is fixedly installed on the installation frame, the first electric cylinder is fixedly installed at the output end of the electric sliding rail, the electric clamping jaw is fixedly installed at the output end of the first electric cylinder, the second electric cylinder is fixedly installed on the frame, and the push plate is fixedly installed at the output end of the second electric cylinder and is in sliding connection with the sliding chute.

Still further, still include the protection subassembly, the protection subassembly includes first apron, second apron and hinge, first apron fixed mounting is in the upper end of mounting bracket, pass through the hinge between second apron and the first apron and articulate.

Advantageous effects

When the ceramic circuit board feeding device is used, the ceramic circuit board on the feeding conveyor belt is adsorbed and fixed through the adjustable adsorption component, the ceramic circuit board at the adsorption end of the adjustable adsorption component is transported through the transport driving component, and then transported to the discharging transport component to complete discharging through the transport driving component, so that the risk of invisible damage or fragmentation of the ceramic circuit board when transported to the discharging transport component due to the fact that the ceramic circuit board on the transport driving component is directly transported is offset and cannot be transported accurately is avoided;

The utility model greatly improves the work efficiency of material collection, ensures that the product is not damaged, improves the quality and reliability of the product, and reduces the potential quality risk of the product caused by invisible damage of the product and the product bad risk caused by complete damage of the product. The device is simple in operation, convenient to maintain and high in operation efficiency. The whole sintering process of the product is automated.

When the suction nozzle spacing adjusting device is used, the first positioning holes formed in the mounting blocks are matched with the second positioning holes formed in the mounting tables at corresponding positions, and the first positioning holes and the second positioning holes are fixed through bolts, so that the distance between the suction nozzles is adjusted.

When the ceramic suction nozzle is used, the suction force can be adjusted according to the size of the ceramic sheet through the small valve on the suction nozzle, and the moving speed of the suction nozzle, the moving speed of the receiving fork and the waiting time of the receiving fork for waiting for products are adjusted through the control system.

When the feeding conveyor belt is used, the feeding conveyor belt is conveyed to a ceramic circuit board below the feeding conveyor belt to be adsorbed by the suction nozzle, the motor drives the threaded rod to rotate, the threaded rod drives the mounting plate and the sliding sleeve on the threaded rod to move, the mounting plate drives the material receiving fork to move to the suction nozzle, the ceramic circuit board positioned on the suction nozzle is conveyed to the material receiving fork, and the motor drives the first conveying component to reset;

When the ceramic circuit board feeding device is used, the material receiving fork is then scratched through the material blocking fork, the circuit board on the material receiving fork is left on the blanking conveying belt positioned on one side of the material blocking fork close to the feeding conveying belt, the blanking conveying belt drives the ceramic circuit board to move to the front end of the material blocking fork, when the fact that the ceramic circuit board is conveyed to the lower end of the electric clamping jaw is detected, the first electric cylinder is started to drive the electric clamping jaw to move downwards, meanwhile, the electric clamping jaw clamps the ceramic circuit board, the electric sliding rail is started to drive the ceramic circuit board to be conveyed to the upper side of the jig main body, meanwhile, the second electric cylinder drives the push plate to move upwards to the upper surface of the ceramic circuit board or contact the electric clamping jaw, at the moment, the electric clamping jaw is loosened, the ceramic circuit board is placed on the push plate, and the second electric cylinder drives the push plate to slide in the sliding groove, so that the ceramic circuit board is fed and stored.

When the automatic material collecting system is used, the first cover plate and the second cover plate are hinged through the hinge, so that operators are protected when the automatic material collecting system operates, the automatic material collecting system is stopped when an abnormality occurs, and the second cover plate is opened to treat the abnormality.

Drawings

In order to more clearly illustrate the embodiments of the present utility model or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below. It is evident that the drawings in the following description are only some embodiments of the present utility model and that other drawings may be obtained from these drawings without inventive effort for a person of ordinary skill in the art.

FIG. 1 is a perspective view of a main body structure of an automatic material receiving device for sintering control of a thick film ceramic circuit board;

FIG. 2 is a front view of the structure of an automatic material receiving device for sintering control of a thick film ceramic circuit board according to the utility model;

FIG. 3 is a left side view of the structure of an automatic material receiving device for sintering control of a thick film ceramic circuit board according to the utility model;

FIG. 4 is a perspective view of a main body structure of an automatic receiving device for controlling sintering of a thick film ceramic circuit board according to the present utility model;

FIG. 5 is a cross-sectional view taken along the direction A-A of FIG. 3;

fig. 6 is a sectional view taken along the B-B direction of fig. 2.

Reference numerals in the drawings represent respectively:

1. The system comprises a main body 11, a frame 12, a mounting bracket 2, a loading conveyor 3, an adjustable suction assembly 31, a first suction assembly 311, a suction nozzle 312, a mounting block 313, a first locating hole 32, an adjustment assembly 321, a mounting block 322, a second locating hole 323, a bolt 4, a transfer drive assembly 41, a drive assembly 411, a motor 412, a threaded rod 413, a slide bar 42, a first transfer assembly 421, a mounting plate 422, a sliding sleeve 423, a receiving fork 5, a blanking transfer assembly 51, a blanking assembly 511, a blanking conveyor 512, a blocking fork 52, a second transfer assembly 521, an electric slide rail 522, a first electric cylinder 523, an electric jaw 524, a second electric cylinder 525, a push plate 53, a bin assembly 531, a jig main body 532, a chute 6, a protective assembly 61, a first cover plate 62, a second cover plate 63, and a hinge.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present utility model more clear, the technical solutions of the embodiments of the present utility model will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present utility model. It will be apparent that the described embodiments are some, but not all, embodiments of the utility model. All other embodiments, which can be made by those skilled in the art based on the embodiments of the utility model without making any inventive effort, are intended to be within the scope of the utility model.

The utility model is further described below with reference to examples.

Example 1

Referring to fig. 1-6 of the specification, an automatic receiving device for sintering control of thick film ceramic circuit boards comprises a device main body 1 and a feeding conveyor belt 2, wherein an adjustable adsorption component 3 is installed on the device main body 1, an adsorption end of the adjustable adsorption component 3 is positioned above the adjustable adsorption component 3, the adjustable adsorption component 3 is used for sucking the ceramic circuit boards on the feeding conveyor belt 2, a transfer driving component 4 and a blanking transfer component 5 are installed on the device main body 1, the transfer driving component 4 is connected with the blanking transfer component 5, the transfer driving component 4 is used for transferring the ceramic circuit boards adsorbed by the adjustable adsorption component 3 to the blanking transfer component 5, and the blanking transfer component 5 is used for blanking the circuit boards;

The transferring driving assembly 4 comprises a driving assembly 41 and a first transferring assembly 42, the driving assembly 41 is arranged on the equipment main body 1, the first transferring assembly 42 is movably connected with the driving assembly 41, and the first transferring assembly 42 is connected with the blanking transferring assembly 5.

The ceramic circuit board transported by the feeding conveyor belt 2 is adsorbed by the adjustable adsorption component 3, and the first transfer component 42 is driven by the driving component 41 to move, so that the driving component 41 transfers the ceramic circuit board to the discharging transfer component 5 matched with the ceramic circuit board, and the ceramic circuit board is prevented from being cracked when the ceramic circuit board on the feeding conveyor belt 2 is directly transferred by the transfer driving component 4 and cannot be precisely transferred, and the ceramic circuit board is transferred to the discharging transfer component 5; the ceramic circuit board is subjected to blanking, transferring and storing through the blanking transferring assembly 5; the automatic material receiving quality requirement of the ceramic circuit board is realized, the product rejection rate is reduced, the device is convenient to operate and maintain, and the operation efficiency is high.

Example 2

In some embodiments, as shown in fig. 1-6, the apparatus body 1 includes a frame 11 and a mounting frame 12, the mounting frame 12 is fixedly mounted at an upper end of the frame 11, the adjustable adsorption assembly 3, the driving assembly 41, and the blanking transfer assembly 5 are all connected with the mounting frame 12, the blanking transfer assembly 5 is mounted on the frame 11, and an end portion of the feeding conveyor belt 2 extends above the frame 11.

The adjustable adsorption component 3 comprises a first adsorption component 31 and an adjusting component 32, wherein the first adsorption component 31 is provided with a plurality of groups, the first adsorption component 31 is arranged on the adjusting component 32 at equal intervals, the adjusting component 32 is arranged on the mounting frame 12, and the output end of the first adsorption component 31 is positioned above the feeding conveyor belt 2.

The first adsorption component 31 comprises a suction nozzle 311, a mounting block 312 and a first positioning hole 313, the suction nozzle 311 is fixedly mounted on the mounting block 312, the suction nozzle 311 is positioned above the material conveying belt 2, the mounting block 312 is connected with the adjusting component 32, and the mounting block 312 is provided with the first positioning hole 313 matched with the adjusting component 32.

The adjusting component 32 comprises a mounting table 321, a second positioning hole 322 and a bolt 323, wherein the mounting table 321 is fixedly arranged at the inner end of the mounting frame 12, the mounting table 321 is in contact connection with the mounting block 312, the mounting table 321 is provided with the second positioning hole 322, and the second positioning hole 322 is fixedly connected with the first positioning hole 313 through the bolt 323.

The driving assembly 41 comprises a motor 411, a threaded rod 412 and a sliding rod 413, wherein the motor 411 is fixedly arranged on the mounting frame 12, the threaded rod 412 is fixedly connected with the output end of the motor 411, the sliding rod 413 is fixedly arranged on the mounting frame 12 and parallel to the threaded rod 413, and the sliding rod 413 and the threaded rod 412 are connected with the first transferring assembly 42.

The first transfer assembly 42 comprises a mounting plate 421, a sliding sleeve 422 and a receiving fork 423, the sliding sleeve 422 is fixedly mounted on the mounting plate 421, the sliding sleeve 422 is slidably connected with the sliding rod 413, the mounting plate 421 is in threaded connection with the threaded rod 412, the receiving fork 423 is fixedly mounted at the lower end of the mounting plate 421, and the receiving fork 423 and the blanking transfer assembly 5 are matched for use.

The unloading is transported subassembly 5 includes unloading subassembly 51, second and is transported subassembly 52 and feed bin subassembly 53, and unloading subassembly 51 is installed on frame 11, and unloading subassembly 51 and material receiving fork 423 cooperation are used, and data second is transported subassembly 52 and frame 11 and mounting bracket 12 all are connected, and feed bin subassembly 53 and frame 11, unloading subassembly 51, second are transported subassembly 52 and all are connected.

The blanking assembly 51 comprises a blanking conveying belt 511 and a blocking fork 512, the blanking conveying belt 511 and the blocking fork 512 are fixedly arranged at the upper end of the frame 11, the blocking fork 512 is positioned at one side of the blanking conveying belt 511, which is close to the feeding conveying belt 2, and the blocking fork 512 and the receiving fork 423 are matched for sliding use;

The bin assembly 53 comprises a jig main body 531 and a chute 532, the jig main body 531 is fixedly connected with the frame 11, the chute 532 is arranged on the jig main body 531, and the second transfer assembly 52 is connected with the chute 532;

The second transfer assembly 52 includes an electric slide rail 521, a first electric cylinder 522, an electric clamping jaw 523, a second electric cylinder 524, and a push plate 525, wherein the electric slide rail 521 is fixedly mounted on the mounting frame 12, the first electric cylinder 522 is fixedly mounted at an output end of the electric slide rail 521, the electric clamping jaw 523 is fixedly mounted at an output end of the first electric cylinder 522, the second electric cylinder 524 is fixedly mounted on the frame 11, and the push plate 525 is fixedly mounted at an output end of the second electric cylinder 524 and is slidably connected with the slide slot 532.

And the control system is electrically connected with the suction nozzle 311 and the motor 411.

The ceramic circuit board transported by the feeding conveyor belt 2 is adsorbed by the adjustable adsorption component 3, and the first transporting component 42 is driven by the driving component 41 to move, so that the driving component 41 transports the ceramic circuit board to the discharging transporting component 5 matched with the driving component for use, and the discharging, transporting and storing of the ceramic circuit board are realized by the discharging transporting component 5.

Preferably, the fork end of the receiving fork 423 is an L-shaped fork, the fork end of the retaining fork 512 is an I-shaped fork, and the L-shaped fork and the I-shaped fork are in sliding connection.

The first positioning holes 313 formed in the mounting block 312 are matched with the second positioning holes 322 formed in the mounting table 321 at the corresponding positions, and the first positioning holes 313 and the second positioning holes 322 are fixed through bolts 323, so that the distance between the suction nozzles 311 is adjusted.

The suction force can be adjusted according to the size of the ceramic wafer through a small valve on the suction nozzle 311, and the moving speed of the suction nozzle 311, the moving speed of the receiving fork 423 and the waiting time of the receiving fork 423 for waiting for products are adjusted through a control system.

The ceramic circuit board below the feeding conveyor belt 2 is transported to be adsorbed by the suction nozzle 311, the motor 411 drives the threaded rod 412 to rotate, the threaded rod 412 drives the mounting plate 421 and the sliding sleeve 422 on the mounting plate 421 to move on the sliding rod 413, the mounting plate 421 drives the material receiving fork 423 to move to the suction nozzle 311, the ceramic circuit board positioned on the suction nozzle 311 is transported to the material receiving fork 423, and the motor 411 drives the first transporting component 42 to reset;

Then the receiving fork 423 slides over the blocking fork 512, the circuit board on the receiving fork is left on the discharging conveying belt 511 positioned on one side of the blocking fork 512 close to the feeding conveying belt 2, the discharging conveying belt 511 drives the ceramic circuit board to move to the front end of the receiving fork, when the fact that the ceramic circuit board is conveyed to the lower end of the electric clamping jaw (523) is detected, the first electric cylinder 522 is started to drive the electric clamping jaw 523 to move downwards, meanwhile, the electric clamping jaw 523 clamps the ceramic circuit board, the electric sliding rail 521 is started, the ceramic circuit board is driven to be conveyed to the upper side of the jig main body 531, meanwhile, the second electric cylinder 524 drives the push plate 525 to move upwards to the upper surface of the receiving fork or contact the ceramic circuit board on the upper surface of the receiving fork, the electric clamping jaw 523 is loosened at the moment, the second electric cylinder 524 drives the push plate 525 to slide in the sliding groove 532, and accordingly discharging and storing of the ceramic circuit board are achieved.

Example 3

In some embodiments, as shown in fig. 1-6, the protective assembly 6 further includes a protective assembly 6, where the protective assembly 6 includes a first cover 61, a second cover 62, and a hinge 63, the first cover 61 is fixedly mounted on an upper end of the mounting frame 12, and the second cover 62 is hinged to the first cover 61 by the hinge 63.

Through the hinge 63 between the first cover plate 61 and the second cover plate 62, the protection of operators during the operation of the automatic material receiving system is realized, the automatic material receiving system is stopped when abnormality occurs, and the second cover plate 62 is opened to treat the abnormality.

The above embodiments are only for illustrating the technical solution of the present utility model, and are not limiting; although the utility model has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some technical features thereof can be replaced by equivalents; such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present utility model.

Claims (10)

1. The utility model provides an automatic material collecting device of thick film ceramic circuit board sintering control, includes equipment main part (1) and material loading conveyer belt (2), its characterized in that: install adjustable adsorption component (3) on equipment main part (1), the adsorption end of adjustable adsorption component (3) is located the top of adjustable adsorption component (3), adjustable adsorption component (3) are used for absorbing the ceramic circuit board on material loading conveyer belt (2), install on equipment main part (1) and transport drive assembly (4) and unloading and transport subassembly (5), transport drive assembly (4) and unloading and transport subassembly (5) and connect, transport drive assembly (4) are used for transporting to unloading to transport subassembly (5) to adjustable adsorption component (3) absorptive ceramic circuit board, unloading is transported subassembly (5) and is used for the unloading to the circuit board;

The transfer driving assembly (4) comprises a driving assembly (41) and a first transfer assembly (42), the driving assembly (41) is installed on the equipment main body (1), the first transfer assembly (42) is movably connected with the driving assembly (41), and the first transfer assembly (42) is connected with the blanking transfer assembly (5).

2. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 1, wherein: the equipment main body (1) comprises a frame (11) and a mounting frame (12), the mounting frame (12) is fixedly mounted at the upper end of the frame (11), the adjustable adsorption component (3), the driving component (41) and the blanking transfer component (5) are connected with the mounting frame (12), the blanking transfer component (5) is mounted on the frame (11), and the end part of the feeding conveyor belt (2) extends to the upper side of the frame (11).

3. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 2, wherein: the adjustable adsorption component (3) comprises a first adsorption component (31) and an adjusting component (32), wherein the first adsorption component (31) is provided with a plurality of groups, the first adsorption component (31) is arranged on the adjusting component (32) at equal intervals, the adjusting component (32) is arranged on the mounting frame (12), and the output end of the first adsorption component (31) is positioned above the feeding conveyor belt (2).

4. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 3, wherein: the first adsorption component (31) comprises a suction nozzle (311), a mounting block (312) and a first positioning hole (313), wherein the suction nozzle (311) is fixedly arranged on the mounting block (312), the suction nozzle (311) is positioned above the material conveying belt (2), the mounting block (312) is connected with the adjusting component (32), and the mounting block (312) is provided with the first positioning hole (313) matched with the adjusting component (32).

5. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 4, wherein: the adjusting component (32) comprises a mounting table (321), a second positioning hole (322) and a bolt (323), wherein the mounting table (321) is fixedly arranged at the inner end of the mounting frame (12), the mounting table (321) is in contact connection with the mounting block (312), the mounting table (321) is provided with the second positioning hole (322), and the second positioning hole (322) and the first positioning hole (313) are fixedly connected through the bolt (323).

6. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 5, wherein: the driving assembly (41) comprises a motor (411), a threaded rod (412) and a sliding rod (413), wherein the motor (411) is fixedly installed on the installation frame (12), the threaded rod (412) is fixedly connected with the output end of the motor (411), the sliding rod (413) is fixedly installed on the installation frame (12) and is parallel to the threaded rod (413), and the sliding rod (413) and the threaded rod (412) are connected with the first transfer assembly (42).

7. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 6, wherein: the first transfer assembly (42) comprises a mounting plate (421), a sliding sleeve (422) and a receiving fork (423), the sliding sleeve (422) is fixedly installed on the mounting plate (421), the sliding sleeve (422) is in sliding connection with a sliding rod (413), the mounting plate (421) is in threaded connection with a threaded rod (412), the receiving fork (423) is fixedly installed at the lower end of the mounting plate (421), and the receiving fork (423) and the discharging transfer assembly (5) are matched for use.

8. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 7, wherein: unloading is transported subassembly (5) and is included unloading subassembly (51), second and is transported subassembly (52) and feed bin subassembly (53), unloading subassembly (51) are installed on frame (11), unloading subassembly (51) and connect fork (423) cooperation use, second is transported subassembly (52) and frame (11), mounting bracket (12) all are connected, feed bin subassembly (53) and frame (11), unloading subassembly (51), second are transported subassembly (52) all and are connected.

9. The automatic material receiving device for sintering control of thick film ceramic circuit boards according to claim 8, wherein: the blanking assembly (51) comprises a blanking conveying belt (511) and a blocking fork (512), the blanking conveying belt (511) and the blocking fork (512) are fixedly arranged at the upper end of the frame (11), the blocking fork (512) is positioned at one side, close to the feeding conveying belt (2), of the blanking conveying belt (511), and the blocking fork (512) and the receiving fork (423) are matched and used in a sliding mode;

the bin assembly (53) comprises a jig main body (531) and a chute (532), the jig main body (531) is fixedly connected with the frame (11), the chute (532) is arranged on the jig main body (531), and the second transfer assembly (52) is connected with the chute (532);

The second transfer assembly (52) comprises an electric sliding rail (521), a first electric cylinder (522), an electric clamping jaw (523), a second electric cylinder (524) and a push plate (525), wherein the electric sliding rail (521) is fixedly installed on the installation frame (12), the first electric cylinder (522) is fixedly installed at the output end of the electric sliding rail (521), the electric clamping jaw (523) is fixedly installed at the output end of the first electric cylinder (522), the second electric cylinder (524) is fixedly installed on the frame (11), and the push plate (525) is fixedly installed at the output end of the second electric cylinder (524) and is in sliding connection with the sliding groove (532).

10. The automatic material receiving device for thick film ceramic circuit board sintering control according to claim 9, wherein: the novel protective device comprises a mounting rack (12), and is characterized by further comprising a protective component (6), wherein the protective component (6) comprises a first cover plate (61), a second cover plate (62) and a hinge (63), the first cover plate (61) is fixedly mounted at the upper end of the mounting rack (12), and the second cover plate (62) is hinged with the first cover plate (61) through the hinge (63).