CN216541753U - Tail fiber assembly pressing machine - Google Patents

Abstract

The utility model provides a tail fiber assembly pressing machine, which comprises: a conveying mechanism; is rotatably arranged; the material taking mechanism is arranged on one side of the conveying mechanism; the material taking mechanism is used for respectively taking and delivering the SUS metal piece and the inserting core to the conveying mechanism; the pressing mechanism is arranged on the other side of the conveying mechanism; the pressing mechanism comprises pressing pins which can move along the vertical direction, and the pressing pins are arranged towards the conveying mechanism. The material taking mechanism and the pressing mechanism are arranged on the side edge of the conveying mechanism, so that the overall layout is more compact, and the overall size can be reduced. During pressing, the material taking mechanism respectively takes and delivers the SUS metal piece and the inserting core to the conveying mechanism, the inserting core is located above the SUS metal piece, the conveying mechanism rotates to convey the SUS metal piece and the inserting core to the lower portion of the pressing pin, the pressing pin vertically moves downwards, and the inserting core is pressed into the SUS metal piece to complete pressing of the tail fiber assembly. Compared with the prior art in which the tail fiber assembly is manually pressed and assembled, the production efficiency can be improved, and the manual labor intensity can be reduced.

Description

Tail fiber assembly pressing machine

Technical Field

The utility model relates to the field of tail fiber assembly assembling, in particular to a tail fiber assembly pressing machine.

Background

The tail fiber is connected with the fiber cores of other optical cables through fusion splicing, and is usually arranged in an optical fiber terminal box and used for connecting the optical cables with an optical fiber transceiver. The tail fiber is divided into multimode tail fiber and single-mode tail fiber. The connector is also called the tail fiber subassembly, and the tail fiber subassembly is bonded with glue between 125um optic fibre and the pottery lock pin, and SUS metalwork and pottery lock pin are through interference fit pressfitting to form.

In the prior art, the pigtail assembly is usually manually assembled by a human, and the general steps are as follows: the lock pin and the SUS metal piece are fixed in sequence by manpower, and then the lock pin and the SUS metal piece are pressed together by a manual pressing tool. The labor intensity of manually assembling the tail fiber assembly is high, and the yield is low.

Therefore, the prior art has defects and needs to be improved and developed.

SUMMERY OF THE UTILITY MODEL

In view of the above-mentioned shortcomings of the prior art, the present invention provides a pigtail module pressing machine, which aims to solve the problem of low efficiency of manually assembling pigtail modules in the prior art.

The technical scheme adopted by the utility model for solving the technical problem is as follows:

a pigtail assembly press comprising:

a conveying mechanism; is rotatably arranged;

the material taking mechanism is arranged on one side of the conveying mechanism; the material taking mechanism is used for respectively taking and delivering an SUS metal piece and an inserting core to the conveying mechanism, and the inserting core is placed above the SUS metal piece;

the pressing mechanism is arranged on the other side of the conveying mechanism; the pressing mechanism comprises pressing needles which are movable in the vertical direction and are arranged towards the conveying mechanism.

Further, the material taking mechanism comprises a first material taking part and a second material taking part which are arranged on the outer side of the conveying mechanism;

the first material taking part is used for taking and delivering the SUS metal piece to the conveying mechanism;

the second material taking part and the first material taking part are arranged at intervals, and the second material taking part is used for taking and delivering the inserting core to the conveying mechanism.

Further, the first material taking part comprises a first cylinder, a second cylinder and a first suction head;

the first air cylinder is arranged along the length direction;

the second air cylinder is arranged along the vertical direction and is arranged on the driving end of the first air cylinder;

the first suction head is arranged at one end, facing the conveying mechanism, of the second air cylinder;

the second material taking part comprises a third cylinder, a fourth cylinder and a second suction head;

the third air cylinder is a rotary air cylinder arranged along the vertical direction, and can rotate towards the conveying mechanism;

the fourth cylinder is mounted on the third cylinder;

the second suction head is mounted on the third cylinder.

Further, the conveying mechanism comprises a rotary table which is arranged in a rotating mode and a tool which is arranged on the rotary table;

the tool is connected with the turntable; the tool comprises a mounting plate and a bulge arranged on the mounting plate; and the protrusion is provided with a limiting hole for placing the SUS metal piece.

Further, the pressing mechanism further comprises a sleeve and a bottom plate positioned below the sleeve;

the sleeve comprises a first cylinder and a second cylinder positioned below the first cylinder, and the first cylinder is embedded in the second cylinder in a vertically movable manner; the pressing needle is connected with the top of the first cylinder;

the second cylinder is connected with the bottom plate, a groove is formed in the side wall of the second cylinder and communicated with the inside of the second cylinder, and the groove faces the material taking mechanism;

the bottom plate is arranged above the tool; the bottom plate is provided with a first through hole; the axis of the first through hole is coincided with the axis of the limiting hole and the axis of the pressing pin.

Further, the pressing mechanism further comprises a fixing plate and a fifth air cylinder;

the fifth cylinder is arranged along the vertical direction;

the bottom plate is arranged on the fixing plate, the fixing plate is arranged above the tool, and the fixing plate is in driving connection with the fifth cylinder; and a second through hole is formed in the fixing plate, and the axis of the second through hole is superposed with the axis of the first through hole.

Furthermore, the pressing mechanism further comprises a first screw rod module and a pressing head which are arranged above the tool;

the first lead screw module is arranged along the vertical direction;

the pressure head is located the first lead screw module orientation the one end of first barrel, the pressure head with first lead screw module drive is connected.

Furthermore, the tail fiber assembly pressing machine also comprises a first vibration material tray, a linear feeder, a second vibration material tray and a feeding pipeline which are arranged on one side of the conveying mechanism;

the first vibration tray is used for placing the SUS metal piece;

the linear feeder is connected with the first vibration tray, so that the SUS metal piece can enter the linear feeder;

the second vibration material tray and the first vibration material tray are arranged at intervals, the second vibration material tray is used for placing the inserting core, and the feeding pipeline is connected with the second vibration material tray, so that the inserting core can enter the feeding pipeline.

Further, the tail fiber assembly pressing machine further comprises a material distributing plate arranged between the linear feeder and the conveying mechanism;

the material separating plate is movably arranged in the direction vertical to the linear feeder, and a limiting groove used for accommodating one SUS metal piece is formed in one side, facing the output end of the linear feeder, of the material separating plate; the limiting groove is provided with an opening, and the opening faces to the output end of the linear feeder.

Furthermore, the tail fiber assembly pressing machine also comprises a discharging mechanism arranged on one side of the conveying mechanism, and the discharging mechanism comprises a first belt module, a sixth cylinder, a third suction head and a material cup;

the first belt module is positioned above the conveying mechanism and arranged along the length direction;

the sixth air cylinder is vertically arranged on the first belt module;

the third suction head is arranged at one end, facing the conveying mechanism, of the sixth cylinder;

the material cup is arranged below the third suction head.

According to the technical scheme, the utility model has at least the following advantages and positive effects:

according to the utility model, the conveying mechanism is rotatably arranged, and the material taking mechanism and the pressing mechanism are both arranged on the side edge of the conveying mechanism, so that the overall layout is more compact, and the overall size can be reduced. During pressing, the material taking mechanism respectively takes and sends the SUS metal piece and the inserting core to the conveying mechanism, the inserting core is located above the SUS metal piece, the conveying mechanism rotates to convey the SUS metal piece and the inserting core to the lower portion of the pressing pin, the pressing pin vertically moves downwards, and the inserting core is pressed into the SUS metal piece, so that pressing of the tail fiber assembly is completed. Compared with the prior art in which the tail fiber assembly is manually pressed and assembled, the production efficiency can be improved, and the manual labor intensity can be reduced.

Drawings

FIG. 1 is a schematic view of a pigtail assembly press according to an embodiment of the utility model.

FIG. 2 is a schematic view of a portion of the assembly of a pigtail assembly press in an embodiment of the utility model.

FIG. 3 is a front view of a pigtail assembly press in an embodiment of the utility model.

Fig. 4 is an enlarged schematic view of a portion a in fig. 3.

Fig. 5 is an enlarged schematic view of a portion B in fig. 3.

FIG. 6 is a side view of a pigtail assembly press in an embodiment of the utility model.

Fig. 7 is an enlarged schematic view of a portion C in fig. 6.

Fig. 8 is a schematic view of a tooling structure of a pigtail assembly pressing machine according to an embodiment of the utility model.

Fig. 9 is a schematic structural view of a pigtail assembly.

Description of reference numerals:

100. a tail fiber component pressing machine; 1. a conveying mechanism; 11. a turntable; 12. assembling; 121. mounting a plate; 122. a protrusion; 1221. a limiting hole; 13. a stepping motor; 14. a cam divider; 2. a material taking mechanism; 21. a first material taking part; 211. a first cylinder; 212. a second cylinder; 213. a first suction head; 22. a second material taking part; 221. a third cylinder; 222. a fourth cylinder; 223. a second suction head; 3. a pressing mechanism; 31. a sleeve; 311. a first cylinder; 312. a second cylinder; 3121. a groove; 32. a base plate; 33. a fixing plate; 34. a fifth cylinder; 35. a first lead screw module; 36. a pressure head; 41. a first vibrating tray; 42. a linear feeder; 43. a second vibrating tray; 44. a feed line; 45. a material distributing plate; 451. a limiting groove; 46. a seventh cylinder; 5. a discharge mechanism; 51. a first belt module; 52. a sixth cylinder; 53. a third suction head; 54. a material cup; 61. pressing in a size sensor; 200. a pigtail assembly; 2001. SUS metal members; 2002. and (4) inserting cores.

Detailed Description

Reference will now be made in detail to embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like or similar 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 accompanying drawings are illustrative only for the purpose of explaining the present invention, and are not to be construed as limiting the present invention.

Referring to fig. 1 to 5 and 9, in an embodiment of the present invention, a pigtail module pressing machine 100 is provided for pressing the pigtail module 200. The pigtail assembly 200 comprises an SUS metal 2001 and a ferrule 2002, wherein the SUS metal 2001 is substantially cylindrical, a boss is arranged at one end of the circumference of the SUS metal 2001, a hole is formed in the axis of the SUS metal 2001, and the ferrule 2002 is inserted into the hole. The ferrule 2002 is typically a ferrule 2002. The specific structure of the pigtail assembly 200 can be referred to the related art, and will not be described in detail herein. For convenience of description, referring to the direction of the coordinate system in fig. 1, the direction of the X axis of the coordinate system is referred to as the longitudinal direction, the direction of the Y axis of the coordinate system is referred to as the width direction, and the direction of the Z axis of the coordinate system is referred to as the vertical direction or the height direction.

The tail fiber assembly pressing machine 100 comprises a conveying mechanism 1 which is rotatably arranged, a material taking mechanism 2 which is arranged on one side of the conveying mechanism 1 and a pressing mechanism 3 which is arranged on the other side of the conveying mechanism 1. The material taking mechanism 2 is used for respectively conveying the SUS metal member 2001 and the ferrule 2002 to the conveying mechanism 1, and putting the SUS metal member 2001 and the ferrule 2002 in a pressing state, namely the ferrule 2002 is positioned above the SUS metal member 2001. The conveying mechanism 1 is used for conveying the SUS metal piece 2001 and the ferrule 2002 to the pressing mechanism 3 to facilitate pressing by the pressing mechanism 3. Conveying mechanism 1 is roughly circular, extracting mechanism 2 with pressing mechanism 3 all sets up conveying mechanism 1's side can make holistic overall arrangement compacter, reducible holistic volume. During pressing, the material taking mechanism 2 respectively takes the SUS metal member 2001 and the ferrule 2002 to the conveying mechanism 1, the ferrule 2002 is positioned above the SUS metal member 2001, the conveying mechanism 1 rotates to convey the SUS metal member 2001 and the ferrule 2002 to the lower part of the pressing pin (not shown), the pressing pin moves vertically downwards to press the ferrule 2002 into the SUS metal member 2001, and pressing and assembling of the pigtail assembly 200 is completed. Compared with the prior art that the pigtail assembly 200 is assembled by manual pressing, the production efficiency can be improved, and the manual labor intensity can be reduced.

Specifically, referring to fig. 1 to 4, as a specific implementation manner of the present embodiment, the material taking mechanism 2 includes a first material taking part 21 and a second material taking part 22, which are disposed outside the conveying mechanism 1. The first material taking part 21 is used for taking and delivering the SUS metal piece 2001 to the conveying mechanism 1, the second material taking part 22 and the first material taking part 21 are arranged at intervals, the second material taking part 22 is used for taking and delivering the ferrule 2002 to the conveying mechanism 1, namely, the first material taking part 21 firstly takes and delivers the SUS metal piece 2001 to the conveying mechanism 1, the conveying mechanism 1 rotates to the second material taking part 22, and the second material taking part 22 takes and delivers the ferrule 2002 to the conveying mechanism 1, so that the ferrule 2002 is placed above the SUS metal piece 2001. The SUS metal 2001 and the ferrule 2002 may be fixed to the transport mechanism 1 by a corresponding jig.

Specifically, referring to fig. 1 to 4, as a specific implementation manner of the present embodiment, the first material taking part 21 includes a first cylinder 211, a second cylinder 212, and a first suction head 213. The first cylinder 211 is disposed in a length direction, and thus a moving end of the first cylinder 211 moves in the length direction. The second cylinder 212 is disposed in a vertical direction, and thus the moving end of the second cylinder 212 moves in a vertical direction. The second cylinder 212 is installed at a driving end of the first cylinder 211, and particularly, the second cylinder 212 is installed at a moving end of the first cylinder 211, and thus, the moving end of the second cylinder 212 has moving characteristics in a length direction and a vertical direction. The first suction head 213 is installed at an end of the second cylinder 212 facing the transporting mechanism 1, and particularly, the first suction head 213 is installed at a moving end of the second cylinder 212 and facing the transporting mechanism 1, and thus, the moving end of the first suction head 213 has moving characteristics in a length direction and a vertical direction. The first suction head 213 has an air hole on the bottom surface thereof, and sucks the SUS metal 2001 by negative pressure. In operation, when the first material taking part 21 is stopped above the SUS metal member 2001 to be grabbed, the second air cylinder 212 moves vertically downward, so that the first suction head 213 touches and sucks the SUS metal member 2001 to be grabbed, after the sucking, the second air cylinder 212 moves vertically upward to a preset position, then the first air cylinder 211 moves to a preset position along the length direction towards one side of the conveying mechanism 1 and is stopped right above the conveying mechanism 1, and the second air cylinder 212 moves vertically downward, so that the grabbed SUS metal member 2001 is placed on the conveying device, and the grabbing and feeding of the SUS metal member 2001 are completed.

The second take off section 22 includes a third cylinder 221, a fourth cylinder 222 and a second suction head 223. The third cylinder 221 is a rotation cylinder disposed in a vertical direction, that is, a rotation plane of a moving end of the third cylinder 221 is an XOZ plane, so that the third cylinder 221 disposed at a side where the conveying mechanism 1 is disposed can rotate toward the conveying mechanism 1. The fourth cylinder 222 is installed on the third cylinder 221, an initial position of the fourth cylinder 222 is in a vertical state, and a movable end of the fourth cylinder 222 faces downward vertically. The second suction head 223 is installed on the third cylinder 221, and an air hole is formed in the bottom surface of the second suction head 223, so that the insertion core 2002 is sucked by negative pressure. In operation, the fourth cylinder 222 moves vertically, the second suction head 223 touches the ferrule 2002 to be sucked, the ferrule 2002 to be sucked is in a lying state, the second suction head 223 sucks the ferrule 2002 and then moves upwards to a preset position, then the third cylinder 221 rotates 90 degrees, at this time, the fourth cylinder 222 is arranged along the X-axis direction, at this time, the ferrule 2002 is in a standing state, then the fourth cylinder 222 moves towards one side close to the conveying mechanism 1 along the X-axis direction, the ferrule 2002 is placed on the conveying mechanism 1, and the ferrule 2002 is located above the SUS metal piece 2001.

Specifically, referring to fig. 1 to 5 and 8, as a specific implementation manner of the present embodiment, the conveying mechanism 1 includes a rotating disc 11 and a tool 12 disposed on the rotating disc 11. The turntable 11 is in a disk shape and is arranged to lie flat. The rotary disc 11 is driven by a stepping motor 13 and a cam divider 14, specifically, the stepping motor 13 drives the cam divider 14 to move, and then the cam divider 14 drives the rotary disc 11 to move, so that the rotary disc 11 can rotate a preset angle each time, and the first material taking part 21 and the second material taking part 22 can take materials conveniently. The tool 12 is fixedly connected with the turntable 11. The tool 12 comprises an installation plate 121 and a bulge 122 installed on the installation plate 121, wherein a limiting hole 1221 used for placing the SUS metal piece 2001 is formed in the bulge 122.

In this embodiment, the edge of the turntable 11 is provided with four fixtures 12, an included angle between any two adjacent fixtures 12 is 90 degrees, an included angle between a connecting line from the first material taking part to the center of the turntable 11 and a connecting line from the pressing mechanism 3 to the center of the turntable 11 is 90 degrees, and the second material taking part 22 is in the condition that the fixtures 12 are stopped for feeding below the pressing mechanism 3. The turntable 11 rotates 90 degrees each time, so that the loading and the pressing are convenient.

Specifically, referring to fig. 1, fig. 3 and fig. 5, as a specific implementation manner of the present embodiment, the pressing mechanism 3 further includes a sleeve 31 and a bottom plate 32 located below the sleeve 31. The sleeve 31 comprises a first cylinder 311 and a second cylinder 312 located below the first cylinder 311, the first cylinder 311 is embedded in the second cylinder 312 in a vertically movable manner, and the first cylinder 311 is embedded in the second cylinder 312 in a vertically movable manner by embedding a spring at the bottom of the first cylinder 311.

The pressing pin is approximately cylindrical, and the bottom of the pressing pin is pointed. The pressing pin is connected to the top of the first cylinder 311, so that the pressing pin can move downward numerically when hitting the top of the first cylinder 311.

The bottom of the second cylinder 312 is connected to the bottom plate 32, a groove 3121 is formed in a side wall of the second cylinder 312, the groove 3121 is communicated with the inside of the second cylinder 312, the groove 3121 faces the material taking mechanism 2, specifically, the groove 3121 faces the second material taking part 22 of the material taking mechanism 2, so that, when the third cylinder 221 rotates, the fourth cylinder 222 can vertically place the sucked insert 2002 into the second cylinder 312 through the groove 3121.

The bottom plate 32 is disposed above the fixture 12, a first through hole (not shown) is formed in the bottom plate 32, and an axis of the first through hole coincides with an axis of the limiting hole 1221 and an axis of the presser pin, so that the ferrule 2002 placed in the second cylinder 312 can be placed above the SUS metal 2001. After the fixture 12 is stopped below the bottom plate 32, the pressing pin moves downward, penetrates through the first through hole and presses the ferrule 2002 into the SUS metal 2001.

Specifically, referring to fig. 3 and 5, as a specific implementation manner of the present embodiment, the pressing mechanism 3 further includes a fixing plate 33 and a fifth cylinder 34. The fifth cylinder 34 is disposed in a vertical direction, and thus a driving end of the fifth cylinder 34 moves in the vertical direction.

The fixing plate 33 has a substantially plate shape, and the fixing plate 33 is laid flat. The base plate 32 is mounted on the fixing plate 33, that is, the sleeve 31 is fixed on the fixing plate 33 by the base plate 32. The fixing plate 33 is disposed above the tool 12, and the fixing plate 33 is in driving connection with the fifth cylinder 34, so that the fixing plate 33 can move in the vertical direction. The fixing plate 33 is formed with a second through hole (not shown), and an axis of the second through hole coincides with an axis of the first through hole, so that the ferrule 2002 and the press pin can pass through the second through hole.

Therefore, before the ferrule 2002 is put into the second cylinder 312, the fixing plate 33 moves downward and presses on the tool 12, and then the ferrule 2002 is put into the second cylinder 312, and the ferrule 2002 enters the second through hole along the first through hole and is positioned above the SUS metal 2001. After the second material taking part 22 finishes the loading of the ferrule 2002, the press pin moves vertically downward, sequentially passes through the first through hole and the second through hole, and presses the ferrule 2002 into the SUS metal piece 2001.

Specifically, referring to fig. 1, fig. 3 and fig. 5, as a specific implementation manner of the present embodiment, the pressing mechanism 3 further includes a first screw rod module 35 and a pressing head 36, which are disposed above the tooling 12. The first lead screw module 35 is disposed along the vertical direction, so that the slider of the first lead screw module 35 can move along the vertical direction. The pressing head 36 is located at one end of the first lead screw module 35 facing the first barrel 311, and the pressing head 36 is in driving connection with the first lead screw module 35, that is, the pressing head 36 can move along the vertical direction along with the slider of the first lead screw module 35. When the ram 36 moves vertically downward, it may strike the first cylinder 311 to push the presser pin downward to press the ferrule 2002 into the SUS metal 2001.

Specifically, referring to fig. 1 to 4, as a specific implementation manner of the present embodiment, the pigtail assembly pressing machine 100 further includes a first vibrating tray 41, a linear feeder 42, a second vibrating tray 43 and a feeding duct 44, which are disposed at one side of the conveying mechanism 1.

The first vibratory tray 41 has a substantially disk shape, and the SUS metal 2001 is placed on the first vibratory tray 41. The linear feeder 42 is disposed in a longitudinal direction. The linear feeder 42 is connected to the first vibratory tray 41 so that the SUS metal parts 2001 can be introduced into the linear feeder 42, and the linear feeder 42 can sequentially output the SUS metal parts 2001 to be sucked by the first material taking section 21. The SUS metal 2001 fed out from the linear feeder 42 is in an upright state. The specific structure and operation of the vibratory pan and the linear feeder 42 may be referred to in the related art and will not be described in detail herein.

The second vibratory tray 43 is substantially disc-shaped, the second vibratory tray 43 is spaced apart from the first vibratory tray 41, the second vibratory tray 43 is used for placing the ferrules 2002, and the feeding pipe 44 is connected to the second vibratory tray 43 so that the ferrules 2002 can enter the feeding pipe 44. Because the diameter of the feeding pipe is slightly larger than that of the insertion core 2002 and the end of the feeding pipe 44 is in a horizontal state, the insertion core 2002 output by the feeding pipe 44 is in a flat state so as to be conveniently sucked by the second material taking part 22.

Specifically, referring to fig. 6 and 7, as a specific implementation manner of the present embodiment, the pigtail assembly pressing machine 100 further includes a material distribution plate 45 disposed between the linear feeder 42 and the conveying mechanism 1.

The material distributing plate 45 is plate-shaped, and the material distributing plate 45 is movably disposed in a direction perpendicular to the linear feeder 42, that is, the material distributing plate 45 is movable in a width direction. A limiting groove 451 for accommodating one SUS metal 2001 is formed in one side of the material separating plate 45 facing the output end of the linear feeder 42, and the limiting groove 451 has an opening facing the output end of the linear feeder 42. Therefore, when the limiting groove 451 of the material separating plate 45 is aligned with the output end of the linear feeder 42, one of the SUS metal members 2001 may be inserted into the limiting groove 451. After one SUS metal 2001 enters the limiting groove 451, the material separating plate 45 moves in the vertical direction, and the side edge of the material separating plate 45 blocks the output end of the linear feeder 42, so that one SUS metal 2001 can be separated at a time.

The pigtail assembly pressing machine 100 further comprises a seventh cylinder 46 arranged at one end of the material distribution plate 45 in the width direction, the seventh cylinder 46 is arranged in the width direction, and the material distribution plate 45 is in driving connection with the seventh cylinder 46, so that the material distribution plate 45 can move in the width direction.

Specifically, referring to fig. 3 and 5, as a specific implementation manner of this embodiment, the pigtail assembly pressing machine 100 further includes a discharging mechanism 5 disposed on one side of the conveying mechanism 1, and an included angle between a connecting line between the circle centers of the discharging mechanism 5 and the rotary table 11 and a connecting line between the circle centers of the pressing mechanism 3 and the rotary table 11 is 90 degrees, so that after pressing, the rotary table 11 rotates 90 degrees to perform discharging, and the discharged work is rotated to a position below the first material taking portion 21, so that simultaneous discharging and feeding can be achieved.

The discharging mechanism 5 comprises a first belt module 51, a sixth air cylinder 52, a third suction head 53 and a material cup 54. The first belt module 51 is located above the conveying mechanism 1, and the first belt module 51 is arranged along the length direction. The sixth cylinder 52 is vertically installed on the first belt module 51, so that the sixth cylinder 52 can move in the length direction and the vertical direction. The third suction head 53 is installed at an end of the sixth cylinder 52 facing the transporting mechanism 1, and thus, the third suction head 53 is movable in a length direction and a vertical direction. The material cup 54 is arranged below the third suction head 53 and is used for receiving the tail fiber assembly 200 unloaded from the third suction head 53. In operation, after the pressed pigtail assembly 200 rotates to the discharging mechanism 5, the sixth cylinder 52 moves along the length direction, so that the sixth cylinder 52 is about to stop above the tooling 12, the third suction head 53 moves downwards and adsorbs the pigtail assembly 200, and then returns to the initial position, the sixth cylinder 52 moves vertically downwards, and the pigtail assembly 200 is placed in the material cup 54, so as to complete discharging.

The pigtail assembly press 100 further comprises a press-in size sensor 61 and a load cell (not shown) arranged in the first lead screw module 35 to monitor the pressure during pressing. The pressing size sensor 61 is provided at one side of the ram 36 to monitor the stroke of the ram 36 to determine whether the pressing size meets a standard. The pressing quality can be judged by the pressing size sensor 61 and the load cell.

The material cups 54 are four, the three material cups 54 are arranged at intervals along the horizontal direction, and the four material cups 54 are respectively used for receiving the tail fiber assemblies 200 with good products, poor pressing sizes, overlarge pressing force and undersize pressing force along the direction far away from the turntable 11, so that the tail fiber assemblies 200 are rapidly classified, the follow-up manual screening and sorting are not needed, and the manual labor intensity can be reduced.

In summary, the present invention provides a tail fiber assembly pressing machine 100, the conveying mechanism 1 of the tail fiber assembly pressing machine 100 is rotatably disposed, and the material taking mechanism 2 and the pressing mechanism 3 are both disposed at the side of the conveying mechanism 1, so that the overall layout is more compact, and the overall volume can be reduced. During pressing, the material taking mechanism 2 respectively takes the SUS metal piece 2001 and the insertion core 2002 to the conveying mechanism 1, the insertion core 2002 is located above the SUS metal piece 2001, the conveying mechanism 1 rotates to convey the SUS metal piece 2001 and the insertion core 2002 to the lower side of the pressing pin, the pressing pin moves vertically downwards, and the insertion core 2002 is pressed into the SUS metal piece 2001, so that pressing of the tail fiber assembly 200 is completed. Compared with the prior art that the pigtail assembly 200 is assembled by manual pressing, the production efficiency can be improved, and the manual labor intensity can be reduced.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the utility model and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the utility model.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or to implicitly indicate the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

Naturally, the above embodiments of the present invention are described in detail, but it should not be understood that the scope of the present invention is limited thereto, and other various embodiments of the present invention can be obtained by those skilled in the art without any creative work based on the embodiments, and the scope of the present invention is subject to the appended claims.

Claims (10)

1. A pigtail assembly press, comprising:

a conveying mechanism; is rotatably arranged;

the material taking mechanism is arranged on one side of the conveying mechanism; the material taking mechanism is used for respectively taking and delivering an SUS metal piece and an inserting core to the conveying mechanism, and the inserting core is placed above the SUS metal piece;

the pressing mechanism is arranged on the other side of the conveying mechanism; the pressing mechanism comprises pressing needles which are movable in the vertical direction and are arranged towards the conveying mechanism.

2. The pigtail assembly press of claim 1, wherein the take-off mechanism comprises a first take-off section and a second take-off section disposed outside the conveying mechanism;

the first material taking part is used for taking and delivering the SUS metal piece to the conveying mechanism;

the second material taking part and the first material taking part are arranged at intervals, and the second material taking part is used for taking and delivering the inserting core to the conveying mechanism.

3. The pigtail assembly press of claim 2,

the first material taking part comprises a first cylinder, a second cylinder and a first suction head;

the first air cylinder is arranged along the length direction;

the second air cylinder is arranged along the vertical direction and is arranged on the driving end of the first air cylinder;

the first suction head is arranged at one end of the second cylinder facing the conveying mechanism;

the second material taking part comprises a third cylinder, a fourth cylinder and a second suction head;

the third air cylinder is a rotary air cylinder arranged along the vertical direction, and can rotate towards the conveying mechanism;

the fourth cylinder is mounted on the third cylinder;

the second suction head is mounted on the third cylinder.

4. The pigtail assembly press of claim 1, wherein the delivery mechanism comprises a rotatably disposed turntable and a tooling disposed on the turntable;

the tool is connected with the turntable; the tool comprises a mounting plate and a bulge arranged on the mounting plate; and the protrusion is provided with a limiting hole for placing the SUS metal piece.

5. The pigtail assembly press of claim 4, wherein the pressing mechanism further comprises a sleeve and a bottom plate located below the sleeve;

the sleeve comprises a first cylinder and a second cylinder positioned below the first cylinder, and the first cylinder is embedded in the second cylinder in a vertically movable manner; the pressing needle is connected with the top of the first cylinder;

the second cylinder is connected with the bottom plate, a groove is formed in the side wall of the second cylinder and communicated with the inside of the second cylinder, and the groove faces the material taking mechanism;

the bottom plate is arranged above the tool; the bottom plate is provided with a first through hole; the axis of the first through hole is coincided with the axis of the limiting hole and the axis of the pressing pin.

6. The pigtail assembly press of claim 5, wherein the pressing mechanism further comprises a fixed plate and a fifth cylinder;

the fifth cylinder is arranged along the vertical direction;

the bottom plate is arranged on the fixing plate, the fixing plate is arranged above the tool, and the fixing plate is in driving connection with the fifth cylinder; and a second through hole is formed in the fixing plate, and the axis of the second through hole is superposed with the axis of the first through hole.

7. The pigtail assembly press of claim 6, wherein the pressing mechanism further comprises a first lead screw module and a ram disposed above the tooling;

the first lead screw module is arranged along the vertical direction;

the pressure head is located the first lead screw module orientation the one end of first barrel, the pressure head with first lead screw module drive is connected.

8. The pigtail assembly press of claim 1, further comprising a first vibratory tray, a linear feeder, a second vibratory tray and a feed conduit disposed at one side of the feeding mechanism;

the first vibration tray is used for placing the SUS metal piece;

the linear feeder is connected with the first vibration tray, so that the SUS metal piece can enter the linear feeder;

the second vibration material tray and the first vibration material tray are arranged at intervals, the second vibration material tray is used for placing the inserting core, and the feeding pipeline is connected with the second vibration material tray, so that the inserting core can enter the feeding pipeline.

9. The pigtail assembly press of claim 8, further comprising a distribution plate disposed between the linear feeder and the transport mechanism;

the material separating plate is movably arranged in the direction vertical to the linear feeder, and a limiting groove used for accommodating one SUS metal piece is formed in one side, facing the output end of the linear feeder, of the material separating plate; the limiting groove is provided with an opening, and the opening faces to the output end of the linear feeder.

10. The pigtail assembly press of claim 1, further comprising a discharge mechanism disposed at one side of the conveying mechanism, wherein the discharge mechanism comprises a first belt module, a sixth cylinder, a third suction head and a cup;

the first belt module is positioned above the conveying mechanism and arranged along the length direction;

the sixth air cylinder is vertically arranged on the first belt module;

the third suction head is arranged at one end, facing the conveying mechanism, of the sixth cylinder;

the material cup is arranged below the third suction head.

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