CN112777318A - Fortune material mechanism and silk screen printing equipment - Google Patents

Abstract

The invention discloses a material conveying mechanism and screen printing equipment, wherein the material conveying mechanism is applied to the screen printing equipment and comprises a transmission structure and a material carrying structure, a feeding station and a printing station are formed on the transmission structure, the material carrying structure comprises a first objective table and a second objective table, the first objective table and the second objective table are both connected with the transmission structure, the transmission structure can drive the first objective table and the second objective table to reciprocate between the feeding station and the printing station, and the moving direction of the first objective table is opposite to that of the second objective table. The application provides a fortune material mechanism can realize the printing and go on in step with last unloading, waits for the time of unloading when can saving the silk screen printing, improves the work efficiency of silk screen printing equipment.

Description

Fortune material mechanism and silk screen printing equipment

Technical Field

The invention relates to the technical field of silk screen printing, in particular to a material conveying mechanism and silk screen printing equipment.

Background

In the glass processing industry, various patterns are often required to be printed on the surface of glass to enhance the decorative effect of the glass. Because the screen printing has the characteristics of small imprinting force, strong covering force of ink and the like, the screen printing mode is usually adopted for printing patterns on the surface of glass at present. However, in the existing screen printing equipment, after one workpiece to be printed is printed and discharged, the next workpiece to be printed can be loaded and printed, which takes long time for printing and has low printing efficiency.

Disclosure of Invention

The invention mainly aims to provide a material conveying mechanism, aiming at improving the printing efficiency and reducing the printing time.

In order to achieve the above object, the present invention provides a material transporting mechanism for a screen printing apparatus, the material transporting mechanism comprising:

the conveying structure is provided with a feeding station and a printing station; and

carry the material structure, carry the material structure and include first objective table and second objective table, first objective table with the second objective table all with transmission structure connects, transmission structure can drive first objective table with the second objective table in material loading station with reciprocating motion between the printing station, the moving direction of first objective table with the moving direction of second objective table is opposite.

In an embodiment of the present application, the transmission structure includes:

the first object stage and the second object stage are connected with the two supports in a sliding mode and located in the sliding space; and

and the driving assembly is connected with the first object stage and the second object stage and can drive the first object stage and the second object stage to reciprocate between the feeding station and the printing station along the support.

In an example embodiment of the present application, the bracket is provided with a first slide rail and a second slide rail, a first sliding space is formed between the first slide rails of the two brackets, a second sliding space is formed between the second slide rails of the two brackets, the first stage is slidably connected to the first slide rail and slides in the first sliding space, and the second stage is slidably connected to the second slide rail and slides in the second sliding space.

In an embodiment of the present application, the first slide rail is disposed on a side surface of one of the brackets facing the other bracket, and the second slide rail is disposed on an upper surface of the bracket.

In an embodiment of the present application, the transmission structure further includes two connecting members, where the two connecting members are slidably connected to the first slide rail and the second slide rail respectively;

the first object stage and the second object stage are respectively connected with one connecting piece, and the two connecting pieces are connected with the driving assembly.

In one embodiment of the present application, the connector includes:

the main body part is connected to the first slide rail or the second slide rail in a sliding mode, and the first object stage and the second object stage are respectively connected with the main body part of one connecting piece; and

and two opposite ends of the connecting part are respectively connected with the main body part and the driving component.

In one embodiment of the present application, the driving assembly includes:

a drive member; and

the driving part can drive the driving part to move and can drive the first objective table and the second objective table to respectively slide along the first slide rail and the second slide rail.

In an embodiment of the application, a driving wheel is disposed at an end of the driving member connected to the transmission member, the connecting member is connected to the transmission member at an interval, and the driving member can drive the driving wheel to rotate and drive the transmission member to rotate.

In an embodiment of the application, the connecting member is fixedly connected to the transmission member, and an insertion hole through which the transmission member passes is formed at an end of the connecting member connected to the transmission member.

The invention also provides a screen printing device, which comprises a screen printing mechanism and a material conveying mechanism, wherein the material conveying mechanism comprises:

the conveying structure is provided with a feeding station and a printing station; and

carry the material structure, carry the material structure and include first objective table and second objective table, first objective table with the second objective table all with transmission structure connects, transmission structure can drive first objective table with the second objective table in material loading station with reciprocating motion between the printing station, the moving direction of first objective table with the moving direction of second objective table is opposite.

The material conveying mechanism provided by the technical scheme of the invention is applied to screen printing equipment, and comprises a transmission structure and a material loading structure, wherein the material loading structure is provided with a first objective table and a second objective table, and a feeding station and a printing station are formed on the transmission structure. When silk screen printing equipment operated, first objective table and second objective table reciprocating motion between material loading station and printing station can be driven to transmission structure to when making the work piece of treating printing on the first objective table transferred to the printing station and prints, the second objective table can be with accomplishing another work piece of treating printing of printing and transferring to the material loading station and carry out the unloading, and will wait to print the work piece material loading next to be located the second objective table of material loading station on. And after the workpiece to be printed on the first objective table is printed, repeating the steps. The application provides a fortune material mechanism can realize the printing and go on in step with going up unloading to material time of waiting for when saving the silk screen printing improves the work efficiency of silk screen printing equipment.

Drawings

In order to more clearly illustrate the embodiments of the present invention 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 obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of a screen printing apparatus according to an embodiment of the present invention;

FIG. 2 is a schematic view of a material conveying mechanism according to an embodiment of the present invention;

fig. 3 is a schematic structural diagram of another view angle of the material conveying mechanism according to an embodiment of the present invention.

The reference numbers illustrate:

the implementation, functional features and advantages of the objects of the present invention will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

It should be noted that all the directional indicators (such as up, down, left, right, front, and rear … …) in the embodiment of the present invention are only used to explain the relative position relationship between the components, the movement situation, etc. in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indicator is changed accordingly.

In addition, the descriptions related to "first", "second", etc. in the present invention are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the meaning of "and/or" appearing throughout is to include three juxtapositions, exemplified by "A and/or B," including either the A or B arrangement, or both A and B satisfied arrangement. In addition, technical solutions between various embodiments may be combined with each other, but must be realized by a person skilled in the art, and when the technical solutions are contradictory or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope of the present invention.

Referring to fig. 1 to 3, the present invention provides a material conveying mechanism 10, and the material conveying mechanism 10 is applied to a screen printing apparatus 1000 for conveying a workpiece 300 to be printed to print a printing material on a surface of the workpiece 300 to be printed.

In an example embodiment of the present application, the material conveying mechanism 10 includes a conveying structure 11 and a material loading structure 13, the conveying structure 11 is formed with a loading station 11a and a printing station 11b, the material loading structure 13 includes a first object stage 131 and a second object stage 133, the first object stage 131 and the second object stage 133 are both connected to the conveying structure 11, the conveying structure 11 can drive the first object stage 131 and the second object stage 133 to move back and forth between the loading station 11a and the printing station 11b, and a moving direction of the first object stage 131 is opposite to a moving direction of the second object stage 133.

First stage 131 and second stage 133 include a stage body 1311 and a stage plate 1313, where stage body 1311 may be plate-shaped, shelf-shaped, or the like, as long as it can support stage plate 1313 and workpiece 300 to be printed on stage plate 1313. The stage body 1311 and the stage plate 1313 are provided with a relief hole 131a at a corresponding position for the positioning mechanism of the screen printing apparatus 1000 to perform position correction on the workpiece 300 to be printed placed on the stage plate 1313. Thus, the positioning mechanism can be arranged below the material conveying mechanism 10 during arrangement, so that the distribution and arrangement are convenient, and the installation space is saved. It can be understood that the object plate 1313 and the object table body 1311 may be integrally formed for convenience of manufacturing, and may also be detachably connected as a whole by bolt-nut connection, snap connection, or the like for convenience of replacing the object plate 1313 to adapt to workpieces 300 to be printed in different sizes.

The material conveying mechanism 10 provided by the technical scheme of the invention is applied to the screen printing equipment 1000, the material conveying mechanism 10 comprises a transmission structure 11 and a material loading structure 13, the material loading structure 13 is provided with a first object stage 131 and a second object stage 133, and the transmission structure 11 is provided with a feeding station 11a and a printing station 11 b. When the screen printing apparatus 1000 is in operation, the transmission structure 11 may drive the first stage 131 and the second stage 133 to reciprocate between the feeding station 11a and the printing station 11b, so that when the workpiece 300 to be printed on the first stage 131 is transferred to the printing station 11b for printing, the second stage 133 may transfer another workpiece 300 to be printed, which has been printed, to the feeding station 11a for blanking, and feed the next workpiece 300 to be printed onto the second stage 133 located at the feeding station 11 a. After waiting for the workpiece 300 to be printed on the first stage 131 to be printed, the above steps are repeated. Please provide fortune material mechanism 10 itself can realize that printing and unloading go on in step to save the time of waiting for unloading in the silk screen printing, improve the work efficiency of silk screen printing equipment 1000.

Referring to fig. 2, in an exemplary embodiment of the present disclosure, the conveying structure 11 includes two brackets 111 and a driving assembly 113, the two brackets 111 are spaced apart from each other and form a sliding space, the first stage 131 and the second stage 133 are slidably connected to the two brackets 111 and located in the sliding space, and the driving assembly 113 is connected to the first stage 131 and the second stage 133 and can drive the first stage 131 and the second stage 133 to reciprocate between the loading station 11a and the printing station 11b along the brackets 111.

The holder 111 may be made of a metal type material, and may have a plate shape or a rod shape. The two brackets 111 may position the first stage 131 and the second stage 133 at the installation positions, that is, opposite sides of the first stage 131 are connected to the two brackets 111, respectively, and opposite sides of the second stage 133 are connected to the two brackets 111, respectively, so that the first stage 131 and the second stage 133 may be in a sliding space formed with the two brackets 111. The two brackets 111 are connected with the first object stage 131 and the second object stage 133, so that the structural strength of the installation of the first object stage 131 and the second object stage 133 can be enhanced, the stability of the installation of the first object stage 131 and the second object stage 133 is improved, and the first object stage 131 and the second object stage 133 are prevented from shaking when the workpiece 300 to be printed is carried. When the first object stage 131 and the second object stage 133 slide along the support 111 in the sliding space, the support 111 can also guide the first object stage 131 and the second object stage 133 to ensure that the first object stage 131 and the second object stage 133 can move to the loading station 11a or the printing station 11b, and the first object stage 131 and the second object stage 133 are prevented from deviating from the direction during movement.

Referring to fig. 2, in an embodiment of the present disclosure, the bracket 111 may further include a first sliding rail 1111 and a second sliding rail 1113, a first sliding space is formed between the first sliding rails 1111 of the two brackets 111, a second sliding space is formed between the second sliding rails 1113 of the two brackets 111, the first stage 131 is slidably connected to the first sliding rails 1111 and slides in the first sliding space, and the second stage 133 is slidably connected to the second sliding rails 1113 and slides in the second sliding space.

When the workpiece 300 to be printed is transported, the first stage 131 slides along the first slide rail 1111 in the first sliding space, and the second stage 133 slides along the second slide rail 1113 in the second sliding space. The first object stage 131 and the second object stage 133 are respectively connected with the first slide rail 1111 and the second slide rail 1113 of the bracket 111, so that the friction force generated by the bracket 111 when the first object stage 131 and the second object stage 133 slide relative to the bracket 111 can be reduced, the first object stage 131 and the second object stage 133 can slide more smoothly, and the situations of blocking and bumping in the process of conveying the workpiece 300 to be printed by the material conveying mechanism 10 are avoided. Meanwhile, since the friction force is reduced, the power required to be applied when the first stage 131 and the second stage 133 are driven to slide can be reduced, and the friction loss of the bracket 111 can be reduced.

In an embodiment of the present application, referring to fig. 2, the direction indicated by H in fig. 2 is a bottom-to-top direction. The first sliding rail 1111 is disposed on a side surface of one of the brackets 111 facing the other bracket 111, and the second sliding rail 1113 is disposed on an upper surface of the bracket 111. With such an arrangement, a height difference can be formed between the first stage 131 and the second stage 133, so that the driving assembly 113 can be ensured not to interfere with each other when pushing the first stage 131 and the second stage 133 to move in opposite directions, and further, when the first stage 131 and the second stage 133 transmit the workpiece 300 to be printed, the workpiece 300 to be printed can not be damaged by friction or fall off.

Referring to fig. 3, in an embodiment of the present application, the transmission structure 11 further includes two connecting members 115, where the two connecting members 115 are slidably connected to the first sliding rail 1111 and the second sliding rail 1113, respectively; the first stage 131 and the second stage 133 are respectively connected to one of the connectors 115, and both of the connectors 115 are connected to the driving assembly 113.

In this embodiment, the connecting member 115 includes a main body 1151 and a connecting portion 1153, the main body 1151 is provided with a mounting surface 115b for mounting the first object stage 131 and the second object stage 133, so that the connecting member 115 is in surface contact with the first object stage 131 and the second object stage 133, and thus when the driving assembly 113 is driven by the connecting member 115 to slide with the first object stage 131 and the second object stage 133, the range of driving force applied to the first object stage 131 and the second object stage 133 is larger and more uniform, and the driving assembly is more easily pushed. For easy replacement, the first stage 131 and the second stage 133 may be provided with screws or pins, and the mounting surface 115b of the connecting member 115 is correspondingly provided with screw holes or pin holes, so that the first stage 131 and the second stage 133 can be detachably connected to the connecting member 115. The connecting piece 115, the first object stage 131 and the second object stage 133 can be detachably connected into a whole, so that the manufacturing and installation can be facilitated, and the manufacturing difficulty is reduced. The driving assembly 113 is connected with the first object stage 131 and the second object stage 133 through the connecting piece 115, and the driving assembly 113 can be connected at any position of the first object stage 131 and the second object stage 133 according to use requirements during manufacturing, so that the installation space of the driving assembly 113 and the first object stage 131 and the second object stage 133 is saved, and the manufacturing and installation are facilitated.

Referring to fig. 3, in an exemplary embodiment of the present application, the connecting member 115 includes a main body 1151 and a connecting portion 1153, the main body 1151 is slidably connected to the first rail 1111 or the second rail 1113, the first stage 131 and the second stage 133 are respectively connected to the main body 1151 of one connecting member 115, and opposite ends of the connecting portion 1153 are respectively connected to the main body 1151 and the driving assembly 113.

In this embodiment, the main body 1151 of the connecting member 115 is fixed to the bracket 111, and may be directly slidably connected to the first sliding rail 1111 and the second sliding rail 1113, or may be additionally provided with a sliding member 117 and connected to the first sliding rail 1111 and the second sliding rail 1113 through the sliding member 117. The sliding parts 117 can be arranged at intervals, and one side of each sliding part 117, which faces away from the first sliding rail 1111 or the second sliding rail 1113, is connected with the connecting part 115, so that the difficulty in manufacturing and installing the connecting part 115 is reduced, and the material for manufacturing the connecting part 1153 between the connecting part 115 and the first sliding rail 1111 or the second sliding rail 1113 is also reduced.

The first object stage 131 and the second object stage 133 are connected to the bracket 111 through the main body 1151 of the connecting member 115 and connected to the driving assembly 113 through the connecting portion 1153 of the connecting member 115, so that the connection strength between the first object stage 131 and the bracket 111 and the second object stage 133 and the bracket 111 are enhanced while the first object stage 131 and the second object stage 133 are ensured to be driven by the driving assembly 113 to reciprocate between the loading station 11a and the printing station 11b along with the connecting member 115, and the problem that the first object stage 131 and the second object stage 133 fall off when being directly connected to the first slide rail 1111 and the second slide rail 1113 and sliding can be prevented.

It is understood that the first stage 131 and the second stage 133 can be directly driven by the driving assembly 113, for example, the driving assembly 113 can be a pneumatic cylinder or a hydraulic cylinder, etc., and the output end thereof can be directly connected to the first stage 131 or the second stage 133 to push the first stage 131 and the second stage 133 to slide along the first slide 1111 and the second slide 1113, respectively. Of course, the first stage 131 may also be indirectly driven by the driving assembly 113.

Referring to fig. 2, in an exemplary embodiment of the present application, the driving assembly 113 includes a driving member 1131 and a transmission member 1133, the transmission member 1133 is connected to the driving member 1131, the two connection members 115 are connected to the transmission member 1133, and the driving member 1131 can drive the transmission member 1133 to move and can drive the first object stage 131 and the second object stage 133 to slide along the first slide 1111 and the second slide 1113, respectively, through the connection members 115.

In this embodiment, the driving member 1131 may be a motor, preferably a servo motor, which has high precision and high precision of rotation, so as to facilitate control of the speed of rotation of the transmission member 1133, and thus to better control the speed and position of the transmission of the first stage 131 and the second stage 133. Of course, the motor may be a stepping motor. The transmission member 1133 may be a transmission device such as a chain or a belt, when the transmission member 1133 is a chain or a belt, one end of the transmission member is fixed to the output end of the driving member 1131 through a transmission wheel 1135, the other end of the transmission member is fixed by the frame 900 (not shown) of the screen printing apparatus 1000, and the two connection members 115 are installed at different positions of the transmission member 1133 at intervals. The driving member 1133 can rotate clockwise or counterclockwise by the driving of the motor, so as to drive the connecting member 115 and the first stage 131 and the second stage 133 connected to the connecting member 115 to move toward the loading station 11a or the printing station 11 b. The driving element 1131 can be installed at any position according to the requirement by an indirect driving mode, and any kind of driving element 1131 and transmission element 1133 can be selected according to the requirement.

Referring to fig. 2, in an embodiment of the present application, a driving wheel 1135 is disposed at one end of the driving member 1131 connected to the transmission member 1133, the connecting member 115 is connected to the transmission member 1133 at intervals, and the driving member 1131 can drive the driving wheel 1135 to rotate and drive the transmission member 1133 to rotate.

The transmission wheel 1135 is disposed such that the transmission members 1133 do not interfere with each other when rotating, thereby affecting the transmission effect. Because the diameter of drive wheel 1135 is greater than the diameter of driving piece 1131 output, compare in that the output of driving piece 1131 is directly connected with driving piece 1133, under the same rotational speed, the same time can move longer distance when driving piece 1133 is connected with drive wheel 1135, consequently add drive wheel 1135 and be connected with driving piece 1133 and can accelerate the moving speed of the driving piece 1131 of being connected with driving piece 1133 under the same power condition, thereby can accelerate the speed that first objective table 131 and second objective table 133 transmit and wait to print work piece 300, further reduce the time of whole printing process, improve printing efficiency, reduce required cost such as electric energy when using.

Referring to fig. 3, in an embodiment of the present application, the connecting member 115 is fixedly connected to the transmission member 1133, and an end of the connecting member 115 connected to the transmission member 1133 is provided with a socket 115a for passing the transmission member 1133.

The transmission member 1133 penetrates through the insertion hole 115a formed in the connection member 115, and the transmission member 1133 is inserted and fixed into the insertion hole 115a formed in the connection member 115, so that the connection strength between the connection member 115 and the transmission member 1133 can be enhanced, the connection between the transmission member 1133 and the connection member 115 is firmer, and the connection member 115 is prevented from falling off along with the movement of the transmission member 1133, and the normal operation of the material transporting mechanism 10 is prevented from being influenced.

The invention further provides a screen printing device 1000, the screen printing device 1000 includes a screen printing mechanism 30 and a material conveying mechanism 10, the specific structure of the material conveying mechanism 10 refers to the above embodiments, and since the screen printing device 1000 adopts all the technical solutions of all the above embodiments, at least all the beneficial effects brought by the technical solutions of the above embodiments are achieved, and no further description is given here. Wherein the silk-screen printing mechanism 30 is used for printing the workpiece 300 to be printed, which is conveyed to the printing station 11b by the material conveying mechanism 10, so as to print a pattern on the surface of the workpiece 300 to be printed.

Specifically, referring to fig. 1, a screen printing apparatus 1000 adopted in the present application may include a frame 900, a material preparing apparatus 500, a dust removing apparatus 700, and a screen printing apparatus 100. The rack 900 is provided with a material conveying mechanism 91 for conveying materials so as to convey the workpiece 300 to be printed among the material preparing device 500, the dust removing device 700 and the screen printing device 100, and the screen printing device 100 comprises a screen printing mechanism 30 and a material conveying mechanism 10. Feed mechanism establishes, is formed with on the transport structure 51 and gets the material station, and transport structure 51 can adopt modes such as belt transmission to convey.

The material preparing apparatus 500 includes a conveying structure 51, a feeding structure 53, and a taking structure 55, and the material preparing apparatus 500 is formed with a feeding area 500a, a feeding area 500b, and a taking area 500c in this order along a conveying direction (a direction indicated by a in fig. 1) of the conveying structure 51. The feeding structure 53 is disposed in the feeding area 500a, and is configured to provide the material rack carrying the workpiece 300 to be printed to the conveying structure 51, and the conveying structure 51 is configured to convey the material rack to the feeding area 500b along a conveying direction, so that the material conveying mechanism 91 transfers the workpiece 300 to be printed on the material rack to the dust removing device 700. The workpiece 300 to be printed after the screen printing is transferred to the feeding area 500b by the material transporting mechanism 10 again, and the material taking structure 55 disposed in the feeding area 500b takes the workpiece 300 to be printed off from the material transporting mechanism 10, so that the workpiece 300 to be printed can be transported to the material taking area 500c by the transporting structure 51.

The dust removing device 700 comprises an object placing plate 71 and a dust removing structure 73, and an adsorption hole is formed in the object placing plate 71. The workpiece 300 to be printed, which is transferred to the dust removing device 700 by the material transfer mechanism 91, is placed on the object placing plate 71 and is vacuum-adsorbed on the object placing plate 71 through the adsorption holes, so that the dust removing structure 73 is convenient to clean. The cleaned workpiece 300 to be printed is transferred to the first stage 131 or the second stage 133 located at the loading station 11a by the material transfer mechanism 91, and is transported to the printing station 11b by the first stage 131 or the second stage 133, and the printing material is printed on the surface thereof by the screen printing mechanism 30.

The material transfer mechanism 91 may include a module 911 and a material transfer robot 913, and the material transfer robot 913 is used for clamping the workpiece 300 to be printed, and the workpiece 300 to be printed may be moved among the material preparation apparatus 500, the dust removing apparatus 700 and the screen printing apparatus 100 through the module 911 for transferring the workpiece 300 to be printed.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the scope of the present invention, and all modifications and equivalents of the present invention, which are made by the contents of the present specification and the accompanying drawings, or directly/indirectly applied to other related technical fields, are included in the scope of the present invention.

Claims (10)

1. The utility model provides a fortune material mechanism, its characterized in that fortune material mechanism is used for silk screen printing equipment, fortune material mechanism includes:

the conveying structure is provided with a feeding station and a printing station; and

carry the material structure, carry the material structure and include first objective table and second objective table, first objective table with the second objective table all with transmission structure connects, transmission structure can drive first objective table with the second objective table in material loading station with reciprocating motion between the printing station, the moving direction of first objective table with the moving direction of second objective table is opposite.

2. The material handling mechanism of claim 1, wherein the transport structure comprises:

the first object stage and the second object stage are connected with the two supports in a sliding mode and located in the sliding space; and

and the driving assembly is connected with the first object stage and the second object stage and can drive the first object stage and the second object stage to reciprocate between the feeding station and the printing station along the support.

3. The material handling mechanism of claim 2, wherein the rack has a first rail and a second rail, the first rail of the rack forms a first sliding space therebetween, the second rail of the rack forms a second sliding space therebetween, the first stage is slidably connected to the first rail and slides within the first sliding space, and the second stage is slidably connected to the second rail and slides within the second sliding space.

4. The material conveying mechanism as claimed in claim 3, wherein the first slide rail is provided on a side surface of one of the brackets facing the other bracket, and the second slide rail is provided on an upper surface of the bracket.

5. The material conveying mechanism as claimed in claim 3, wherein the conveying structure further comprises two connecting members, and the two connecting members are slidably connected to the first slide rail and the second slide rail respectively;

the first object stage and the second object stage are respectively connected with one connecting piece, and the two connecting pieces are connected with the driving assembly.

6. The material handling mechanism of claim 5, wherein the connector comprises:

the main body part is connected to the first slide rail or the second slide rail in a sliding mode, and the first object stage and the second object stage are respectively connected with the main body part of one connecting piece; and

and two opposite ends of the connecting part are respectively connected with the main body part and the driving component.

7. The material handling mechanism of claim 5, wherein the drive assembly comprises:

a drive member; and

the driving part can drive the driving part to move and can drive the first objective table and the second objective table to respectively slide along the first slide rail and the second slide rail.

8. The material handling mechanism of claim 7 wherein said drive member is provided with a drive wheel at an end thereof connected to said drive member, said drive member being spaced from said drive member, said drive member being capable of driving rotation of said drive wheel and thereby said drive member.

9. The material transporting mechanism as claimed in claim 8, wherein the connecting member is fixedly connected to the driving member, and an insertion hole for the driving member to pass through is formed at an end of the connecting member connected to the driving member.

10. A screen printing apparatus, characterized in that it comprises a screen printing mechanism and a material conveying mechanism as claimed in any one of claims 1 to 9.

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