CN218340784U - Punching device - Google Patents

Abstract

The application provides a punching device belongs to the photovoltaic field of making. The punching device comprises a punching mechanism, a feeding and discharging transmission mechanism and a material taking and discharging mechanism; the punching mechanism is used for punching the photovoltaic frame which is not punched; the feeding and discharging transmission mechanism comprises a feeding unit and a discharging unit, the feeding unit is used for inputting the photovoltaic frames which are not punched into the feeding unit at the first preset position, and the discharging unit is used for outputting the punched photovoltaic frames from the second preset position; the material taking and placing mechanism comprises a first material taking and placing assembly and a second material taking and placing assembly, the first material taking and placing assembly is used for transferring the non-punched photovoltaic frame from a first preset position to the punching mechanism, and the second material taking and placing assembly is used for transferring the punched photovoltaic frame from the punching mechanism to a second preset position. The punching device is provided with the material taking and placing mechanism which is used for automatically taking and placing materials, and two groups of material taking and placing assemblies are configured to conveniently and synchronously carry out feeding and discharging, so that the material transfer efficiency can be effectively improved, and the overall efficiency of the punching process is improved.

Description

Punching device

Technical Field

The application relates to the field of photovoltaic manufacturing, in particular to a punching device.

Background

The photovoltaic frame is an important structure of the framed photovoltaic module, and in the manufacturing process of the framed photovoltaic module, punching processes such as punching are generally required according to design requirements, so that the photovoltaic frame with a specific shape structure is formed. However, in the current punching process, the material is generally required to be manually transferred between the conveying mechanism and the punching mechanism, so that the efficiency of the punching process is low.

SUMMERY OF THE UTILITY MODEL

The application aims to provide a punching device which can improve the efficiency of a punching process.

The embodiment of the application is realized as follows:

the embodiment of the application provides a punching device which comprises a punching mechanism, a feeding and discharging transmission mechanism and a feeding and discharging mechanism; the punching mechanism is used for punching the photovoltaic frame which is not punched; the feeding and discharging transmission mechanism comprises a feeding unit and a discharging unit, the feeding unit is used for inputting the photovoltaic frames which are not punched into the feeding unit at the first preset position, and the discharging unit is used for outputting the punched photovoltaic frames from the second preset position; the material taking and placing mechanism comprises a first material taking and placing assembly and a second material taking and placing assembly, the first material taking and placing assembly is used for transferring the non-punched photovoltaic frame from a first preset position to the punching mechanism, and the second material taking and placing assembly is used for transferring the punched photovoltaic frame from the punching mechanism to a second preset position.

Among the above-mentioned technical scheme, the configuration is got and is put material mechanism and be used for getting the blowing automatically, thereby can improve material transfer efficiency and improve the overall efficiency of die-cutting technology, but also can save the cost of labor. Wherein, dispose feeding unit and ejection of compact unit, and dispose alone and be used for defeated first getting of transferring to the die-cut mechanism from feeding unit with the photovoltaic frame that does not die-cut and get the material subassembly with the second that is used for transferring die-cut photovoltaic frame to the ejection of compact unit from the die-cut mechanism, conveniently get the unloading of material subassembly through the second when getting the material subassembly material loading through first, compare with through same getting the material subassembly material loading and unloading, can further improve the unloading beat of going up, thereby can improve the overall efficiency of die-cut technology better.

In some possible embodiments, the feeding unit and the discharging unit both convey the photovoltaic frame in a first direction, and the feeding unit and the discharging unit are distributed side by side in a second direction, and the first direction and the second direction are perpendicular to each other and perpendicular to the height direction of the punching device.

In the technical scheme, the feeding unit and the discharging unit are distributed side by side in a direction perpendicular to the conveying direction of the photovoltaic frame, the structure distribution is compact, and the space can be saved; should be the horizontal direction side by side, can also effectively avoid mutual interference between feed unit and the ejection of compact unit.

In some possible embodiments, the material taking and discharging mechanism and the material feeding and discharging conveying mechanism are distributed side by side along the second direction.

In the technical scheme, the material taking and placing mechanism and the material feeding and discharging transmission mechanism are distributed side by side along the conveying direction vertical to the photovoltaic frame, the structural distribution is compact, and the space can be saved; should be the horizontal direction side by side, can also effectively avoid getting mutual interference between drop feed mechanism and the business turn over material conveying mechanism.

In some possible embodiments, the die cutting mechanism and the feed and discharge transport mechanism are distributed side-by-side in the second direction.

In the technical scheme, the punching mechanism and the feeding and discharging transmission mechanism are distributed side by side along the conveying direction vertical to the photovoltaic frame, the structural distribution is compact, and the space can be saved; should be the horizontal direction side by side, can also effectively avoid mutual interference between die-cutting mechanism and business turn over material conveying mechanism. Simultaneously, under this mode side by side, the photovoltaic frame only need carry on the translation at the transfer process of material loading and unloading can, need not to rotate the switching-over around vertical pivot for the transfer of material is convenient and fast more.

In some possible embodiments, the material taking and placing mechanism is provided with a material taking and placing driving member, and a power output end of the material taking and placing mechanism is simultaneously in transmission connection with the first material taking and placing assembly and the second material taking and placing assembly and is used for driving the first material taking and placing assembly and the second material taking and placing assembly to synchronously move along the second direction; when the first material taking and placing assembly corresponds to the first preset position, the second material taking and placing assembly corresponds to the punching mechanism; when the first material taking and placing component corresponds to the punching mechanism, the second material taking and placing component corresponds to the second preset position.

Among the above-mentioned technical scheme, first get to put material subassembly and second get to put the material subassembly and can get material and synchronous blowing in step under synchronous motion, get drop feed mechanism's drive convenient, and first get to put material subassembly and second get to put material subassembly get to put the material beat unanimously for the transfer operation of material is more efficient and accurate.

In some possible embodiments, the material taking and placing driving member includes a driving motor, a driving sprocket and a mounting base, the driving sprocket is connected between the driving motor and the mounting base in a driving manner, and the first material taking and placing assembly and the second material taking and placing assembly are both connected with the mounting base.

Among the above-mentioned technical scheme, get through servo motor and drive sprocket output power drive first get and put material subassembly and second and get and put material subassembly synchronous motion for get simple structure and the operation of putting the material driving piece and stablize.

In some possible embodiments, the first material taking and placing assembly comprises a plurality of first material taking and placing structures distributed side by side along a first direction; and/or the second material taking and placing assembly comprises a plurality of second material taking and placing structures which are distributed side by side along the first direction.

Among the above-mentioned technical scheme, get a plurality of material structures of getting that the material subassembly configuration distributes side by side along the first direction, conveniently get the blowing from a plurality of positions for photovoltaic frame's atress scope is wider and the atress is more even, is favorable to carrying on more steadily that the material is got and is put.

In some possible embodiments, the conveying surface of the in-and-out conveying mechanism is lower than the blanking dies of the blanking mechanism.

In the technical scheme, the feeding and discharging transmission mechanism is configured to be lower than the punching die of the punching mechanism, so that the die of the punching mechanism is convenient to replace from the side where the feeding and discharging transmission mechanism is located, and the die of the punching mechanism is more convenient to replace.

In some possible embodiments, the material taking part of the first material taking and placing assembly and/or the second material taking and placing assembly is provided with an electromagnet.

Among the above-mentioned technical scheme, get the material position of getting of material subassembly and set up the electro-magnet, when carrying out the die-cut of the photovoltaic frame (for example steel frame) of iron content, be convenient for realize the absorption of photovoltaic frame and put down through electromagnetic force, compare with getting material modes such as mechanical clamping jaw, can avoid causing the damage to the photovoltaic frame, and its structure is simpler can also save the shared space of getting the material subassembly.

In some possible embodiments, the feeding unit includes a feeding conveying member and a jacking driving member, and the jacking driving member is used for jacking the photovoltaic frame which is not punched on the feeding conveying member to a first preset position; and/or the discharging unit comprises a discharging conveying piece and a descending driving piece, and the descending driving piece is used for descending the punched photovoltaic frame onto the discharging conveying piece from the second preset position.

Among the above-mentioned technical scheme, through configuration jacking driving piece and descending driving piece for first default position and second default position are located the position that is higher than conveying surface, can more conveniently get and put material mechanism and get the blowing. Moreover, in the jacking and landing processes, the angle of the photovoltaic frame can be finely adjusted along the axial direction of the photovoltaic frame by matching with specific operation, so that the photovoltaic frame is at a more appropriate angle in the transmission and punching processes.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present application, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present application and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained from the drawings without inventive effort.

FIG. 1 is a schematic view of a die cutting device according to some embodiments of the present application, shown in a first perspective;

FIG. 2 is a schematic diagram of a second perspective view of a blanking device according to some embodiments of the present disclosure;

fig. 3 is a schematic diagram of a third perspective view of a blanking device according to some embodiments of the present disclosure.

An icon:

100-a die cutting device;

110-a die-cutting mechanism;

120-a feed and discharge transport mechanism; 121-a feed unit; 1211-a feed conveyance member; 1212-jacking driving member; 122-a discharge unit; 1221-a discharge transport; 1222-lowering a drive;

130-taking and placing mechanism; 131-a first material taking and placing component; 132-a second material taking and placing component; 133-a pick-and-place drive member; 1331-a drive motor; 1332-a drive sprocket; 1333-a mounting substrate;

a-a first direction; b-a second direction.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present application clearer, the technical solutions in the embodiments of the present application will be clearly and completely described below with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are some embodiments of the present application, but not all embodiments. The components of the embodiments of the present application, generally described and illustrated in the figures herein, can be arranged and designed in a wide variety of different configurations.

Thus, the following detailed description of the embodiments of the present application, presented in the accompanying drawings, is not intended to limit the scope of the claimed application, but is merely representative of selected embodiments of the application. 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 application.

It should be noted that: like reference numbers and letters refer to like items in the following figures, and thus, once an item is defined in one figure, it need not be further defined or explained in subsequent figures.

In the description of the present application, it is to be noted that the terms "center", "upper", "lower", "vertical", "horizontal", "inner", "outer", and the like indicate orientations or positional relationships based on orientations or positional relationships shown in the drawings or orientations or positional relationships conventionally laid out when products of the application are used, and are only used for convenience in describing the application and simplifying the description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the application.

Furthermore, the terms "first," "second," and the like are used merely to distinguish one description from another, and are not to be construed as indicating or implying relative importance.

Furthermore, the terms "perpendicular", "parallel", and the like do not require that the components be absolutely perpendicular or parallel, but may be slightly inclined.

In the description of the present application, it is further noted that, unless expressly stated or limited otherwise, the terms "disposed," "mounted," "connected," and "connected" are to be construed broadly, e.g., as meaning either a fixed connection, a removable connection, or an integral connection; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meaning of the above terms in this application will be understood to be a specific case for those of ordinary skill in the art.

In addition, in the present application, "and/or" such as "feature 1 and/or" feature 2 "means that" feature 1 "alone," feature 2 "alone, and" feature 1 "plus" feature 2 "alone may be used.

The technical solutions provided in the present application will be exemplarily described below with reference to some specific embodiments.

Referring to fig. 1 to 3, an embodiment of the present application provides a punching device 100, which includes a punching mechanism 110, a feeding and discharging conveying mechanism 120, and a material taking and discharging mechanism 130; the punching mechanism 110 is used for punching the photovoltaic frame which is not punched; the feeding and discharging transmission mechanism 120 comprises a feeding unit 121 and a discharging unit 122, wherein the feeding unit 121 is used for inputting the photovoltaic frames which are not punched into a first preset position, and the discharging unit 122 is used for outputting the punched photovoltaic frames from a second preset position; the material taking and placing mechanism 130 comprises a first material taking and placing assembly 131 and a second material taking and placing assembly 132, the first material taking and placing assembly 131 is used for transferring the non-punched photovoltaic frames from a first preset position to the punching mechanism 110, and the second material taking and placing assembly 132 is used for transferring the punched photovoltaic frames from the punching mechanism 110 to a second preset position.

The punching mechanism 110 may be provided in a manner conventional in the art, such as configuring a die for punching a photovoltaic frame.

In the feeding and discharging transmission mechanism 120, the feeding unit 121 and the discharging unit 122 are not limited to be disposed, for example, but not limited to, a roller transmission mode, a belt transmission mode, a sprocket transmission mode, etc. As an example, the feeding unit 121 and the discharging unit 122 are respectively provided with a conveying roller having a shape and size matched with the photovoltaic frame for roller conveying the photovoltaic frame.

In the material taking and placing mechanism 130, the first material taking and placing assembly 131 and the second material taking and placing assembly 132 can move synchronously through the same power structure, or the first material taking and placing assembly and the second material taking and placing assembly can be connected to different power structures to control movement independently. Wherein, the operation of getting the material can be implemented to every group and get the blowing subassembly, also can implement the operation of blowing.

The die-cutting device 100 provided by the embodiment of the application has the following working principle:

the feeding unit 121 conveys the photovoltaic frame to a first working position to be loaded, and the feeding unit 121 is configured with a baffle, for example, for abutting against an end of the photovoltaic frame when the photovoltaic frame is conveyed in place. The first material taking and placing assembly 131 transfers the non-punched photovoltaic frame from the first preset position to the punching mechanism 110, and the punching mechanism 110 punches the photovoltaic frame. After the punching mechanism 110 finishes punching, the second material taking and placing assembly 132 transfers the punched photovoltaic frames to a second preset position from the punching mechanism 110, and then the discharging unit 122 outputs the punched photovoltaic frames from the second preset position; while the second material taking and placing assembly 132 performs blanking, the first material taking and placing assembly 131 repeats the feeding action, and transfers the new material to the photovoltaic frame from the first preset position to the punching mechanism 110.

In the technical scheme provided by the application, the material taking and placing mechanism 130 is configured to automatically take and place materials, so that the material transfer efficiency can be improved, the overall efficiency of the punching process can be improved, and the labor cost can be saved. Wherein, dispose feed unit 121 and discharge unit 122, and dispose alone and be used for defeated first taking of transferring to die-cut mechanism 110 from feed unit 121 of the photovoltaic frame that does not die-cut and get material subassembly 131 and be used for getting the second that die-cut photovoltaic frame transferred to discharge unit 122 from die-cut mechanism 110 and get material subassembly 132, conveniently get material subassembly 132 unloading through the second when getting material subassembly 131 material loading through first, compare with getting material subassembly material loading and unloading through same, can further improve and go up the unloading beat, thereby can improve the overall efficiency of die-cut technology better.

In this application, every group gets that blowing subassembly gets to put the material mode not be restricted, can be modes such as mechanical snatching, magnetic force absorption.

As an example, the material taking positions of the first material taking and placing assembly 131 and/or the second material taking and placing assembly 132 are provided with electromagnets.

Among the above-mentioned technical scheme, get the material position of getting of material subassembly and set up the electro-magnet, when carrying out the die-cut of the photovoltaic frame of iron-containing magnetic substance, be convenient for realize the absorption of photovoltaic frame and put down through electromagnetic force, compare with getting material modes such as mechanical clamping jaw, can avoid causing the damage to the photovoltaic frame, and its structure is simpler can also save the shared space of getting the material subassembly.

In the application, the arrangement modes of the punching mechanism 110, the feeding and discharging transmission mechanism 120 and the material taking and discharging mechanism 130 are not limited, and the punching mechanism, the feeding and discharging transmission mechanism and the material taking and discharging mechanism can be designed according to the requirements of a construction site.

In some possible embodiments, the feeding unit 121 and the discharging unit 122 both convey the photovoltaic frame in a first direction a, and the feeding unit 121 and the discharging unit 122 are distributed side by side in a second direction B, the first direction a and the second direction B being perpendicular to each other and to the height direction of the punching device 100. That is, the feeding unit 121 and the discharging unit 122 are distributed side by side in the horizontal direction, and the side by side direction is perpendicular to the conveying direction of the photovoltaic frame. The feeding unit 121 and the discharging unit 122 may be disposed on the same rack.

In the technical scheme, the feeding unit 121 and the discharging unit 122 are distributed side by side in a direction perpendicular to the conveying direction of the photovoltaic frame, the structure distribution is compact, and the space can be saved; the parallel direction is a horizontal direction, and mutual interference between the feeding unit 121 and the discharging unit 122 can be effectively avoided.

It should be noted that in other embodiments, the feeding unit 121 and the discharging unit 122 may be distributed side by side in the vertical direction; alternatively, the conveying directions between the feeding unit 121 and the discharging unit 122 can be perpendicular to each other or at an angle.

In this application, optionally, the feeding unit 121 includes a feeding conveying member 1211 and a lifting driving member 1212, where the lifting driving member 1212 is configured to lift the uncut photovoltaic frames on the feeding conveying member 1211 to a first preset position; optionally, the discharging unit 122 includes a discharging conveyor 1221 and a drop drive 1222, and the drop drive 1222 is configured to drop the punched photovoltaic frame from the second predetermined position onto the discharging conveyor 1221. The feeding conveying member 1211 and the discharging conveying member 1221 are respectively provided with a plurality of conveying rollers, and the conveying rollers have shape and size matched with the photovoltaic frame and are used for carrying out roller conveying on the photovoltaic frame; illustratively, the lift-up drive 1212 and the drop-down drive 1222 each include a positioning cylinder, optionally also fitted with a jaw structure such as a 180-degree flat jaw.

In the above technical solution, by configuring the jacking driving element 1212 and the descending driving element 1222, the first preset position and the second preset position are located at positions higher than the conveying surface, so that the material taking and placing mechanism 130 can take and place materials more conveniently. Moreover, in the lifting and falling processes, the angle of the photovoltaic frame can be finely adjusted along the axial direction of the photovoltaic frame conveniently in cooperation with specific operations (for example, adjustment operations in cooperation with the clamping jaws), so that the photovoltaic frame is at a more proper angle in the transmission and punching processes.

In some possible embodiments, the pick-and-place mechanism 130 and the in-and-out transport mechanism 120 are distributed side by side along the second direction B. That is, the material taking and placing mechanism 130 and the material feeding and discharging transmission mechanism 120 are distributed side by side in the horizontal direction, and the side by side direction is perpendicular to the conveying direction of the photovoltaic frame.

As an example, the material taking and placing mechanism 130 is located on a side of the material discharging unit 122 away from the material feeding unit 121; that is, the feeding unit 121, the discharging unit 122, and the taking and placing mechanism 130 are sequentially disposed along the second direction B.

In the technical scheme, the material taking and placing mechanism 130 and the material feeding and discharging transmission mechanism 120 are distributed side by side along the conveying direction perpendicular to the photovoltaic frame, the structural distribution is compact, and the space can be saved; the parallel direction is a horizontal direction, and mutual interference between the material taking and placing mechanism 130 and the material feeding and discharging transmission mechanism 120 can be effectively avoided.

It should be noted that in other embodiments, the material taking and placing mechanism 130 and the material feeding and discharging conveying mechanism 120 may be distributed side by side in the vertical direction, and in addition, the material taking and placing mechanism 130 may also be disposed upstream or downstream of the material feeding and discharging conveying mechanism 120.

In some possible embodiments, the die cutting mechanism 110 and the in-feed delivery mechanism 120 are distributed side-by-side along the second direction B. That is, the punching mechanism 110 and the feeding and discharging transmission mechanism 120 are distributed side by side in the horizontal direction, and the side by side direction is perpendicular to the conveying direction of the photovoltaic frame.

By way of example, the punching mechanism 110 is located between the taking and placing mechanism 130 and the feeding and discharging mechanism 120, and the feeding unit 121, the discharging unit 122, the punching mechanism 110 and the taking and placing mechanism 130 are arranged in sequence, for example, along the second direction B.

In the technical scheme, the punching mechanism 110 and the feeding and discharging transmission mechanism 120 are distributed side by side along the conveying direction vertical to the photovoltaic frame, the structural distribution is compact, and the space can be saved; the parallel direction is horizontal, and the mutual interference between the punching mechanism 110 and the feeding and discharging transmission mechanism 120 can be effectively avoided. Simultaneously, under this mode side by side, the photovoltaic frame only need carry on the translation at the transfer process of material loading and unloading can, need not to rotate the switching-over around vertical pivot for the transfer of material is convenient and fast more.

It should be noted that in other embodiments, the material taking and placing mechanism 130 and the material feeding and discharging conveying mechanism 120 may be distributed side by side in the vertical direction, and in addition, the material taking and placing mechanism 130 may also be disposed upstream or downstream of the material feeding and discharging conveying mechanism 120.

Based on the embodiment in which the punching mechanism 110 and the in-and-out conveying mechanism 120 are arranged side by side in the second direction B, optionally, the conveying surface of the in-and-out conveying mechanism 120 is lower than the punching die of the punching mechanism 110. The conveying surface of the feeding and discharging conveying mechanism 120 is lower than the punching mechanism 110, which means that the highest point of the conveying surface of the feeding and discharging conveying mechanism 120 is lower than the lowest point of the punching mold that needs to be replaced by the punching mechanism 110.

In the above technical solution, the feeding and discharging transmission mechanism 120 is configured to be a punching die lower than the punching die 110, so that the die of the punching die 110 can be conveniently replaced from the side where the feeding and discharging transmission mechanism 120 is located, and the die of the punching die 110 can be more conveniently replaced.

In some possible embodiments, the material taking and placing mechanism 130 is provided with a material taking and placing driving element 133, and a power output end of the material taking and placing mechanism 130 is in transmission connection with both the first material taking and placing assembly 131 and the second material taking and placing assembly 132, and is used for driving the first material taking and placing assembly 131 and the second material taking and placing assembly 132 to move synchronously along the second direction B. When the first material taking and placing assembly 131 corresponds to the first preset position, the second material taking and placing assembly 132 corresponds to the punching mechanism 110; when the first material taking and placing assembly 131 corresponds to the punching mechanism 110, the second material taking and placing assembly 132 corresponds to the second predetermined position.

The first material taking and placing assembly 131 corresponds to a first preset position, which means that the first material taking and placing assembly 131 is located at a position where materials can be taken from the first preset position; the second material taking and placing component 132 corresponds to the punching mechanism 110, which means that the second material taking and placing component 132 is located at a position where the material can be taken from the punching mechanism 110. Similarly, the first material taking and placing assembly 131 corresponds to the punching mechanism 110, which means that the first material taking and placing assembly 131 is located at a position where the photovoltaic frame can be placed on the punching mechanism 110, and the second material taking and placing assembly 132 corresponds to a second preset position, which means that the second material taking and placing assembly 132 can place the photovoltaic frame at the second preset position.

In the above technical scheme, the first material taking and placing assembly 131 and the second material taking and placing assembly 132 can synchronously take materials and synchronously place materials under synchronous motion, the material taking and placing mechanism 130 is convenient to drive, and the material taking and placing periods of the first material taking and placing assembly 131 and the second material taking and placing assembly 132 are consistent, so that the material transfer operation is more efficient and accurate.

Based on the embodiment that the first material taking and placing assembly 131 and the second material taking and placing assembly 132 move synchronously, as an example, the material taking and placing driving member 133 includes a driving motor 1331, a driving sprocket 1332 and a mounting base 1333, the driving sprocket 1332 is in driving connection between the driving motor 1331 and the mounting base 1333, and both the first material taking and placing assembly 131 and the second material taking and placing assembly 132 are connected with the mounting base 1333.

In the above technical solution, the servo motor and the transmission chain wheel 1332 output power to drive the first material taking and placing assembly 131 and the second material taking and placing assembly 132 to move synchronously, so that the material taking and placing driving member 133 has a simple structure and operates stably.

In other embodiments, the driving sprocket 1332 may be replaced with a belt, chain, lead screw, or other driving structure.

Considering that the photovoltaic frame generally has certain length and weight, in material loading and unloading process, provide sufficient effort of snatching, be favorable to carrying out more steadily that the material is got and is put.

In view of the above considerations, in some possible embodiments, the first material taking and placing assembly 131 comprises a plurality of first material taking and placing structures distributed side by side along the first direction a; and/or the second material taking and placing assembly 132 comprises a plurality of second material taking and placing structures distributed side by side along the first direction a.

Among the above-mentioned technical scheme, get a plurality of material structures of getting that the material subassembly configuration distributes side by side along first direction A, conveniently get the blowing from a plurality of positions for photovoltaic frame's atress scope is wider and the atress is more even, is favorable to carrying on more steadily that the material gets and puts.

The above description is only a preferred embodiment of the present application and is not intended to limit the present application, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, improvement and the like made within the spirit and principle of the present application shall be included in the protection scope of the present application.

Claims (10)

1. A die cutting device, comprising:

the punching mechanism is used for punching the photovoltaic frame which is not punched;

the feeding and discharging transmission mechanism comprises a feeding unit and a discharging unit, the feeding unit is used for inputting the photovoltaic frame which is not punched into the feeding unit at a first preset position, and the discharging unit is used for outputting the punched photovoltaic frame from a second preset position; and

the material taking and placing mechanism comprises a first material taking and placing assembly and a second material taking and placing assembly, the first material taking and placing assembly is used for transferring the photovoltaic frame which is not punched from the first preset position to the punching mechanism, and the second material taking and placing assembly is used for transferring the punched photovoltaic frame from the punching mechanism to the second preset position.

2. The punching device according to claim 1, wherein the feeding unit and the discharging unit both convey the photovoltaic frame in a first direction, and the feeding unit and the discharging unit are distributed side by side in a second direction, and the first direction and the second direction are perpendicular to each other and perpendicular to a height direction of the punching device.

3. A die cutting apparatus according to claim 2, wherein the pick-and-place mechanism and the feed and discharge conveyor mechanism are side-by-side along the second direction.

4. A blanking device according to claim 2 or 3, wherein the blanking means and the feed and discharge conveyor means are arranged side by side in the second direction.

5. The punching device according to claim 4, wherein the material taking and placing mechanism is provided with a material taking and placing driving member, and a power output end of the material taking and placing mechanism is in transmission connection with the first material taking and placing assembly and the second material taking and placing assembly at the same time and is used for driving the first material taking and placing assembly and the second material taking and placing assembly to move along the second direction synchronously;

when the first material taking and placing assembly corresponds to the first preset position, the second material taking and placing assembly corresponds to the punching mechanism; when the first material taking and placing component corresponds to the punching mechanism, the second material taking and placing component corresponds to the second preset position.

6. The die cutting device of claim 5, wherein the pick and place drive includes a drive motor, a drive sprocket, and a mounting base, the drive sprocket is drivingly connected between the drive motor and the mounting base, and the first pick and place assembly and the second pick and place assembly are both connected to the mounting base.

7. The blanking apparatus of claim 4 wherein the first pick-and-place assembly includes a plurality of first pick-and-place structures distributed side-by-side along the first direction;

and/or the second material taking and placing assembly comprises a plurality of second material taking and placing structures which are distributed side by side along the first direction.

8. A blanking device according to claim 4 wherein the conveying surface of the feed and discharge conveyor means is lower than the blanking dies of the blanking means.

9. The punching device according to claim 1, wherein the material taking portion of the first material taking and placing assembly and/or the second material taking and placing assembly is provided with an electromagnet.

10. The punching device according to claim 1, wherein the feeding unit comprises a feeding conveying member and a jacking driving member, wherein the jacking driving member is used for jacking the photovoltaic frame which is not punched on the feeding conveying member to the first preset position;

and/or the discharging unit comprises a discharging conveying part and a descending driving part, and the descending driving part is used for descending the punched photovoltaic frame to the discharging conveying part from the second preset position.

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