CN117566403B

CN117566403B - Automatic row of multi-functional core tube towards equipment

Info

Publication number: CN117566403B
Application number: CN202311288807.5A
Authority: CN
Inventors: 王一东; 杨铁军; 王凯
Original assignee: Chuzhou Aiwofu Photoelectric Technology Co ltd
Current assignee: Chuzhou Aiwofu Photoelectric Technology Co ltd
Priority date: 2023-10-08
Filing date: 2023-10-08
Publication date: 2024-06-11
Anticipated expiration: 2043-10-08
Also published as: CN117566403A

Abstract

The invention discloses a multifunctional automatic core inserting pipe arranging device, which comprises a first bearing member and a discharging hopper, wherein the first bearing member comprises two bearing plates which are oppositely arranged, the two bearing plates are obliquely arranged, and conveying belts are respectively arranged on the two bearing plates; a bearing channel is formed between the two bearing plates; the two conveying belts are arranged at two sides of the bearing channel; the downstream of the bearing plate is also provided with a driving reversing assembly which is used for reversing the core insert and conveying the core insert into the discharge pipe; the upstream scattered core inserting pieces are sequentially carried on the first carrying channel and continuously conveyed to the driving reversing assembly through the conveying belt. The multifunctional automatic core inserting pipe arranging equipment provided by the invention can realize automatic sequencing of scattered core inserting pieces, and can be used for conveying the scattered core inserting pieces into the arranging pipes one by one without independently penetrating fine iron wires one by one, so that the fine iron wires can directly penetrate through the core inserting pieces which are already arranged in the arranging pipes, and the arranging and series connection efficiency of the fine iron wires is greatly improved.

Description

Automatic row of multi-functional core tube towards equipment

Technical Field

The invention relates to the technical field of automatic arrangement of inserting cores, in particular to multifunctional automatic arrangement equipment of inserting core tubes.

Background

The well-known core insertion tube, also called ceramic pin body, is widely used in the fields of light and optical fiber communication, the core insertion tube is also a round insulating ceramic cylinder in precise centering in an optical fiber connector plug, the center is provided with a micropore which is used for fixing an optical fiber, the ceramic element is a high-precision special ceramic element which is formed by processing nano zirconia material through a series of formulas, the aperture and true roundness error is 0.5 degree, the connection, the conversion and the scheduling of an optical channel are more flexible,

In the prior art, when the general winding insertion core pipe is discharged, the discharge direction is scattered, and the insertion core is small in size, so that the subsequent series connection of the insertion core pipe through the group of the fine iron wires can be directly influenced, and the defect is overcome.

Disclosure of Invention

The invention aims to provide a multifunctional automatic core inserting pipe arranging device which solves the defects in the prior art.

In order to achieve the above object, the present invention provides the following technical solutions:

The multifunctional automatic core inserting pipe arranging equipment comprises a first bearing member and a discharging hopper arranged at the upstream of the first bearing member, wherein the first bearing member comprises two bearing plates which are oppositely arranged, the two bearing plates are obliquely arranged, and conveying belts are respectively arranged on the two bearing plates; a bearing channel is formed between the two bearing plates; the two conveying belts are arranged on two sides of the bearing channel;

the downstream of the bearing plate is also provided with a driving reversing assembly which is used for reversing the core insert and conveying the core insert into the discharge pipe;

The upstream scattered core inserting pieces are sequentially carried on the first carrying channel and continuously conveyed to the driving reversing assembly through the conveying belt.

In a further preferable scheme of the embodiment of the invention, the two bearing channels are arranged in a V shape, the width dimension of the bearing channel is smaller than the diameter of the connecting part, and the width dimension of the bearing channel is larger than the diameter of the insulating ceramic cylinder.

In a further preferable scheme of the embodiment of the invention, the bearing plates are obliquely arranged towards the downstream direction, and a cross bar is arranged between the two bearing plates.

In a further preferable scheme of the embodiment of the invention, one end of the bearing plate is provided with a baffle component for baffle core inserting pieces, and the driving reversing component is provided with a plurality of bearing mechanisms; when the driving reversing assembly is conveyed, the blocking assembly is driven to release the blocking, so that the insert pin is conveyed into the bearing mechanism.

In a further preferable scheme of the embodiment of the invention, one end of the bearing plate is fixedly provided with a fixed bearing plate, the baffle component is arranged on one of the fixed bearing plates, the baffle component comprises a hinge rod rotatably arranged on the fixed bearing plate, one end of the hinge rod is movably provided with a baffle block, the other end of the hinge rod is fixedly provided with a bearing block, the hinge shaft of the hinge rod is provided with a torsion spring, and the elastic force can enable the bearing block to be attached to the core insert at the outlet position of the fixed bearing plate.

In a further preferable scheme of the embodiment of the invention, a limiting rod is slidably arranged on one of the fixed bearing plates, an extrusion inclined plane is arranged at one end of the limiting rod, a baffle post is fixedly arranged below the baffle block, and after the limiting rod is pressed, the limiting rod contracts inwards to enable the extrusion inclined plane to extrude the baffle post, so that the baffle block is inserted between adjacent core inserting pieces.

In a further preferable scheme of the embodiment of the invention, the driving reversing assembly comprises a driving disc rotatably arranged on the fixed base, the bearing mechanisms are arranged on the driving disc, the driving disc is provided with abutting assemblies corresponding to the bearing mechanisms one by one, and the abutting assemblies drive the extrusion limiting rods in the rotating process of the driving disc.

In a further preferred embodiment of the present invention, the bearing mechanism includes a bearing block rotatably disposed on the driving disc, and the bearing block has a receiving position and a placing position on a rotation stroke, where the bearing block is located at a notch position of the bearing channel, and the placing position is located at a feed port position of the discharge pipe after the bearing block rotates a certain angle.

In a further preferable scheme of the embodiment of the invention, the bearing block is rotatably arranged on the driving disc through the fixed column, the outer part of the rotating column is sleeved with the sliding sleeve, the rotating column is provided with the limit guide column, and the limit guide column is positioned in the spiral groove formed in the sliding sleeve.

In a further preferable scheme of the embodiment of the invention, the abutting assembly comprises a squeezing block which is arranged in a sliding manner along the radial direction of the driving disc, one end of the squeezing block is connected with a second elastic piece, a fixed baffle is fixedly arranged on the fixed base, and the conveying belt fixed baffle is arranged beside the row-direction pipe.

In the technical scheme, the multifunctional automatic core inserting pipe arranging device has the beneficial effects that:

According to the invention, through the mutual matching of the bearing plates and the driving reversing assemblies, after the core inserting pieces scattered by the discharging hopper fall into the bearing channel, the core inserting pieces can be automatically and sequentially discharged into the bearing channel, the core inserting pieces gradually move to the position of the driving reversing assembly after being detected under the conveying of the conveying belt, and then the core inserting pieces are horizontally placed on the discharge pipe through the driving reversing assemblies, namely, the automatic sorting of the scattered core inserting pieces can be realized, the scattered core inserting pieces are conveyed into the discharge pipe one by one, the thin iron wires do not need to be independently and one by one, the thin iron wires are directly penetrated on the core inserting pieces already arranged in the discharge pipe, the efficiency of the serial connection of the group of the thin iron wires is greatly improved, and the subsequent processing efficiency is improved.

It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are not restrictive of the disclosure.

This document provides an overview of various implementations or examples of the technology described in this disclosure, and is not a comprehensive disclosure of the full scope or all of the features of the technology disclosed.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings required for the embodiments will be briefly described below, and it is apparent that the drawings in the following description are only some embodiments described in the present application, and other drawings may be obtained according to these drawings for a person having ordinary skill in the art.

FIG. 1 is a schematic view of the overall structure provided by an embodiment of the present invention;

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

FIG. 3 is an enlarged schematic view of the structure at A according to an embodiment of the present invention;

Fig. 4 is a schematic structural diagram of a carrier plate according to an embodiment of the present invention;

FIG. 5 is a schematic diagram of a driving disc according to an embodiment of the present invention;

FIG. 6 is a schematic view of a spacer assembly according to an embodiment of the present invention;

fig. 7 is a schematic structural diagram of a bearing block according to an embodiment of the present invention;

FIG. 8 is a schematic cross-sectional view of a driving disc and a carrier block according to an embodiment of the present invention;

fig. 9 is a schematic cross-sectional structure of a carrying mechanism according to an embodiment of the present invention;

FIG. 10 is a schematic view of a position structure of a spacer assembly and a ferrule according to an embodiment of the present invention

Fig. 11 is a schematic structural diagram according to an embodiment of the present invention.

Reference numerals illustrate:

1. a carrying plate; 2. discharging a hopper; 11. a cross bar; 101. a carrying channel; 12. a conveyor belt; 3. a fixed base; 31. a discharge pipe; 32. a fixed baffle; 4. a drive plate; 5. a bearing block; 51. a carrying groove; 501. a through groove; 52. an elastic sheet; 521. a connecting rod; 5211. an extrusion rod; 532. limiting guide posts; 53. fixing the column; 531. a sliding sleeve; 5311. a spiral groove; 5312. a first elastic member; 6. a spacer assembly; 61. a limit rod; 7. a ferrule; 71. a connection part; 72. an insulating porcelain column; 62. a hinge rod; 621. a support block; 63. a baffle block; 631. a baffle column; 611. extruding the inclined plane; 8. extruding a block; 81. a second elastic member; 9. fixing the bearing plate; 5212. and a bump.

Detailed Description

In order to make the objects, technical solutions and advantages of the embodiments of the present disclosure more apparent, the technical solutions of the embodiments of the present disclosure will be clearly and completely described below with reference to the accompanying drawings of the embodiments of the present disclosure. It will be apparent that the described embodiments are some, but not all, of the embodiments of the present disclosure. All other embodiments, which can be made by one of ordinary skill in the art without the need for inventive faculty, are within the scope of the present disclosure, based on the described embodiments of the present disclosure.

Referring to fig. 1-11, a multifunctional automatic core inserting pipe arranging device comprises a first bearing member and a discharge hopper 2 arranged at the upstream of the first bearing member, wherein the first bearing member comprises two bearing plates 1 which are oppositely arranged, the two bearing plates 1 are obliquely arranged, and conveying belts 12 are respectively arranged on the two bearing plates 1; a bearing channel 101 is formed between the two bearing plates 1; two conveyor belts 12 are arranged on both sides of the carrying channel 101;

a driving reversing assembly is further arranged at the downstream of the bearing plate 1 and is used for reversing and conveying the core inserting pieces 7 into the discharge pipe 31;

The upstream loose ferrules 7 are successively carried on the first carrying channel 101 and continuously transported to the drive reversing assembly by the conveyor belt 12.

Specifically, as shown in fig. 3, the length of the insulating ceramic cylinder is greater than the length of the upper conductor of the ferrule, and the gravity is relatively heavy, that is, after passing through the bearing channel 101, the main body moves downward through the bearing channel 101 under the self-construction and the gravity;

According to the invention, through the mutual matching of the bearing plate 1 and the driving reversing assembly, after the scattered core inserting pieces of the hopper 2 fall into the bearing channel 101, the core inserting pieces can be automatically and sequentially discharged into the bearing channel 101, the core inserting pieces gradually move to the position of the driving reversing assembly after being detected under the conveying of the conveying belt 12, and then the core inserting pieces are horizontally placed on the discharge pipe 31 through the driving reversing assembly, namely, the scattered core inserting pieces can be automatically ordered and are conveyed into the discharge pipe 31 one by one, the thin iron wires do not need to be independently and one by one to pass through the core inserting pieces which are already arranged in the discharge pipe 31, the series connection efficiency of the group row of the thin iron wires is greatly improved, and the subsequent processing efficiency is improved.

In a further embodiment of the present invention, the two bearing channels 101 are disposed in a V-shape, the width dimension of the bearing channel 101 is smaller than the diameter of the connecting portion 71, and the width dimension of the bearing channel 101 is larger than the diameter of the insulating ceramic cylinder 72. By making the width dimension of the carrying channel 101 smaller than the diameter of the connecting portion 71, the width dimension is larger than the diameter of the insulating ceramic cylinder 72, so that the scattered ferrule 7 automatically falls into the carrying channel 101 when passing through the carrying channel 101, and the connecting portion is located above the carrying channel 101, that is, the produced ferrule 7 can be automatically arranged on the carrying channel 101.

In a further embodiment of the invention, the carrier plates 1 are arranged obliquely in the downstream direction, and a cross bar 11 is arranged between the two carrier plates 1.

Further, one end of the bearing plate 1 is provided with a baffle component 6 for baffle core inserting pieces 7, and the driving reversing component is provided with a plurality of bearing mechanisms; when the reversing assembly is driven to convey, the baffle assembly 6 is driven to release the baffle, so that the insert 7 is conveyed into the bearing mechanism.

Further, the fixed carrier plate 9 that is provided with of one end of the carrier plate 1 is fixed, separates shelves subassembly 6 and sets up on one of them fixed carrier plate 9, and separates shelves subassembly 6 including rotating the articulated pole 62 that sets up on fixed carrier plate 9, and the one end activity of articulated pole 62 is provided with separates the retaining piece 63, and the other end is fixed to be provided with the support piece 621, and is provided with torque spring on the articulated shaft of articulated pole 62, and elasticity can make the laminating of support piece 621 be in on the lock pin piece 7 of fixed carrier plate 9 exit position department.

In a further embodiment of the present invention, a limiting rod 61 is slidably disposed on one of the fixing support plates 9, an extrusion inclined surface 611 is disposed at one end of the limiting rod 61, and a blocking post 631 is fixedly disposed under the blocking block 63, and after the limiting rod 61 is pressed, the limiting rod is contracted inwards, so that the extrusion inclined surface 611 extrudes the blocking post 631, and the blocking block 63 is inserted between the adjacent core inserts 7.

Specifically, the invention can separate the core inserting pieces 7 at the outlet position of the fixed carrier plate 9 through the separation assembly 6, then when the reversing assembly is driven to move, the limiting rod 61 can be extruded, then the limiting rod 61 is enabled to be extruded, the blocking column 631 can be driven to move towards the position between the two core inserting pieces 7 by the extrusion blocking column 631, meanwhile, the bearing block 621 at the other end can be driven to be separated from the core inserting pieces 7, namely, the core inserting pieces 7 at the separation can be released, and the previous core inserting pieces can be separated through the separation of the separation block 63, so that the core inserting pieces can be stably and orderly released into the bearing mechanism one by one, and the conveying efficiency and the conveying stability are greatly improved.

In a further embodiment of the present invention, the driving reversing assembly includes a driving disc 4 rotatably disposed on the fixed base 3, and the bearing mechanism is disposed on the driving disc 4, and the driving disc 4 is provided with a tightening assembly corresponding to the bearing mechanism one by one, and the tightening assembly drives the extrusion limiting rod 61 during the rotation process of the driving disc 4.

In a further embodiment of the present invention, the bearing mechanism includes a bearing block 5 rotatably disposed on the driving disc 4, and the bearing block 5 has a receiving position and a placing position on the rotation stroke, where the bearing block 5 is located at a notch position of the bearing channel 101, and the placing position is located at a feed port position of the discharge tube 31 after the bearing block 5 rotates a certain angle. Specifically, the invention can realize bearing the conveyed core inserting piece through the bearing mechanism, then gradually enable the bearing block 5 in the horizontal state to move to the vertical state under the drive of the driving disk 4, namely, the core inserting piece can be driven to move from the vertical direction to the horizontal direction, namely, the reversing and the discharging of the core inserting piece can be facilitated, and the whole process can be switched to the position passively through fight in different parts of the driving disk 4, so that the functionality of the device is greatly improved.

In a further embodiment of the present invention, the bearing block 5 is rotatably disposed on the driving disc 4 through the fixed column 53, the outer portion of the rotating column is sleeved with the sliding sleeve 531, the rotating column is provided with the limit guide column 532, and the limit guide column 532 is disposed in the spiral groove 5311 formed in the sliding sleeve 531.

In a further embodiment of the present invention, the abutting assembly includes a pressing block 8 slidably disposed along a radial direction of the driving disc 4, one end of the pressing block 8 is connected with a second elastic member 81, a fixed baffle 32 is fixedly disposed on the fixed base 3, and the fixed baffle 32 of the conveying belt 12 is disposed beside the discharge tube 31.

Still including setting up the barrier on the carrier block 5, and the barrier includes setting up the elastic sheet 52 that sets up on the carrier block 5, can carry out spacingly through the setting of elastic sheet 52 to insulating porcelain cylinder, make the lock pin 7 that moves to the carrier groove 51 in by spacingly, namely, in the in-process that carrier position and place position switch over, can not drop, guarantee the stability of its device, and the elastic sheet 52 sets up in the logical inslot 501 that carrier block 5 offered, and the inboard of elastic sheet 52 is connected with the connecting rod 521, and the one end of connecting rod 521 inserts to the fixed column 53 in, and the fixed column 53 sliding is provided with the squeeze rod 5211, and be provided with the inclined plane on the squeeze rod 5211, and this inclined plane extrudees in the inslot of seting of connecting rod 521, the other end protrusion to the fixed column 53, when carrier block 5 is in place position, the squeeze rod 5211 pressurized inward movement, and can be through this inclined plane extrusion connecting rod 521 to the direction motion of sliding sleeve 531, namely, can pull the elastic sheet 52 shrink, can not separate, be in the separation, be convenient for lock pin 7 drops to the row 31 inwards.

When the device is operated, firstly, the produced device core inserting pieces drop onto the discharging hopper 2, then slide onto the bearing plate 1 through the discharging hopper 2, then the insulating ceramic columns of the core inserting pieces penetrate through the bearing channel 101, the connecting part 71 is positioned on the conveying belt 12 on the bearing channel 101, then the device core inserting pieces are continuously conveyed, in the continuous conveying process, the core inserting pieces sequentially move to the position of the fixed bearing plate 9, then the baffle assembly 6 is used for baffle separation, then the driving disc 4 starts to rotate, the extrusion block 8 arranged beside the bearing block 5 gradually extrudes the limit rod 61, the elastic force of the second elastic piece 81 is larger than the elastic force of the torque spring arranged on the rotating shaft of the hinging rod 62, namely, the extrusion block 8 at the moment cannot deform, then under the extrusion of the limit rod 61, the extrusion inclined plane 611 is abutted against the baffle post 631, then the baffle post 631 gradually drives the baffle block 63 to gradually move towards the direction of the core inserting piece 7, and at the same time, the bearing block 621 at the other end can be driven to be separated from the core inserting piece 7, namely, the baffle block 7 can be released from the baffle block 7 can be gradually moved into the fixed bearing disc 4, and then the baffle block 8 can be gradually moved into the fixed disc 32, and the baffle plate 4 can be gradually moved before the baffle block 63 is gradually moved. At this time, as shown in fig. 8, in the process of moving inward of the extrusion block 8, the sliding sleeve 531 is gradually extruded, so that the sliding sleeve 531 moves gradually towards the direction of the fixed column 53, because the sliding sleeve 531 can only slide, and cannot rotate, and the limit guide column 532 is located in the spiral groove 5311 formed in the sliding sleeve 531, that is, when the sliding sleeve 531 moves, the fixed column 53 can be driven to rotate, and then the connected bearing block 5 is driven to rotate, and then the bearing block 5 can be gradually moved to the position of the discharge tube 31, and at this time, the bearing block 5 is in the placement position, the notch of the bearing groove 51 faces downward, as shown in fig. 3, at the position beside the discharge tube 31, and in the conversion process, the protruding end of the extrusion rod 5211 gradually moves to the position of the bump 5212, then under the action of the bump 5212, the extrusion rod 5211 is pressed inward, and can extrude the connecting rod 521 through the inclined plane, so that the connecting rod 521 moves towards the direction of the sliding sleeve 531, that can pull the elastic piece 52 to shrink, that is not separate the core plug 7 from the plug 7 and continuously move to the plug-in the tube 31, and then the plug-in tube 31 is continuously arranged in the plug-in unit 31.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that modifications may be made to the described embodiments in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are to be regarded as illustrative in nature and not as restrictive of the scope of the invention, which is defined by the appended claims.

Claims

1. The multifunctional automatic core inserting pipe arranging equipment is characterized by comprising a first bearing member and a discharging hopper (2) arranged at the upstream of the first bearing member, wherein the first bearing member comprises two bearing plates (1) which are oppositely arranged, the two bearing plates (1) are obliquely arranged, and conveying belts (12) are respectively arranged on the two bearing plates (1); a bearing channel (101) is formed between the two bearing plates (1); the two conveying belts (12) are arranged at two sides of the bearing channel (101);

The downstream of the bearing plate (1) is also provided with a driving reversing assembly which is used for reversing the core inserting piece (7) and conveying the core inserting piece into the discharge pipe (31);

The upstream scattered core inserting pieces (7) are sequentially carried on the carrying channel (101) and continuously conveyed to the driving reversing assembly through the conveying belt (12); the driving reversing assembly is provided with a plurality of bearing mechanisms;

The driving reversing assembly comprises a driving disc (4) rotatably arranged on the fixed base (3), and the bearing mechanism is arranged on the driving disc (4);

The bearing mechanism comprises a bearing block (5) rotatably arranged on the driving disc (4), and the bearing block (5) is respectively provided with a bearing position and a placing position on the rotating stroke, wherein the bearing block (5) is positioned at the notch position of the bearing channel (101) in the bearing position, and the bearing block (5) is rotated for a certain angle and positioned at the feed inlet position of the discharge pipe (31) in the placing position;

The bearing block (5) is rotatably arranged on the driving disc (4) through a fixed column (53), a sliding sleeve (531) is sleeved outside the rotating column, a limit guide column (532) is arranged on the rotating column, and the limit guide column (532) is positioned in a spiral groove (5311) formed in the sliding sleeve (531);

The driving disc (4) is provided with abutting assemblies which are in one-to-one correspondence with the bearing mechanisms, and the abutting assemblies drive the extrusion limiting rods (61) in the rotation process of the driving disc (4);

The abutting assembly comprises an extrusion block (8) which is arranged in a sliding manner along the radial direction of the driving disc (4), one end of the extrusion block (8) is connected with a second elastic piece (81), a fixed baffle (32) is fixedly arranged on the fixed base (3), and the fixed baffle (32) is arranged beside the discharge pipe (31); in the process of moving the driving disc (4), the extrusion block (8) gradually extrudes the fixed baffle plate (32), and then the extrusion block (8) can gradually move inwards under the limit of the fixed baffle plate (32); during the inward movement of the extrusion block (8), the sliding sleeve (531) is gradually extruded, so that the sliding sleeve (531) gradually moves towards the fixed column (53).

2. The automatic arranging device of the multifunctional plug core pipe according to claim 1, wherein the two bearing channels (101) are arranged in a V shape, the width dimension of the bearing channel (101) is smaller than the diameter of the connecting part (71), and the width dimension of the bearing channel (101) is larger than the diameter of the insulating ceramic cylinder (72).

3. The automatic arranging equipment of the multifunctional plug core tube according to claim 1, wherein the bearing plates (1) are obliquely arranged towards the downstream direction, and a cross bar (11) is arranged between the two bearing plates (1).

4. The automatic arranging equipment of the multifunctional insertion core pipe according to claim 1, wherein one end of the bearing plate (1) is provided with a baffle assembly (6) for baffle insertion core pieces (7); when the driving reversing assembly is conveyed, the blocking assembly (6) is driven to release the blocking, so that the core inserting piece (7) is conveyed into the bearing mechanism.

5. The automatic arranging equipment of the multifunctional insertion core pipe according to claim 4, wherein a fixed bearing plate (9) is fixedly arranged at one end of the bearing plate (1), the baffle component (6) is arranged on one of the fixed bearing plates (9), the baffle component (6) comprises a hinge rod (62) rotatably arranged on the fixed bearing plate (9), a baffle block (63) is movably arranged at one end of the hinge rod (62), a bearing block (621) is fixedly arranged at the other end of the hinge rod, a torque spring is arranged on a hinge shaft of the hinge rod (62), and the elastic force can enable the bearing block (621) to be attached to an insertion core piece (7) at an outlet position of the fixed bearing plate (9).

6. The automatic arranging equipment of the multifunctional plug core pipe according to claim 5, wherein a limit rod (61) is slidably arranged on one fixed bearing plate (9), an extrusion inclined plane (611) is arranged at one end of the limit rod (61), a baffle column is fixedly arranged below the baffle block (63), after the limit rod (61) is pressed, the limit rod is contracted inwards, and the extrusion inclined plane (611) extrudes the baffle column, so that the baffle block (63) is inserted between adjacent plug core pieces (7).