CN211743623U - Type-C connector assembling line - Google Patents
Type-C connector assembling line Download PDFInfo
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- CN211743623U CN211743623U CN202020399551.0U CN202020399551U CN211743623U CN 211743623 U CN211743623 U CN 211743623U CN 202020399551 U CN202020399551 U CN 202020399551U CN 211743623 U CN211743623 U CN 211743623U
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Abstract
The utility model relates to a connector production technical field discloses a Type-C connector assembly line. The Type-C connector assembling production line comprises a clamping hook assembly, an elastic sheet assembly and an iron shell assembly which are sequentially arranged along the movement direction of a rubber core to be assembled; the clamping hook assembly is configured to cut a clamping hook material belt to obtain a clamping hook, and the clamping hook is assembled on the rubber core; the spring loading assembly is configured to cut a spring strip to obtain a spring, and the spring is assembled on the rubber core provided with the clamping hook; the iron shell assembly is configured to press the rubber core assembled with the clamping hook and the elastic sheet into an iron shell; a moving assembly configured to move the glue core at the loading hook assembly, the loading tab assembly, and the loading iron shell assembly in sequence. The utility model provides a Type-C connector assembly line can assemble Type-C connector automatically, improves production efficiency, guarantees the quality of the Type-C connector after the equipment, improves the qualification rate of product.
Description
Technical Field
The utility model relates to a connector production technical field especially relates to a Type-C connector assembly production line.
Background
The structure of the Type-C connector is shown in figures 1-5, the Type-C connector comprises a rubber core 200, hooks 300, elastic sheets 500 and an iron shell 600, wherein insertion grooves are formed in two sides of the rubber core 200, the hooks 300 are inserted into the insertion grooves in two sides of the rubber core 200, the elastic sheets 500 are clamped on the upper side surface and the lower side surface of the rubber core 200, and the assembled structure is shown in figure 1. After the elastic sheet 500 and the hook 300 are mounted, the iron case 600 is sleeved outside the rubber core 200 to encapsulate the rubber core 200, the hook 300 and the elastic sheet 500.
In the prior art, different molds are generally used for assembling the hook 300, the elastic sheet 500 and the iron shell 600 step by manual work, but the manual assembly mode is adopted, so that the working efficiency is low, the quality after assembly is difficult to ensure, and the unqualified rate of products is high.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to provide a Type-C connector assembly line can assemble Type-C connector automatically, improves production efficiency, guarantees the quality of the Type-C connector after the equipment, improves the qualification rate of product.
To achieve the purpose, the utility model adopts the following technical proposal:
the utility model provides a Type-C connector assembly line includes:
a clamping hook assembly, an elastic sheet assembly and an iron shell assembly are sequentially arranged along the movement direction of the rubber core to be assembled;
the clamping hook assembly is configured to cut a clamping hook material belt to obtain a clamping hook, and the clamping hook is assembled on the rubber core;
the spring loading assembly is configured to cut a spring strip to obtain a spring, and the spring is assembled on the rubber core provided with the clamping hook;
the iron shell assembly is configured to press the rubber core assembled with the clamping hook and the elastic sheet into an iron shell;
a moving assembly configured to move the glue core at the loading hook assembly, the loading tab assembly, and the loading iron shell assembly in sequence.
Preferably, the Type-C connector assembly line further comprises a rubber core material tray assembly, a clamping hook feeding assembly, an elastic sheet feeding assembly and an iron shell feeding assembly;
the core tray assembly is configured to provide the cores to be assembled; the hook feeding component is configured to feed a hook material belt to the hook loading component; the clip feed assembly is configured to deliver a clip strip to the clip loading assembly; and the iron shell feeding assembly conveys the iron shell to the iron shell loading assembly.
Preferably, the card-holding hook assembly comprises:
the clamping hook strip workbench is provided with a first placing groove communicated with the clamping hook feeding assembly, and the clamping hook strip can be positioned in the first placing groove;
the first supporting component is positioned in the first placing groove and can move up and down relative to the clamping hook belt workbench;
the first supporting component is lifted relative to the hook strip workbench and can jack up the hook strip in the first placing groove;
the first pushing component is configured to push the hook material belt jacked up by the first supporting component in the first placing groove to move forwards by the distance of at least one hook;
the first cutting component is configured to cut the hook material belt positioned below the first cutting component so as to obtain hooks;
and the pushing assembly is configured to push the clamping hook and press the clamping hook on the rubber core.
Preferably, the first support assembly comprises:
the first clamping hook supporting piece is arranged at one end close to the clamping hook feeding component, at least part of the structure of the first clamping hook supporting piece is positioned in the first placing groove, and the first clamping hook supporting piece is configured to support the rear end of the clamping hook material belt positioned in the first placing groove;
the second clamping hook supporting piece is arranged at one end close to the first shearing component, at least part of the structure of the second clamping hook supporting piece is arranged in the first placing groove, and the second clamping hook supporting piece is configured to support the front end of the clamping hook material belt in the first placing groove;
the first hook supporting piece and the second hook supporting piece can be lifted relative to the first placing groove;
the first clamping hook supporting piece and the second clamping hook supporting piece can jack up a clamping hook material belt in the first placing groove and can place the clamping hook material belt in the first placing groove.
Preferably, the first pushing assembly comprises:
the first pushing driving piece is arranged on the hook belt workbench;
the first pushing component is connected to the output end of the first pushing driving component and can push the clamping hook material belt jacked up by the first supporting component to move forwards by the width of one clamping hook.
Preferably, the first shearing assembly comprises:
the first shearing driving piece is arranged on the clamping hook belt workbench;
the first cutting assembly is connected to the output end of the first cutting driving piece, and the first cutting driving piece can press down the first cutting assembly;
after the first cutting assembly cuts the clamping hook material belt, a single clamping hook is obtained, and waste materials on the clamping hook material belt after the clamping hook is cut can be cut.
Preferably, the loading tab assembly comprises:
a glue core workbench configured to place the glue core;
the rotating assembly and the two groups of press-fitting elastic sheet assemblies are positioned on the same side of the rubber core workbench, and the two groups of press-fitting elastic sheet assemblies are respectively positioned on the upstream and downstream of the rotating assembly along the movement direction of the rubber core;
the press-fitting elastic sheet assembly is configured to cut the elastic sheet material belt to obtain an elastic sheet, the elastic sheet is press-fitted to the rubber core, and the rotating assembly rotates the rubber core with one side provided with the elastic sheet by 180 degrees;
the other side of the rubber core workbench is provided with the moving assembly, and the moving assembly is configured to move the rubber core on the rubber core workbench.
Preferably, the press-fitting spring plate assembly includes:
the elastic piece cutting assembly is configured to cut the elastic piece material belt conveyed by the elastic piece feeding assembly so as to obtain the elastic pieces;
the elastic sheet press-fitting assembly moves the elastic sheet to the rubber core on the rubber core workbench so as to press-fit the elastic sheet to the rubber core.
Preferably, the rotating assembly comprises:
a support;
the rotary driving piece is arranged on the bracket;
the rotating part is communicated with the rubber core workbench, the rubber core on the rubber core workbench can be moved to the rotating part by the moving assembly, and the rotating driving part can drive the rotating part and the rubber core to rotate 180 degrees.
Preferably, the iron shell assembly comprises:
the iron shell loading workbench is communicated with the rubber core workbench and is configured to receive the rubber core conveyed by the rubber core workbench;
the iron shell conveying channel assembly is arranged on one side of the iron shell loading workbench and communicated with the iron shell feeding assembly, and the iron shell conveying channel assembly is configured to convey the iron shells conveyed by the iron shell feeding assembly to the rubber core workbench in sequence;
the assembling iron shell assembly is arranged on the other side of the iron shell assembling workbench and is positioned at the downstream of the iron shell conveying channel assembly, and the assembling iron shell assembly is configured to assemble the iron shell and the rubber core on the iron shell assembling workbench;
the rubber core limiting assembly is arranged at the upstream of the iron shell conveying channel assembly and is configured to limit the rubber core on the iron shell assembling workbench to move to the iron shell assembling assembly;
the moving assembly can drive the rubber core and the iron shell on the iron shell loading workbench to move.
The utility model has the advantages that: the utility model discloses in utilize dress pothook subassembly to cut the pothook material area to acquire the pothook, and assemble the pothook on gluing the core, later, utilize to remove the subassembly and remove to the dress shell fragment subassembly with the gluey core that will be equipped with the pothook, the dress shell fragment subassembly cuts the shell fragment material area and obtains single shell fragment, and assembles the shell fragment on gluing the core. And then, the moving assembly moves the rubber core assembled with the elastic sheet to the iron shell assembly again, so that the rubber core assembled with the clamping hook and the elastic sheet is pressed into the iron shell. Utilize Type-C connector assembly line to realize the automatic equipment to Type-C connector, can improve work efficiency, guarantee the quality of the Type-C connector after the equipment, improve the qualification rate of product.
Drawings
FIG. 1 is a schematic diagram of a prior art Type-C connector (excluding the iron shell);
FIG. 2 is an exploded view of a prior art Type-C connector (excluding the iron shell);
fig. 3 is a schematic structural diagram of a hook tape in the prior art;
fig. 4 is a schematic structural diagram of a spring sheet material tape in the prior art;
FIG. 5 is a schematic structural diagram of a prior art iron shell;
FIG. 6 is a schematic structural view of the latch loading assembly, the spring loading assembly and the iron shell loading assembly of the present invention;
fig. 7 is a schematic structural view of the snap hook assembly with a sliding groove of the present invention;
fig. 8 is a schematic structural view of the hook assembly of the present invention;
fig. 9 is a partial schematic structural view of the hook assembly of the present invention;
fig. 10 is a schematic view of the partial structure of the hook assembly of the present invention after the first cutting head is removed;
fig. 11 is a schematic structural view of a loading tab assembly and a partial movement assembly of the present invention;
fig. 12 is a schematic structural view of a loading tab assembly of the present invention;
fig. 13 is a schematic structural view of the loading tab assembly of the present invention (excluding the chute for transporting the strip of tab material);
fig. 14 is a schematic structural view of the press-fitting spring plate assembly of the present invention;
fig. 15 is a schematic structural view of the shrapnel cutting assembly of the present invention;
fig. 16 is a schematic structural view of the moving assembly of the present invention;
fig. 17 is a schematic structural diagram of the iron case assembly of the present invention.
In the figure: 100. a hook material belt; 200. a rubber core; 300. a hook; 400. a spring sheet material band; 500. a spring plate; 600. an iron shell;
1. installing a clamping hook component; 11. the hook is provided with a workbench; 10. a first placing groove; 101. accommodating grooves; 12. a first support assembly; 121. a first hook supporting member; 1211. a drop passage; 122. a second hook support;
13. a first pushing assembly; 131. a first push drive; 132. a first pushing component; 1321. a first slider; 13211. a first rotating groove; 1322. a first guide block; 1323. a first pusher member;
14. a first shearing assembly; 141. a first shear drive; 142. a first cutting assembly; 1421. a cutting guide; 1422. a first cutting head; 1423. a second cutting head;
15. pushing the assembly; 151. assembling a driving piece; 152. assembling a push plate;
2. a loading tab assembly; 21. a rubber core workbench; 22. a rotating assembly; 221. a rotary drive member; 222. a rotating member;
23. pressing the elastic sheet assembly;
231. the elastic sheet cutting assembly;
2311. the elastic sheet is provided with a workbench; 23110. a second placing groove;
2312. a second support assembly; 23121. a first spring support; 23122. a second spring support;
2313. a second pushing assembly; 23131. a second push drive; 23132. a second pushing assembly; 23133. a second slider; 23134. a second guide block; 23135. a second pusher member; 23136. a second rotating groove;
2314. a second shear assembly; 23141. a second shear drive; 23142. a second cutting assembly; 23143. cutting a pressing piece; 23144. a third cutting head;
232. the elastic sheet press-mounting component; 2321. a first press-fitting driving member; 2322. a second press-fitting driving piece; 2323. adsorbing and pressing the assembly;
3. installing an iron shell assembly; 31. installing an iron shell workbench; 32. an iron shell conveying channel assembly; 33. assembling an iron shell assembly; 34. a restraining rubber core assembly;
4. a moving assembly; 41. a first movement drive assembly; 42. a second movement drive assembly; 43. a laterally moving platform assembly; 431. a first clamping member.
Detailed Description
The technical solution of the present invention is further explained by the following embodiments with reference to the accompanying drawings.
In order to make the objects, technical solutions and advantages of the embodiments of the present invention clearer, the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are some, but not all, embodiments of the present invention. The components of embodiments of the present invention, as generally described and illustrated in the figures herein, may be arranged and designed in a wide variety of different configurations.
Thus, the following detailed description of the embodiments of the present invention, presented in the accompanying drawings, is not intended to limit the scope of the invention, as claimed, but is merely representative of selected embodiments of the invention. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts belong to the protection scope of the present invention.
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 and explained in subsequent figures.
In the description of the present invention, it should be noted that the terms "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", etc. indicate the position or positional relationship based on the position or positional relationship shown in the drawings, or the position or positional relationship which is usually placed when the product of the present invention is used, and are only for convenience of description of the present invention and simplification of description, but do not indicate or imply that the device or element referred to must have a specific position, be constructed and operated in a specific orientation, and thus, should not be construed as limiting the present invention. Furthermore, the terms "first," "second," "third," and the like are used solely to distinguish one from another and are not to be construed as indicating or implying relative importance. In the description of the present invention, "a plurality" means two or more unless otherwise specified.
In the description of the present invention, it should also be noted that, unless otherwise explicitly stated or limited, the terms "disposed" and "connected" are to be interpreted broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected. Either mechanically or electrically. The specific meaning of the above terms in the present invention can be understood in specific cases to those skilled in the art.
In the present disclosure, unless expressly stated or limited otherwise, the first feature "on" or "under" the second feature may comprise direct contact between the first and second features, or may comprise contact between the first and second features not directly. Also, the first feature being "on," "above" and "over" the second feature includes the first feature being directly on and obliquely above the second feature, or merely indicating that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature includes the first feature being directly under and obliquely below the second feature, or simply meaning that the first feature is at a lesser elevation than the second feature.
Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the same or similar elements or elements having the same or similar function throughout. The embodiments described below with reference to the drawings are exemplary only for the purpose of explaining the present invention, and should not be construed as limiting the present invention.
In this embodiment, a Type-C connector assembling line is provided for automatically assembling Type-C connectors as shown in FIGS. 1 to 5.
As shown in fig. 6 to 11, the Type-C connector assembling line includes a chucking assembly 1, a loading tab assembly 2, an iron case assembly 3, and a moving assembly, which are sequentially disposed along the direction of movement of the rubber core 200 to be assembled. The hook assembly 1 is configured to cut the hook material tape 100 to obtain the hooks 300, and assemble the hooks 300 to the rubber core 200. The loading assembly 2 is configured to cut the tab strip 400 to obtain tabs 500 and assemble the tabs 500 to the cores 200 with the hooks 300 installed. The iron case assembly 3 is configured to press the rubber core 200 fitted with the hook 300 and the striking plate 500 into the iron case 600. The moving assembly is configured to move the rubber core 200 at the above-mentioned clip loading assembly 1, the bullet loading assembly 2, and the iron shell loading assembly 3 in sequence.
In this embodiment, the hook strip 100 is cut by the hook assembly 1 to obtain the hook 300, and the hook 300 is assembled on the rubber core 200 in the state shown in fig. 1, and then the rubber core 200 assembled on the hook 300 is moved to the elastic sheet assembly 2 by the moving assembly, and the elastic sheet assembly 2 cuts the elastic sheet strip 400 to obtain a single elastic sheet 500, and the elastic sheet 500 is assembled on the rubber core 200. Then, the moving assembly moves the rubber core 200 assembled with the spring 500 to the iron case assembly 3 again, so as to press the rubber core 200 assembled with the hook 300 and the spring 500 into the iron case 600. Utilize Type-C connector assembly line to realize the automatic equipment to Type-C connector, can improve work efficiency, guarantee the quality of the Type-C connector after the equipment, improve the qualification rate of product.
Preferably, the present embodiment further includes a rubber core tray assembly, a hook feeding assembly, a spring sheet feeding assembly and an iron shell feeding assembly, wherein the rubber core tray assembly is configured to provide a rubber core 200 to be assembled, the hook feeding assembly is configured to convey the hook material strip 100 to the hook assembly 1, the spring sheet feeding assembly is configured to convey the spring sheet material strip 400 to the spring sheet assembly 2, and the iron shell feeding assembly conveys the iron shell 600 to the iron shell assembly 3.
The clamping hook material belt 100 is supplied to the clamping hook assembly 1 by the clamping hook feeding assembly, the rubber core material disc assembly is matched with the clamping hook assembly 1 to cut the clamping hook material belt 100, and the speed of conveying the rubber core 200 to the clamping hook assembly 1 by the rubber core material disc assembly is controlled so as to assemble the clamping hook 300 and the rubber core 200. After pothook 300 and gluey core 200 assembly are accomplished, utilize to remove the subassembly and remove gluey core 200 to loading assembly 2, the speed of gluing core 200 is carried to loading assembly 2 to shell fragment pay-off subassembly cooperation, and the speed of control carrying shell fragment material area 400 to loading assembly 2 to supply loading assembly 2 to cut and acquire single shell fragment 500, thereby be convenient for loading assembly 2 after cutting, begin the assembly promptly, save operating time. The iron shell feeding assembly conveys the iron shell 600 to the iron shell assembly 3, so that the rubber core 200 provided with the clamping hook 300 and the elastic sheet 500 and the iron shell 600 which are moved to the iron shell assembly 3 can be immediately assembled. The rubber core material tray assembly, the clamping hook material feeding assembly, the elastic sheet material feeding assembly and the iron shell material feeding assembly are arranged, so that each process can work compactly and orderly, waiting time among the processes is saved, production efficiency is improved, and production cost is reduced.
Further preferably, the moving assembly in this embodiment includes a first moving assembly, a second moving assembly 4 and a third moving assembly, wherein after the glue core 200 is assembled with the hook 300, the glue core 200 is moved to the loading plate assembly 2 by the first moving assembly. In the process of continuously assembling the elastic sheet 500, the second moving assembly 4 can move the first moving assembly to transfer the rubber core 200 at the position of the elastic sheet loading assembly 2, and the rubber core 200 moves to be matched with the elastic sheet loading assembly 2 to assemble the elastic sheet on the rubber core 200. The third moving assembly can move the rubber core 200 equipped with the hook 300 and the spring sheet 500 to the iron shell assembly 3.
The Type-C connector assembly line further comprises a detection component positioned between the spring loading component 2 and the iron shell loading component 3, and the detection component is configured to detect the rubber core 200 after the assembly of the hook 300 and the spring 500. The rubber core 200 after the assembly of the hook 300 and the elastic sheet 500 is detected to be qualified by the detection component, and then enters the process of assembling the iron shell 600 to ensure that the assembled Type-C connector is a qualified piece. For the rubber core 200 that detects the disqualification after assembling the hook 300 and the elastic sheet 500, the present embodiment is further provided with a removing component that is arranged between the detecting component and the iron shell assembling component 3, and the removing component can remove the disqualification product from the production line.
Specifically, the above-mentioned detection assembly includes a CCD camera configured to detect the core rubber 200 after the hook 300 and the elastic piece 500 are assembled.
Rubber core charging tray subassembly includes the vibration dish in this embodiment, and with the exit linkage's of vibration dish spout, once only places a plurality of rubber cores 200 in the vibration dish, through vibration dish vibration back, rubber core 200 gets into the spout to slide in proper order in the spout and adorn pothook subassembly 1 department, in order to assemble pothook 300.
Fig. 7 is a schematic structural view of the hook assembly 1 with a chute, fig. 8 is a schematic structural view of the hook assembly 1, fig. 9 is a schematic partial structural view of the hook assembly 1, fig. 10 is a schematic partial structural view of the hook assembly 1 with the first cutting head 1422 removed, and the structure of the hook assembly 1 is described in detail with reference to fig. 7 to 10.
During operation, the hook material belt 100 is located in the first placing groove 10, and before the hook material belt 100 moves forward, the first supporting component 12 jacks up the hook material belt 100 in the first placing groove 10, so as to prevent the hook material belt 100 from generating friction with the first placing groove 10 in the moving process, and damage to the hook material belt 100 is caused, and subsequent use is affected. Then, the first pushing component 13 pushes the hook material strip 100 to move forward by a distance of one hook 300, so that the hook material strip 100 is located below the first cutting component 14, and the first cutting component 14 cuts the hook material strip to obtain a single hook 300. The cut hooks 300 are located in the first placing groove 10, and the horizontally placed single hook 300 is pushed by the pushing assembly 15 to be assembled with the rubber core 200.
The automatic assembly of the rubber core 200 and the clamping hook 300 is completed by utilizing the clamping hook assembly 1, and the quality of the rubber core 200 for assembling the clamping hook 300 can be ensured. Meanwhile, the clamping hooks 300 are continuously assembled on each rubber core 200, the production is rapid, the quality of the assembled semi-finished product is stable, the product reject ratio is reduced, and the working efficiency is improved.
Specifically, the first supporting component 12 includes a first hook supporting member 121 and a second hook supporting member 122, the first hook supporting member 121 is disposed near one end of the hook feeding component, and at least a part of the structure is located in the first placing groove 10, and a part of the structure of the first hook supporting member 121 is configured to support the rear end of the hook material tape 100 located in the first placing groove 10. The second hook supporting member 122 is disposed near one end of the first cutting assembly 14, and at least a portion of the second hook supporting member 122 is disposed in the first placing slot 10, and a portion of the second hook supporting member 122 is configured to support the front end of the hook material strip 100 in the first placing slot 10. The first hook supporter 121 and the second hook supporter 122 are both able to be lifted relative to the first placing slot 10. The first hook supporting member 121 and the second hook supporting member 122 are lifted up at the same time to jack up the hook material strip 100 in the first placing groove 10, and both are lowered down at the same time to place the hook material strip 100 in the first placing groove 10.
When the hook material strip 100 needs to move forward, the first hook supporting member 121 and the second hook supporting member 122 both rise to jack up the hook material strip 100 by a predetermined height, so that the hook material strip 100 is not in contact with the first placing groove 10, thereby reducing the abrasion of the first placing groove 10 to the hook material strip 100 in the moving process. After the first hook supporting member 121 and the second hook supporting member 122 descend, the partial structures of the first hook supporting member 121 and the second hook supporting member 122 located in the first placing groove 10 are all flush with the groove bottom of the first placing groove 10, so that the first cutting assembly 14 can cut the hook material strip 100 to obtain the hook 300. Preferably, the first hook supporting member 121 and the second hook supporting member 122 are driven to lift by an air cylinder.
The first pushing assembly 13 includes a first pushing driving member 131 and a first pushing assembly 132, wherein the first pushing driving member 131 is disposed on the hook strip worktable 11. The first pushing component 132 is connected to the output end of the first pushing driving element 131, and the first pushing component 132 can push the hook material strip 100 jacked up by the first supporting component 12 to move forward by the width of one hook 300.
The first pushing driving element 131 can drive the first pushing component 132 to move back and forth, and during the forward movement of the first pushing component 132, the first pushing component 132 can push the hook material belt 100 jacked up by the first supporting component 12 to move forward by the width of one hook 300, so as to ensure continuous production. When the first supporting component 12 descends, the hook material strip 100 descends to contact with the first placing groove 10, at this time, the first pushing component 132 does not contact with the hook material strip 100, and the first pushing component 132 retreats without driving the hook material strip 100 to retreat. The first pushing component 13 is matched with the first supporting component 12 to push the hook material belt 100 to move forwards to realize continuous work, so that the production efficiency is ensured, and the first pushing component 13 is simple in structure and low in cost. Preferably, the first push driving member 131 is a cylinder.
Specifically, the first pushing assembly 132 includes a first sliding block 1321, a first guiding block 1322 and a first pushing member 1323, wherein the first sliding block 1321 is connected to the output end of the first pushing driving element 131. The first guide block 1322 is slidably engaged with the first slide block 1321. The first pushing member 1323 is connected to the first sliding block 1321, and the first pushing member 1323 can push the hook material strap 100 to move forward. When the first pushing member 1323 pushes the hook material belt 100 to move forward, the first sliding block 1321 limits the rotation of the first pushing member 1323, and when the first pushing member 1323 retreats relative to the hook material belt 100, the first pushing member 1323 can rotate relative to the first sliding block 1321.
During the forward movement of the first sliding block 1321, the first guiding block 1322 guides the first sliding block 1321, so that the accuracy of the forward movement is ensured. When the first pushing member 1323 pushes the hook material belt 100 jacked up by the first supporting component 12 forward, the first pushing member 1323 cannot rotate, so that the first pushing member 1323 is in a contact state with the hook material belt 100 in the forward movement process of the hook material belt 100, and applies a forward movement force to the hook material belt 100.
After the hook material strip 100 moves by the width of one hook 300, the first supporting component 12 descends, and the hook material strip 100 descends into the first placing groove 10. While the first cutting assembly 14 cuts and obtains a single hook 300, the first pushing member 1323 retreats relative to the hook material strip 100, and the first pushing member 1323 no longer contacts with the hook material strip 100. Because the hook material belt 100 is very thin, when the hook material belt 100 deforms and contacts the first pushing member 1323, in order to prevent the first pushing member 1323 from moving back and driving the hook material belt 100 to move back together, the first pushing member 1323 can rotate relative to the first sliding block 1321, so that the lowest end of the first pushing member 1323 does not contact the hook material belt 100.
Further preferably, the specific structure of the first pushing member 1323 is as shown in fig. 9 and fig. 10, a round hole is formed in the hook material tape 100 corresponding to each hook 300, a tip of the first pushing member 1323 is inserted into the round hole to push the hook material tape 100 to move forward, a first rotating groove 13211 is formed in the first sliding block 1321, the first pushing member 1323 is located in the first rotating groove 13211, and when the hook material tape 100 moves forward, the first pushing member 1323 can be limited to rotate by the first rotating groove 13211. When the first pushing member 1323 retreats relative to the hook material tape 100, the first pushing member 1323 can rotate in the first rotating groove 13211.
The first pushing component 132 has simple structure and low cost, and can ensure the accuracy of the forward movement of the hook material belt 100. In other embodiments, the first pushing member 1323 and the first sliding block 1321 can be integrally provided.
After the hook material strip 100 moves to the lower part of the first cutting assembly 14, the first cutting assembly 14 cuts the hook material strip 100 therebelow, and one hook 300 is obtained by cutting each time.
Specifically, as shown in fig. 8-10, the first cutting assembly 14 includes a first cutting driving element 141 and a first cutting assembly 142, wherein the first cutting driving element 141 is disposed on the hook tape worktable 11, the first cutting assembly 142 is connected to an output end of the first cutting driving element 141 (an output shaft of the first cutting driving element is not shown in the figures), under a driving action of the first cutting driving element 141, the first cutting driving element 141 can press down the first cutting assembly 142, after the first cutting assembly 142 cuts the hook tape 100, a single hook 300 is obtained, and waste materials on the hook tape 100 after the hook 300 is cut can be cut.
The first cutting driving member 141 drives the first cutting member 142 to cut and obtain a single hook 300 in the process of pushing down, and simultaneously, the first cutting member 142 can be used for cutting the residual waste materials after the hooks 300 on the hook material strip 100 are cut, so that the waste materials are not too long, and the waste materials are prevented from influencing the production.
Preferably, the first cutting assembly 142 includes a cutting guide 1421, a first cutting head 1422 and a second cutting head 1423, wherein the cutting guide 1421 is disposed on the hook strip worktable 11. The first cutting head 1422 is connected to the output end of the first push driving component 131 and is slidably engaged with the cutting guide 1421, and the first cutting head 1422 is configured to cut the hook material strip 100 to obtain the hook 300. The second cutting head 1423 is connected to the first cutting head 1422, and the second cutting head 1423 is configured to cut waste in front of the hook 300.
The first cutting head 1422 and the second cutting head 1423 are driven to simultaneously press down by the first shearing driving part 141, and the first cutting head and the second cutting head 1422 and the second cutting head 1423 are pressed down once to obtain a clamping hook 300, so that the waste materials are cut simultaneously, the working time is saved, and the production efficiency is further improved. Preferably, the first shear drive 141 is a pneumatic cylinder.
To further save time and improve work efficiency, the hook tape 100 is also moved forward by the width of one hook 300 while the cut hooks 300 are being assembled. The hook 300 obtained after cutting falls below the hook material belt 100 for assembly, and the hook material belt 100 is not influenced to move forwards when the hook 300 is assembled.
Preferably, the second hook supporting member 122 is located below the first cutting head 1422, a falling channel 1211 is disposed on the second hook supporting member 122, and the bottom of the first placing groove 10 is provided with a receiving groove 101 communicating with the falling channel 1211.
After the first cutting head 1422 cuts the hook material strip 100 to obtain the hook 300, the top of the part of the second hook supporting member 122 located in the first placing groove 10 is flush with the bottom of the first placing groove 10, so as to support the hook material strip 100. After cutting, the hook 300 falls along the falling channel 1211, and after the hook 300 falls, part of the structure of the hook 300 is located in the falling channel 1211 of the first hook supporting member 121 and part of the structure is located in the receiving groove 101.
The push-fit assembly 15 includes an assembly driving member 151 and an assembly pushing plate 152, wherein the assembly driving member 151 is disposed on the hook belt workbench 11. The assembly pushing plate 152 is connected to the output end of the assembly driving member 151, and the assembly driving member 151 can drive the assembly pushing plate 152 to mount the hook 300 located in the receiving groove 101 and the falling channel 1211 on the rubber core 200.
Specifically, a first pushing channel communicated with the accommodating groove 101 is arranged on the first hook supporting member 121, a second pushing channel communicated with the first pushing channel is arranged on the hook belt workbench 11, and the assembling pushing plate 152 is located in the first pushing channel and the second pushing channel to push the hook 300 located in the accommodating groove 101 to be assembled with the rubber core 200. In this embodiment, the first pushing channel and the second pushing channel are located below the accommodating groove 101 and the falling channel 1211, and the first pushing channel and the second pushing channel are disposed along the same direction, and the moving direction of the assembled pushing plate 152 in the first pushing channel and the second pushing channel is perpendicular to the moving direction of the hook material tape 100 and the vertical direction. Preferably, the assembly driving member 151 is a cylinder.
Fig. 11 is a schematic structural view of the loading blade assembly 2 and the second moving assembly 4, and fig. 12 is a schematic structural view of the loading blade assembly 2. Fig. 13 is a schematic structural view of the loading tab assembly 2 (excluding the chute for conveying the strip of spring tabs), fig. 14 is a schematic structural view of the press-fitting tab assembly 23, and fig. 15 is a schematic structural view of the tab cutting assembly 231. Fig. 16 is a schematic structural diagram of the second moving assembly 4. The loading device will be described in detail below with reference to fig. 11 to 16. As shown in fig. 1-2, the elastic pieces 500 are assembled on both the upper and lower sides of the rubber core 200 in this embodiment, so that when assembling the elastic pieces 500, the rubber core 200 with the elastic pieces 500 assembled on one side needs to be turned over to assemble the rubber core 200 on the other side.
The loading spring assembly 2 in the present embodiment includes a glue core workbench 21, a rotating assembly 22, and two sets of press-fitting spring assemblies 23, wherein the glue core workbench 21 is configured to place the glue core 200. The rotating assembly 22 and the two sets of press-fitting elastic sheet assemblies 23 are located on the same side of the rubber core workbench 21. Along the moving direction of the rubber core 200, two sets of press-fitting elastic sheet assemblies 23 are respectively located upstream and downstream of the rotating assembly 22, the press-fitting elastic sheet assemblies 23 are configured to cut the elastic sheet material strip 400 to obtain the elastic sheet 500, and press-fitting the elastic sheet 500 to the rubber core 200, and the rotating assembly 22 rotates the rubber core 200 with the elastic sheet 500 mounted on one side by 180 °. The other side of the core work table 21 is provided with a second moving assembly 4, and the second moving assembly 4 is configured to move the core 200 on the core work table 21.
The glue core 200 equipped with the hook 300 in this embodiment is moved to the glue core worktable 21, the second moving assembly 4 is configured to move the glue core 200 thereon, the press-fitting elastic sheet assembly 23 upstream of the rotating assembly 22 is utilized to cut the elastic sheet strip 400 to obtain individual elastic sheets 500, and the elastic sheets 500 are press-fitted on one side of the glue core 200. The second moving assembly 4 moves the glue core 200 with the elastic sheet 500 assembled on one side to the rotating assembly 22, after the rotating assembly 22 rotates the glue core 200 by 180 degrees, the second moving assembly 4 moves the glue core 200 with the elastic sheet 500 assembled on one side to the downstream press-fitting elastic sheet assembly 23 again, the press-fitting elastic sheet assembly 23 cuts another elastic sheet material strip 400 to obtain a single elastic sheet 500, and the press-fitting elastic sheets 500 are pressed again in the same way as the press-fitting elastic sheets 500 of the upstream press-fitting elastic sheet assembly 23 to complete the press-fitting of the elastic sheets 500 on both sides of the glue core 200.
In the elastic sheet loading assembly 2 in this embodiment, a set of press-fitting elastic sheet assemblies 23 are disposed upstream and downstream of the rotating assembly 22, and press-fitting of the elastic sheets 500 on both sides of the rubber core 200 can be sequentially completed. In addition, the second moving assembly 4 is utilized to enable the rubber core 200 to move forwards, and the press-fitting elastic sheet assembly 23 and the rotating assembly 22 are matched, so that the assembly process of the rubber core 200 and the elastic sheet 500 is compact, the production efficiency is improved, the production cost is reduced, the quality after the elastic sheet 500 is pressed is ensured, and the rejection rate is reduced.
Specifically, the above-mentioned press-fitting elastic sheet assembly 23 includes an elastic sheet cutting assembly 231 and an elastic sheet press-fitting assembly 232, and the elastic sheet cutting assembly 231 is configured to cut the elastic sheet material strip 400 conveyed by the elastic sheet feeding assembly to obtain the elastic sheet 500. The elastic sheet press-fitting assembly 232 moves the elastic sheet 500 to the glue core 200 on the glue core worktable 21 to press-fit the elastic sheet 500 to the glue core 200.
In this embodiment, the cutting and press-fitting processes of the elastic sheet 500 are sequentially completed by the elastic sheet cutting assembly 231 and the elastic sheet press-fitting assembly 232, and the two processes are continuously performed without time interval, so that the working efficiency is improved, and the production period is shortened.
Further specifically, the tab cutting assembly 231 includes a tab belt workbench 2311, a second supporting assembly 2312, a second pushing assembly 2313 and a second shearing assembly 2314, a second placing groove 23110 communicated with the tab feeding assembly is formed in the tab belt workbench 2311, and the tab material belt 400 is located in the second placing groove 23110. The second supporting assembly 2312 is positioned in the second placing groove 23110, and the second supporting assembly 2312 can move up and down relative to the elastic piece belt workbench 2311. The second support assembly 2312 is raised relative to the strip station 2311 to lift the strip 400 within the second placement groove 23110. The second pushing assembly 2313 is configured to push the strip of resilient material 400 lifted by the second supporting assembly 2312 within the second placement groove 23110 forward by a distance of one resilient tab 500. The second shearing assembly 2314 is configured to shear the strip of clip material 400 thereunder to access the clips 500.
During operation, the spring sheet material strip 400 is located in the second placing groove 23110, before the spring sheet material strip 400 moves forward, the second supporting assembly 2312 jacks up the spring sheet material strip 400 in the second placing groove 23110, so that the spring sheet material strip 400 is prevented from generating friction with the second placing groove 23110 in the moving process, damage is caused to the hook material strip 100, and subsequent use is influenced. Thereafter, the second pushing assembly 2313 pushes the strip 400 of spring strips to move forward by a distance of one spring 500, so that the strip 400 of spring strips is positioned below the second shearing assembly 2314, and the second shearing assembly 2314 cuts the strip to obtain the single spring 500. Then, the cut spring plate 500 is moved to the rubber core 200 equipped with the hook 300 by the second moving assembly 4 for press-fitting.
The elastic sheet cutting assembly 231 in the embodiment continuously cuts the elastic sheet material belt 400, so that the requirement of continuous work of the subsequent elastic sheet press-mounting assembly 232 is met, the continuous work is ensured, and the production efficiency is improved. And overall structure is simple, when guaranteeing the production precision, reduces overall cost.
The second support assembly 2312 includes a first clip support 23121 and a second clip support 23122, wherein the first clip support 23121 is disposed near an end of the clip feeding assembly and at least partially disposed in the second placement groove 23110, and a portion of the first clip support 23121 is configured to support a rear end of the clip material strip 400 disposed in the second placement groove 23110. The second strip support 23122 is disposed proximate an end of the second shearing assembly 2314 and is at least partially disposed within the second placement groove 23110, with portions of the second strip support 23122 being configured to support a leading end of the strip of tabbed material 400 within the second placement groove 23110. The first clip support 23121 and the second clip support 23122 can be lifted relative to the second placement groove 23110, and the first clip support 23121 and the second clip support 23122 can jack up the clip material strip 400 in the second placement groove 23110.
Before the strip of resilient material 400 needs to move forward, the first resilient support 23121 and the second resilient support 23122 are raised to lift the strip of resilient material 400 to a predetermined height, so that the strip of resilient material 400 is not in contact with the second groove 23110. After the first and second clip supports 23121 and 23122 descend, the clip strip 400 contacts the bottom of the second slot 23110, so that the second shearing assembly 2314 shears the clip strip 400 therebelow to obtain the single clips 500.
Specifically, the first dome support 23121 and the second dome support 23122 are driven to lift by the cylinder.
The second pushing assembly 2313 comprises a second pushing driving member 23131 and a second pushing assembly 23132, and the second pushing driving member 23131 is arranged on the elastic strip working table 2311. The second pushing assembly 23132 is connected to an output end of the second pushing driving element 23131, and the second pushing assembly 23132 can push the elastic piece material strip 400 jacked up by the second supporting assembly 2312 to move forward by the width of one elastic piece 500.
The second pushing driving element 23131 is used for driving the second pushing assembly 23132 to move back and forth, and in the process that the second pushing assembly 23132 moves forward, the second pushing assembly 23132 can push the elastic sheet material strip 400 jacked up by the second supporting assembly 2312 to move forward by the distance of one elastic sheet 500, so that continuous production is guaranteed. When the second supporting assembly 2312 descends, the elastic sheet material strip 400 descends to contact with the second placing groove 23110, at this time, the second pushing assembly 23132 does not contact with the elastic sheet material strip 400, and the second pushing assembly 23132 retreats without driving the elastic sheet material strip 400 to retreat.
The second pushing assembly 2313 is matched with the second supporting assembly 2312 to push the elastic sheet material belt 400 to move forwards to achieve continuous work, production efficiency is guaranteed, and the second pushing assembly 2313 is simple in structure and low in cost.
Preferably, to further ensure that second pusher assembly 23132 does not pull resilient strip 400 backward during backward movement relative to second placement groove 23110.
The second pushing assembly 23132 comprises a second slide block 23133, a second guide block 23134 and a second pushing member 23135, wherein the second slide block 23133 is connected with the output end of the second pushing driving member 23131. The second guide block 23134 is slidably engaged with the second slide block 23133. The second pushing member 23135 is connected to the second sliding block 23133, and the second pushing member 23135 can push the spring strip 400 to advance. When the pusher 23135 pushes the spring strip 400 to advance, the second sliding block 23133 limits the second pusher 23135 from rotating, and when the second pusher 23135 retreats relative to the spring strip 400, the second pusher 23135 can rotate relative to the second sliding block 23133.
During the forward movement of the second slider 23133, the second guide piece 23134 guides the second slider 23133, ensuring the accuracy of the forward movement. When the second pusher 23135 pushes the spring strip 400 jacked up by the second supporting assembly 2312 forward, the second pusher 23135 cannot rotate, so that the second pusher 23135 is in a contact state with the spring strip 400 in the forward movement process of the spring strip 400, and applies a forward movement force to the spring strip 400.
After the strip of resilient material 400 moves one width of the resilient tab 500, the second support assembly 2312 is lowered and the strip of resilient material 400 is lowered into the second placement slot 23110. While the second shearing assembly 2314 is cutting to obtain a single strip of clips 500, the second pusher 23135 is retracted relative to the strip of clip material 400 and the second pusher 23135 is no longer in contact with the strip of clip material 400. Because the strip of resilient sheet material 400 is very thin, when the strip of resilient sheet material 400 deforms and contacts the second pusher 23135, in order to prevent the second pusher 23135 from retreating and driving the strip of resilient sheet material 400 to retreat synchronously, in this embodiment, the second pusher 23135 can rotate relative to the second slider 23133, so that the lowermost end of the second pusher 23135 does not contact the strip of resilient sheet material 400.
Further preferably, the second pusher 23135 is structured as shown in fig. 15, a round hole is formed on the strip 400 corresponding to each spring 500, and the tip of the second pusher 23135 is inserted into the round hole to push the strip 400 to move forward. The second sliding block 23133 is provided with a second rotating groove 23136, the second pushing piece 23135 is positioned in the second rotating groove 23136, and when the spring strip 400 moves forwards, the second pushing piece 23135 is limited to rotate through the second rotating groove 23136. When the second pusher 23135 is retracted relative to the strip 400, the second pusher 23135 can rotate within the second rotation groove 23136.
The second pushing assembly 23132 is simple in structure and low in cost, and can ensure the accuracy of forward movement of the elastic sheet material strip 400. In other embodiments, the second pusher 23135 and the second slider 23133 can be integrally formed.
After the strip of resilient material 400 moves below the second shearing assembly 2314, the second shearing assembly 2314 shears the strip of resilient material 400 therebelow, obtaining one resilient strip 500 per cut.
Specifically, the second cutting assembly 2314 includes a second cutting drive 23141 and a second cutting assembly 23142, the second cutting drive 23141 being disposed at the tab belt station 2311. The second cutting assembly 23142 is connected to an output end of the second cutting driving member 23141, the second cutting driving member 23141 can press down the second cutting assembly 23142, a single elastic sheet 500 is obtained after the second cutting assembly 23142 cuts the elastic sheet material belt 400, and waste materials after the elastic sheet 500 is cut on the elastic sheet material belt 400 can be cut.
The second cutting driving member 23141 drives the second cutting assembly 23142 to cut and obtain a single elastic sheet 500 in the process of pressing down, and the second cutting assembly 23142 can also be used for cutting the residual waste materials after the elastic sheets 500 are cut on the elastic sheet material belt 400, so that the waste materials are not too long, and the production is not influenced. Preferably, the second shear drive 23141 is a cylinder.
Preferably, the second cutting assembly 23142 includes a cutting press 23143 and a third cutting head 23144, the cutting press 23143 is disposed at the strip work station 2311 and is configured to press the cut strip 400, and the second push drive 23131 is capable of pressing down the cutting press 23143. The third cutting head 23144 is connected to the cutting pressing member 23143, and the third cutting head 23144 is configured to cut the strip of resilient material 400 to obtain the resilient pieces 500 and simultaneously cut waste material on the strip of resilient material 400 after the resilient pieces 500 are cut.
Drive the second through second shearing driving piece 23141 and cut head 1423 and push down, once push down, acquire shell fragment 500 and cut the waste material, save operating time, further improve production efficiency.
In addition, the elastic sheet press-fitting assembly 232 includes a first press-fitting driving member 2321, a second press-fitting driving member 2322 and an adsorbing press-fitting assembly 2323, wherein the first press-fitting driving member 2321 is disposed on the elastic sheet band working table 2311. The second press-fitting driving member 2322 is connected to the output end of the first press-fitting driving member 2321, and the first press-fitting driving member 2321 drives the second press-fitting driving member 2322 to reciprocate along the Y direction, wherein the Y direction is mutually perpendicular to the moving direction and the vertical direction of the rubber core 200. The absorbing and press-fitting component 2323 is connected to the output end of the second press-fitting driving member 2322, and the second press-fitting driving member 2322 can drive the absorbing and press-fitting component 2323 to reciprocate in the vertical direction.
The suction press-fitting assembly 2323 is configured to suck a single elastic sheet 500 and move the elastic sheet 500 to the glue core 200 on the glue core worktable 21, and the second press-fitting driving member 2322 can drive the suction press-fitting assembly 2323 to press down and press the elastic sheet 500 to the glue core 200.
The size of the elastic sheet 500 is very small, the absorbing and press-fitting component 2323 absorbs the elastic sheet 500, and meanwhile, the first press-fitting driving member 2321 drives the second press-fitting driving member 2322, the absorbing and press-fitting component 2323 and the elastic sheet 500 absorbed by the absorbing and press-fitting component 2323 to move along the Y direction. After the elastic sheet 500 is moved to the proper position, that is, the elastic sheet 500 is moved to the glue core 200 on the glue core worktable 21, the second press-fitting driving member 2322 drives the suction press-fitting assembly 2323 and the elastic sheet 500 to move downward, and the elastic sheet 500 is press-fitted to one side of the glue core 200.
Above-mentioned shell fragment pressure equipment subassembly 232's simple structure only needs to utilize the adsorption of adsorbing pressure equipment subassembly 2323 to shell fragment 500, can realize moving shell fragment 500 to gluey core 200 department on gluey core workstation 21 by the below of cutting head 23144, has guaranteed that the shell fragment 500 removes the in-process and does not receive the damage, is convenient for follow-up unclamp and the installation, and adopts absorptive mode to shift shell fragment 500, and the structure is small, and occupation space is little.
Preferably, the first press-fitting driving member 2321 is a sliding table cylinder, and the second press-fitting driving member 2322 is a cylinder.
Specifically, the adsorption press-fitting assembly 2323 includes a press-fitting member, an adsorption hole is formed in the press-fitting member, and when the elastic sheet material belt 400 is cut, the press-fitting member can compress the elastic sheet 500 which is not cut on the elastic sheet material belt 400, and can adsorb the elastic sheet 500 obtained after cutting.
When the elastic strip 400 is cut, the press-fitting piece is pressed against the elastic sheet 500, the cutting pressing piece 23143 is pressed against the waste part, after the third cutting head 23144 is used for cutting the elastic sheet 500 and removing the waste, the press-fitting piece sucks the elastic sheet 500 by vacuumizing and moves to the upper side of the assembled rubber core 200 under the driving of the first press-fitting driving piece 2321, the second press-fitting driving piece 2322 drives the rubber core 200 to press downwards, and the press-fitting piece presses the adsorbed elastic sheet 500 onto the rubber core 200. Adopt above-mentioned pressure equipment piece can fix a position the shell fragment 500 when cutting to and adsorb shell fragment 500 and remove, can also pressure equipment shell fragment 500 in order to assemble shell fragment 500 and glue the core, this pressure equipment piece's simple structure, the function is many, low in manufacturing cost, easy realization.
The first moving assembly, the second moving assembly 4 and the third moving assembly in this embodiment have the same structure, but the overall structure length of each moving assembly is different, specifically, each of the first moving assembly, the second moving assembly 4 and the third moving assembly includes a first moving driving assembly 41, a second moving driving assembly 42 and a transverse moving platform assembly 43, wherein the first moving driving assembly 41 is disposed on the glue core worktable 21. The first moving driving assembly 41 is connected to an output end of the first moving driving assembly 41, and the first moving driving assembly 41 drives the second moving driving assembly 42 to reciprocate along a moving direction of the rubber core 200. The traverse platform assembly 43 is connected to the output end of the second traverse driving assembly 42, and the second traverse driving assembly 42 drives the traverse platform to reciprocate along the Y direction to release or clamp the core 200 on the core table 21.
In the present embodiment, the second moving driving assembly 42 can drive the traverse platform assembly 43 to reciprocate along the Y direction, so that the traverse platform assembly 43 can clamp or release the core 200 on the core worktable 21. When the core rubber 200 is clamped, the first moving driving assembly 41 is configured to drive the second moving driving assembly 42 and the traverse moving platform assembly 43 to reciprocate relative to the core rubber worktable 21 along the moving direction of the core rubber 200, so that the core rubber 200 moves forward when the traverse moving platform assembly 43 clamps.
Preferably, a plurality of first clamping members 431 are disposed on the traverse platform, and the plurality of first clamping members 431 are spaced apart by a predetermined distance, so that the plurality of first clamping members 431 on the core rubber worktable 21 can simultaneously clamp the plurality of core rubber 200 on the core rubber worktable 21 to simultaneously move forward.
The first clamping member 431 is provided with a fork-shaped structure at an end thereof, the second moving driving assembly 42 drives the fork-shaped structure of the first clamping member 431 to lift the rubber core 200, and the first moving driving assembly 42 drives the rubber core 200 to advance. In other embodiments, the first clamp 431 can also be a jaw cylinder.
Preferably, the first moving driving assembly 41 includes an air cylinder and a screw slider assembly, the air cylinder drives the screw slider assembly to move so as to drive the second moving driving assembly 42 to move back and forth, wherein the screw slider assembly is a conventional structure and is not repeated herein. The second movement driving assembly 42 is a cylinder.
Further preferably, a first sliding assembly is disposed between the first moving driving assembly 41 and the second moving driving assembly 42 to slidably guide the two relative to each other. The second motion drive assembly 42 and the traverse platform assembly 43 are provided with at least two sets of second slide assemblies to guide therebetween.
The first sliding component and the second sliding component are of a conventional sliding rail and sliding block structure, and are not described in detail herein.
In addition, the rotating assembly 22 includes a bracket, a rotating driver 221 and a rotating member 222, wherein the rotating driver 221 is disposed on the bracket. The rotating part 222 is communicated with the rubber core workbench 21, the second moving assembly 4 can move the rubber core 200 on the rubber core workbench 21 to the rotating part 222, the rotating driving part 221 can drive the rotating part 222 and the rubber core 200 to rotate 180 degrees, and the second moving assembly 4 moves the rubber core 200 out of the rotating part 222.
Specifically, fig. 17 is a schematic structural view of the iron shell assembly 3. As shown in fig. 17, the iron case loading assembly 3 includes an iron case loading table 31, an iron case conveying passage assembly 32, an iron case assembling assembly 33, a rubber core limiting assembly 34 and a third moving assembly, wherein the iron case loading table 31 is communicated with the rubber core table 21, and the iron case loading table 31 is configured to receive the rubber core 200 conveyed by the rubber core table 21. The iron shell conveying channel assembly 32 is arranged on one side of the iron shell loading workbench 31, the iron shell conveying channel assembly 32 is communicated with the iron shell feeding assembly, and the iron shell conveying channel assembly 32 is configured to sequentially convey the iron shells 600 conveyed by the iron shell feeding assembly to the rubber core workbench 21. The assembling iron shell assembly 33 is arranged on the other side of the iron shell assembling workbench 31 and is positioned at the downstream of the iron shell conveying channel assembly 32, and the assembling iron shell assembly 33 is configured to assemble the iron shell 600 and the rubber core 200 on the iron shell assembling workbench 31. The core rubber assembly 34 is arranged at the upstream of the iron shell conveying channel assembly 32 and is configured to limit the core rubber 200 on the iron shell installing workbench 31 to move towards the iron shell assembling assembly 33. Specifically, the third moving assembly is configured to drive the rubber core 200 and the iron shell 600 on the iron shell mounting workbench 31 to move.
Specifically, be provided with the gluey core passageway that holds gluey core 200 on dress iron-clad workstation 31, be provided with the iron-clad passageway with gluey core passageway intercommunication on the iron-clad transfer passage subassembly 32, iron-clad 600 moves to assembly iron-clad subassembly 33 department in the iron-clad passageway, and assembly iron-clad subassembly 33 will glue core 200 pressure equipment in iron-clad 600.
The iron shell conveying channel assembly 32 comprises a first air cylinder, the first air cylinder pushes the iron shell 600 in the iron shell channel to move to the glue core channel, the glue core 200 which moves to the position where the iron shell assembly 33 is assembled is clamped by the iron shell assembly 33 under the action of the third moving assembly, and when the iron shell 600 moves to the position where the iron shell assembly 33 is assembled, the iron shell assembly 33 is assembled to press the glue core 200 to the iron shell 600.
The assembly iron shell assembly 33 comprises a second cylinder and a second clamping piece, the second clamping piece is connected to the output end of the second cylinder, the second clamping piece clamps the rubber core 200, and the second cylinder drives the second clamping piece to reciprocate along the Y direction.
The limiting rubber core assembly 34 comprises a third cylinder and a blocking piece connected to the output end of the third cylinder, the third cylinder can drive the blocking piece to reciprocate along the Y direction, and the blocking piece can block the rubber core 200 on the iron shell installing workbench 31.
It is obvious that the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.
Claims (10)
1. The utility model provides a Type-C connector assembly line which characterized in that includes:
a clamping hook assembly (1), an elastic sheet assembly (2) and an iron shell assembly (3) are sequentially arranged along the movement direction of a rubber core (200) to be assembled;
the hook assembly (1) is configured to cut a hook material belt (100) to obtain a hook (300), and assemble the hook (300) on the rubber core (200);
the spring loading assembly (2) is configured to cut a spring strip (400) to obtain a spring (500), and the spring (500) is assembled on the rubber core (200) provided with the hook (300);
the iron shell assembly (3) is configured to press the rubber core (200) assembled with the clamping hook (300) and the elastic sheet (500) into an iron shell (600);
a moving assembly configured to move the glue core (200) at the loading hook assembly (1), the loading tab assembly (2) and the iron shell assembly (3) in sequence.
2. The Type-C connector assembly production line of claim 1, further comprising a rubber core tray assembly, a hook feeding assembly, a spring plate feeding assembly and an iron shell feeding assembly;
the core tray assembly is configured to provide the cores (200) to be assembled; the hook feeding component is configured to feed a hook material strip (100) to the hook assembly (1); the clip feed assembly is configured to deliver a clip material strip (400) to the clip loading assembly (2); and the iron shell feeding assembly conveys the iron shell (600) to the iron shell loading assembly (3).
3. Type-C connector assembly line according to claim 2, characterized in that said snap-in hook assembly (1) comprises:
the hook strip workbench (11) is provided with a first placing groove (10) communicated with the hook feeding assembly, and the hook strip (100) can be positioned in the first placing groove (10);
a first support component (12) positioned in the first placing groove (10), wherein the first support component (12) can perform lifting motion relative to the hook strip workbench (11);
the first supporting component (12) is lifted relative to the hook strip workbench (11) and can jack up the hook strip (100) in the first placing groove (10);
a first pushing component (13) which is configured to push the hook material belt (100) jacked up by the first supporting component (12) in the first placing groove (10) to move forwards by the distance of at least one hook (300);
a first cutting assembly (14) configured to cut the strip (100) of hooks positioned thereunder to obtain hooks (300);
the pushing assembly (15) is configured to push the clamping hook (300) and press the clamping hook to the rubber core (200).
4. Type-C connector assembly line according to claim 3, characterized in that said first support assembly (12) comprises:
the first hook supporting piece (121) is arranged at one end close to the hook feeding component, at least part of the structure of the first hook supporting piece is positioned in the first placing groove (10), and the first hook supporting piece (121) is configured to support the rear end of the hook material belt (100) positioned in the first placing groove (10);
a second hook support (122) disposed near one end of the first cutting assembly (14) and at least partially disposed in the first placement slot (10), wherein the second hook support (122) is configured to support a front end of the hook material strip (100) in the first placement slot (10);
the first hook supporting piece (121) and the second hook supporting piece (122) can be lifted relative to the first placing groove (10); the first hook supporting piece (121) and the second hook supporting piece (122) can jack up the hook material belt (100) in the first placing groove (10), and the hook material belt (100) can be placed in the first placing groove (10).
5. Type-C connector assembly line according to claim 3 or 4, characterized in that said first pushing assembly (13) comprises:
a first push driving member (131) provided on the hook tape table (11);
the first pushing component (132) is connected to the output end of the first pushing driving piece (131), and the first pushing component (132) can push the hook material belt (100) jacked up by the first supporting component (12) to move forwards by the width of the hook (300).
6. Type-C connector assembly line according to claim 3 or 4, characterized in that said first shearing assembly (14) comprises:
a first shearing driving member (141) arranged on the hook strip workbench (11);
a first cutting assembly (142) connected to an output of the first shear drive (141), the first shear drive (141) capable of depressing the first cutting assembly (142);
after the first cutting component (142) cuts the hook material belt (100), a single hook (300) is obtained, and waste materials on the hook material belt (100) after the hook (300) is cut can be cut.
7. Type-C connector assembly line according to claim 2 or 3, characterized in that said loading tab assembly (2) comprises:
a core work table (21) configured to place the core (200);
the rotating assembly (22) and the two groups of press-fitting elastic sheet assemblies (23) are positioned on the same side of the rubber core workbench (21), and the two groups of press-fitting elastic sheet assemblies (23) are respectively positioned on the upstream and downstream of the rotating assembly (22) along the movement direction of the rubber core (200);
the press-fitting elastic sheet assembly (23) is configured to cut the elastic sheet material belt (400) to obtain an elastic sheet (500), press-fitting the elastic sheet (500) to the rubber core (200), and the rotating assembly (22) rotates the rubber core (200) with one side provided with the elastic sheet (500) for 180 degrees;
the other side of the rubber core workbench (21) is provided with the moving assembly, and the moving assembly is configured to move the rubber core (200) on the rubber core workbench (21).
8. The Type-C connector assembly line of claim 7, wherein the press-fit spring plate assembly (23) comprises:
a shrapnel cutting assembly (231) configured to cut the shrapnel material tape (400) conveyed by the shrapnel feeding assembly to obtain the shrapnel (500);
the elastic sheet press-fitting assembly (232) moves the elastic sheet (500) to the rubber core (200) on the rubber core workbench (21) so as to press-fit the elastic sheet (500) to the rubber core (200).
9. Type-C connector assembly line according to claim 7, characterized in that said rotating assembly (22) comprises:
a support;
a rotary drive member (221) disposed on the bracket;
the rotating piece (222) is communicated with the rubber core workbench (21), the moving assembly can move the rubber core (200) on the rubber core workbench (21) to the rotating piece (222), and the rotating driving piece (221) can drive the rotating piece (222) and the rubber core (200) to rotate 180 degrees.
10. Type-C connector assembly line according to claim 7, characterized in that said ironclad assembly (3) comprises:
the iron shell loading workbench (31) is communicated with the rubber core workbench (21) and is configured to receive the rubber core (200) conveyed by the rubber core workbench (21);
the iron shell conveying channel assembly (32) is arranged on one side of the iron shell loading workbench (31), the iron shell conveying channel assembly (32) is communicated with the iron shell feeding assembly, and the iron shell conveying channel assembly (32) is configured to convey the iron shells (600) conveyed by the iron shell feeding assembly to the rubber core workbench (21) in sequence;
an assembling iron shell assembly (33) arranged on the other side of the iron shell assembling workbench (31) and located at the downstream of the iron shell conveying channel assembly (32), wherein the assembling iron shell assembly (33) is configured to assemble the iron shell (600) and the rubber core (200) on the iron shell assembling workbench (31);
a limiting core rubber assembly (34) which is arranged at the upstream of the iron shell conveying channel assembly (32) and is configured to limit the core rubber (200) on the iron shell loading workbench (31) to move to the assembling iron shell assembly (33);
the moving assembly can drive the rubber core (200) and the iron shell (600) on the iron shell loading workbench (31) to move.
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CN111293559A (en) * | 2020-03-25 | 2020-06-16 | 江西日盛精密五金有限公司 | Type-C connector assembling line |
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2020
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Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN111293559A (en) * | 2020-03-25 | 2020-06-16 | 江西日盛精密五金有限公司 | Type-C connector assembling line |
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