CN114454399A

CN114454399A - Forming device for computer network connector

Info

Publication number: CN114454399A
Application number: CN202111579108.7A
Authority: CN
Inventors: 丁才昌; 孙勇; 张国军; 刘志远; 刘天印; 韩文奇; 吕盼; 罗港; 周雅; 付蒙蒙
Original assignee: Pla 75310; Hubei Polytechnic University
Current assignee: Pla 75310; Hubei Polytechnic University
Priority date: 2021-12-22
Filing date: 2021-12-22
Publication date: 2022-05-10
Anticipated expiration: 2041-12-22
Also published as: CN114454399B

Abstract

The invention discloses a forming device for computer network joint, comprising: the device comprises a clip ring frame, clip conveying strips and clip conveying surface belts, wherein the clip ring frame, the clip conveying strips and the clip conveying surface belts are sequentially stacked and correspondingly arranged from top to bottom, fixing seats are respectively arranged on the left side and the right side of the clip ring frame, glue injection devices and clamping devices which are independent and arranged in a circumferential arrangement mode are respectively arranged on the fixing seats on the left side and the right side, and a cold-temperature device which covers a local clip ring frame surface area is fixedly arranged close to the left side of the clamping devices; the collecting boxes are arranged on the clip-shaped conveying surface belt at equal intervals; and the forming device is arranged corresponding to the collecting box, is arranged in the middle of the collecting box, and is provided with an upper end arranged on the square-shaped conveying strip.

Description

Forming device for computer network connector

Technical Field

The invention relates to the technical field of network connector forming, in particular to a forming device for a computer network connector.

Background

The optical fiber interface is a physical interface for connecting an optical fiber cable, the external reinforcement mode is to fasten by using a metal sleeve, and the connector at the network joint end is generally molded by a mode of injecting glue and shaping by a mold. Wherein, it is longer to the tail end of type number structures such as SC, ST, because of improving its bending degree and elasticity, its afterbody structure is parallel layer arc hole dislocation and sets up, consequently, current computer network connects uses forming device, because of the design of arc hole dislocation groove and the factor of colloid self viscosity, lead to carrying out the injecting glue in-process to the sealed mould of clamp, the inside gas in mould groove cavity is difficult to be driven totally by the colloid, it is lower to lead to the colloid to be full of the rate of filling in arc dislocation groove, and then arouse the shaping incomplete, the angle that leaks appears, it is thinner to link between the adjacent cell body, even fracture.

Accordingly, one skilled in the art provides a molding apparatus for computer network connectors to solve the above problems in the background art.

Disclosure of Invention

In order to achieve the purpose, the invention provides the following technical scheme: a molding device for computer network connectors, comprising: the device comprises a clip ring frame, clip conveying strips and clip conveying surface belts, wherein the clip ring frame, the clip conveying strips and the clip conveying surface belts are sequentially stacked and correspondingly arranged from top to bottom, fixing seats are respectively arranged on the left side and the right side of the clip ring frame, glue injection devices and clamping devices which are independent and arranged in a circumferential arrangement mode are respectively arranged on the fixing seats on the left side and the right side, and a cold-temperature device which covers a local clip ring frame surface area is fixedly arranged close to the left side of the clamping devices;

the collecting boxes are arranged on the clip-shaped conveying surface belt at equal intervals;

and the forming device is arranged corresponding to the collecting box, is arranged in the middle of the corresponding collecting box, and is arranged on the corresponding clip-shaped conveying strip at the upper end of the forming device.

As a preferable aspect of the present invention, the molding apparatus includes:

the motor I is fixed in the middle of the collecting box, a rotating shaft is fixed at the output end of the motor I, and the top end of the rotating shaft is embedded into the corresponding clip-shaped conveying strip through a bearing seat;

the single ear seats are arranged in multiple groups, are horizontally and circumferentially arranged and are symmetrically fixed on the outer ring walls close to the upper end and the lower end of the rotating shaft in an up-down mode, and the single ear seats below the rotating shaft are hinged with corresponding shaking rods;

the Z-shaped frames are configured into a plurality of groups, the right side ends of the Z-shaped frames are correspondingly hinged to the single lug seats above and the output ends of the shaking rods below respectively, strip-shaped guide rail plates are arranged on the same side and the same longitudinal surface of the left side end of the Z-shaped frames in a matched mode, driving seats are correspondingly arranged on the outer side surfaces of the strip-shaped guide rail plates close to the upper end and the lower end of the strip-shaped guide rail plates respectively, fixed blocks are arranged on the driving seats respectively, and bearing sleeves are fixed on the fixed blocks above the driving seats;

the forming assembly is arranged in parallel with the strip-shaped guide rail plate, the lower end of the forming assembly is fixed with the fixing block, and the upper end of the forming assembly coaxially slides to penetrate into the bearing sleeve and corresponds to the upper part of the bearing sleeve.

As a preferred technical solution of the present invention, an inclination angle between the rotation of the shake-rocking-bar adjustable forming assembly around the single ear base above and the longitudinal plane is 0 ° to 30 °.

As a preferred aspect of the present invention, the molding assembly includes:

the motor II is arranged on the corresponding fixed block through a concave shell frame, a double-lug seat is coaxially fixed at the output end of the motor II, and a magnet I is arranged in the middle of the double-lug seat;

the die shell is of a left half shell clamping cover and right half shell clamping cover splicing structure, the lower ends of the left half shell clamping cover and the right half shell clamping cover are respectively hinged to the two lug seats on the corresponding side, and an arc-shaped hole cavity which takes the left hinged end of the two lug seats as the circle center is formed in the shell wall of the left half shell clamping cover close to the top end;

the bottom end of the die inner shell is fixed with a magnet II which is attracted with the magnet I, and the upper end of the die inner shell is provided with a sealing pressurizing assembly;

the lower ends of the first telescopic rod and the second telescopic rod are correspondingly hinged to the middle of the corresponding double-lug seat in a front-back mode respectively, the upper ends of the first telescopic rod and the second telescopic rod are correspondingly hinged to connecting shafts respectively, the connecting shafts are correspondingly mounted on the corresponding outer side walls of the left plate shell cover and the right plate shell cover respectively, and the bottom ends of the second telescopic rod are of fixed hinged structures.

As a preferable technical solution of the present invention, the driving force of the second motor is slightly smaller than the driving force of the first motor.

As a preferred aspect of the present invention, the seal pressurization assembly includes:

the air vent column is coaxially fixed at the top end of the inner shell of the corresponding die, a cylindrical shell cover is fixed at the upper end of the air vent column, and a pressure monitoring ball is embedded in the air vent column;

the rough rod penetrates and is fixed at the bottom of the cylindrical shell cover, the right end of the rough rod is contacted and attached with the inner shell of the die, and the left end of the rough rod is provided with an arc rod which is embedded into the corresponding arc hole cavity and is in sliding friction connection;

the sealing air bag is hermetically connected with the outer side of the corresponding vent hole column;

the air pump is arranged in the cylindrical shell cover and is communicated with the upper end of the corresponding air vent column;

and the air guide pipe penetrates through the outer side end of the arc-shaped rod and is led into the cylindrical shell cover, and is communicated with the external air and the inner cavity of the cylindrical shell cover.

As a preferable technical solution of the present invention, the gripping device includes:

the guide clamp sliding frames are arranged in a left-right symmetrical mode;

the double-rack sliding plate is embedded into the guide clamp sliding frame and is in sliding connection, the left side and the right side of the double-rack sliding plate are respectively provided with corresponding driving gears and are in meshing connection, and the bottom end of the double-rack sliding plate is hinged with four groups of clamping rods which are arranged in a circumferential manner;

the lifting rod is arranged at the lower end of the double-rack sliding plate, and the output end of the lifting rod is provided with a quadrilateral shaft seat;

the connecting rods are arranged into four groups, and the upper ends and the lower ends of the connecting rods are correspondingly hinged on the corresponding four-standard shaft seats and the clamping rods respectively.

Compared with the prior art, the invention provides a forming device for a computer network connector, which has the following beneficial effects:

1. according to the invention, the processes of glue injection, filling, cooling, clamping and collection are sequentially and circularly performed in a circular circulating structure mode, so that the preparation and the forming of the network joint sleeve are completed, and the advantages of small occupied space, high flexibility, high preparation efficiency and the like are realized.

2. In the invention, the colloid in the molding assembly in a centrifugal state has a tendency of sinking again due to self gravity factors, and further, particularly, in each rotating and swinging process, the colloid is not tightly attached to the inner wall of the mold due to the surface tension factor of the colloid, so that a bubble cavity which is partially covered in the edges, the surfaces, the corner ends and other areas of the mold is generated, the impact strength is enhanced, the bubble escape rate is enhanced, the relative density of the colloid is improved, and the relative filling rate is improved.

Drawings

FIG. 1 is a schematic structural view of a feeding device of the present invention;

FIG. 2 is an enlarged schematic view of a right-view partial structure of the lifting device of the present invention;

FIG. 3 is an enlarged schematic view of a right-view partial structure of the feeding device of the present invention;

FIG. 4 is an enlarged view of a portion of the positioning assembly of the present invention;

in the figure: 1. a clip-shaped ring frame; 2. a glue injection device; 3. a gripping device; 4. a cold-warm device; 5. a loop-shaped conveyor belt; 6. a collection box; 7. a molding device; 8. a loop conveyor belt; 9. a molding assembly; 31. a guide clip carriage; 32. a double rack slide; 33. a drive gear; 34. lifting a pull rod; 35. a quadrilateral axle seat; 36. a connecting rod; 37. a clamping bar; 71. a first motor; 72. a rotating shaft; 73. a bearing seat; 74. a single-lug seat; 75. shaking the pole; 76. a Z-shaped frame; 77. a strip-shaped guide rail plate; 78. a driving seat; 79. a fixed block; 710. a bearing housing; 91. a second motor; 92. a binaural seat; 93. a first magnet; 94. a mold housing; 95. an inner shell of the mold; 96. a second magnet; 97. a first telescopic rod; 98. a second telescopic rod; 99. a sealed pressurizing assembly; 991. a gas-permeable hole column; 992. a pressure monitoring ball; 993. a cylindrical housing; 994. a rough bar; 995. an air pump; 996. an air duct; 997. the air bag is sealed.

Detailed Description

Referring to fig. 1-4, the present invention provides a technical solution: a molding apparatus for computer network connectors, comprising: the device comprises a clip ring frame 1, clip conveying strips 8 and clip conveying surface belts 5 which are correspondingly arranged from top to bottom in sequence, wherein fixing seats are respectively arranged on the left side and the right side of the clip ring frame 1, glue injection devices 2 and clamping devices 3 which are independent and arranged in a circumferential arrangement are respectively arranged on the fixing seats on the left side and the right side, and a cold-hot device 4 which covers a local surface area of the clip ring frame 1 is fixedly arranged near the left side of the clamping devices 3;

the collecting boxes 6 are arranged on the clip-shaped conveying surface belt 5 at equal intervals;

the forming device 7 is arranged corresponding to the collecting box 5, is arranged in the middle of the corresponding collecting box 5, and is arranged at the upper end of the forming device on the corresponding clip-shaped conveying strip 8;

this structural design, firstly, with the closed circle of shape cyclic structure mode of head and tail, carry out and circulate the injecting glue in proper order, fill, the cooling, press from both sides and get, collect the process, accomplish the preparation shaping of network joint cover, realize taking up space little, the flexibility is high, advantages such as preparation efficiency height, secondly, utilize circulation transmission time difference, adopt the process of filling, with centrifugal stirring, shake even mould internal colloid, and the sealed booster-type mode of exerting pressure of cooperation, break the mould internal edge and remain static bubble chamber, impel the bubble to escape to the colloid top and gather, improve the mould internal colloid filling rate, and then improve the fashioned quality of network joint cover.

In this embodiment, the molding device 7 includes:

the first motor 71 is fixed in the middle of the collecting box 6, the output end of the first motor is fixed with a rotating shaft 72, and the top end of the rotating shaft 72 is embedded into the corresponding clip-shaped conveying strip 8 through a bearing seat 73;

the single-lug seats 74 are arranged in multiple groups, are horizontally and circumferentially arranged, are symmetrically fixed on the outer ring wall close to the upper end and the lower end of the rotating shaft 72 in an up-down mode, and are hinged with corresponding shaking rods 75 on the single-lug seats 74 below;

the Z-shaped frames 76 are configured into a plurality of groups, the right side ends of the Z-shaped frames are correspondingly hinged to the output ends of the single lug seats 74 above and the shaking rods 75 below respectively, the left side ends of the Z-shaped frames 76 on the same side and the same longitudinal surface are matched and provided with strip-shaped guide rail plates 77, the outer side surfaces of the strip-shaped guide rail plates 77 close to the upper end and the lower end are respectively and correspondingly provided with driving seats 78, the driving seats 78 are respectively provided with fixed blocks 79, and bearing sleeves 710 are fixed on the fixed blocks 79 above;

the forming assembly 9 is arranged in parallel with the strip-shaped guide rail plate 77, the lower end of the forming assembly is fixed with the fixed block 79 below, and the upper end of the forming assembly coaxially penetrates into the bearing sleeve 710 corresponding to the upper part in a sliding manner;

according to the structural design, for the integral structure of the molding assembly after glue injection, firstly, a motor I is regulated and controlled by an adjustable constant acceleration a value to carry out rotary centrifugation, and secondly, a shaking rod is regulated and controlled by an adjustable reciprocating expansion frequency b value and an adjustable expansion amount c value to enable the molding assembly to make an inner and outer reciprocating type rotary swing structure around an upper single lug seat;

in this, it is separated by the interval that it can be adjusted and control along corresponding bar guide rail board to upper and lower drive seat, so that the shaping subassembly of the different length of adaptation, wherein, upper drive seat can drive the regulation and control bearing housing and reciprocate, break away from and the solid shaping subassembly of nested card, the clamp of the colloid after the shaping of being convenient for gets, collect, and the support clamp location among the centrifugation process, thereby guarantee the stability of shaping subassembly, avoid conventional vibration to shake even equipment, make the colloid at the top produce the microwave fluctuation ripple, reduce the stable shaping efficiency of colloid.

In this embodiment, the inclination angle between the rotation of the adjustable forming assembly 9 around the single ear seat above and the longitudinal plane is 0 to 30 °;

this design, mainly used, make the shaping subassembly be eight style of calligraphy structures and revolve the pendulum to make the colloid that is in the inside shaping subassembly of centrifugal state, again because of self gravity factor, have the trend of sinking, and then especially at every turn revolve the pendulum in-process, the department of edge, face, angle end etc. exists in the mould, because of colloid self surface tension factor, do not closely adhere with the mould inner wall, and produce the bubble chamber that local cover forms in areas such as mould edge, face, angle end, reinforcing impact strength.

In this embodiment, the forming assembly 9 includes:

the second motor 91 is arranged on the corresponding fixed block 79 through a concave shell frame, the output end of the second motor is coaxially fixed with a double-lug seat 92, and the middle part of the double-lug seat 92 is provided with a first magnet 93;

the die shell 94 is of a left-right half shell cover splicing structure, the lower ends of the die shell are respectively hinged to the two lug seats 92 on the corresponding side, and an arc-shaped hole cavity which takes the left hinged end of the two lug seats 92 as the center of a circle is formed in the shell wall of the left half shell cover close to the top end;

a second magnet 96 attracted with the first magnet 93 is fixed at the bottom end of the inner die shell 95, and a sealing pressurizing assembly 99 is installed at the upper end of the inner die shell;

the lower ends of the first telescopic rod 97 and the second telescopic rod 98 are respectively hinged to the middle parts of the corresponding double lug seats 92 in a front-back corresponding mode, the upper ends of the first telescopic rod 97 and the second telescopic rod 98 are respectively hinged with a connecting shaft in a corresponding mode, the connecting shafts are correspondingly arranged on the corresponding outer side walls of the left plate shell and the right plate shell correspondingly, and the bottom ends of the second telescopic rods 98 are of fixed hinged structures;

this structural design, mainly used, it is first for provide the colloid in mould shell, the mould inner shell, use its axle center as the axle and carry out the rotation, strengthen the centrifugal force that its rotation produced, impel the colloid to strike the impact filling intensity of the recess wall between mould shell and the mould inner shell comprehensively, the second, through sealed pressure boost subassembly with the structural mode of extrusion shrinkage cavity volume carry out the pressure boost, the escape efficiency on the further acceleration bubble, the third, the separation from of the colloid after the shaping of being convenient for.

In this embodiment, the driving force of the second motor 91 is smaller than that of the first motor 71;

this design, mainly used maintain the horizontal centrifugal force of colloid and be less than vertical ascending centrifugal force, and then guarantee that the colloid general state flow trend has the trend of sinking in real time, and then guarantee that the colloid preferentially sinks to improve the filling rate of the colloid from lower to upper between mould shell, the mould inner shell, and the relative density of colloid self, and then improve the shaping quality.

In this embodiment, the seal pressurization assembly 99 includes:

the ventilation hole column 991 is coaxially fixed at the top end of the corresponding die inner shell 95, a cylindrical shell cover 993 is fixed at the upper end of the ventilation hole column, and a pressure monitoring ball 992 is embedded in the ventilation hole column 991;

a rough rod 994 which penetrates and is fixed at the bottom of the cylindrical shell cover 993, the right end of the rough rod touches and attaches to the inner shell 95 of the die, and the left end of the rough rod is provided with an arc rod which is embedded into the corresponding arc hole cavity and is in sliding friction connection;

the sealed air bag 997 is hermetically connected with and covers the outer side of the corresponding vent hole column 991;

an air pump 995 installed inside the cylindrical housing 993 and communicated with the upper end of the corresponding air-permeable hole column 991;

the air guide pipe 996 penetrates through the outer end of the arc-shaped rod and is guided into the cylindrical shell cover 993, and communicates external air with the inner cavity of the cylindrical shell cover 993;

according to the structural design, the injection amount of the colloid needs to be lower than the setting height of the sealing pressurizing assembly, and in the inclined centrifugal process, the top liquid level of the colloid is not in contact with the sealing air bag, so that the phenomenon that the sealing air bag is adhered with the colloid to cause the amount of the colloid needed by molding is avoided, and further, the air pressure in the sealing air bag is the same as the air pressure in the external sealing cavity;

as a preferred embodiment, since the bubbles inside the gel are squeezed by the gel, and the volume of the bubbles is smaller than the volume of the non-squeezed state, after the high pressure gel is released, the pressure is released, so that the pressure monitoring ball detects the variation of the pressure value d after constant pressurization and feeds the variation back to the air pump in time, the initial constant pressurization value is maintained until the monitoring data of the pressure monitoring ball for a relatively long time is unchanged, and the bubbles inside the gel are determined to be relatively removed and fed back to the corresponding motor one, motor two and the shaking rod to stop operation and reset gradually.

In this embodiment, the gripping device 3 includes:

guide clip carriages 31 arranged in bilateral symmetry;

the double-rack sliding plate 32 is embedded into the guide clamp sliding frame 31 and is in sliding connection, the left side and the right side of the double-rack sliding plate are respectively provided with corresponding driving gears 33 and are in meshing connection, and the bottom end of the double-rack sliding plate is hinged with four groups of clamping rods 37 which are arranged in a circumferential arrangement;

the lifting rod 34 is arranged at the lower end of the double-rack sliding plate 32, and the output end of the lifting rod is provided with a quadrilateral shaft seat 35;

the connecting rods 36 are arranged into four groups, and the upper ends and the lower ends of the connecting rods are correspondingly hinged on the corresponding four-standard shaft seat 35 and the corresponding clamping rod 37 respectively;

as the best embodiment, the double-rack sliding plate is driven to move downwards by the driving gear to enable the clamping rod to be clamped at the outer end part of the cylindrical shell cover, wherein the forming assembly is in a vertical state, the bearing sleeve is regulated and controlled to be separated from the outer shell of the mold through the upper driving seat, the telescopic rod I regulates and controls the clamping rod to move upwards by the driving gear when the telescopic rod I regulates and controls the left half shell cover to be unscrewed to be separated from the left end of the rough rod, the shaking rod is matched to pull and take out the inner shell of the mold, after the completion, the telescopic rod I further opens the left half shell cover, the formed colloid is shaken and falls into the collecting box by the shaking rod, and the corresponding steps are operated in the reverse direction to reset and wait for glue injection again.

During specific implementation, a proper forming assembly is selected and installed in the forming device, the glue injection amount of the glue injection device is regulated, the intermittent conveying speed corresponding to the loop-shaped conveying belt and the loop-shaped conveying surface belt is set, the values of a, b, c and d are all zero initially, when the forming device is conveyed into the glue injection device, the forming assembly is driven by the first motor in an auxiliary mode to be opposite to the glue injection device and glue injection is carried out, after the completion, the first motor, the second motor, the shaking rod and the air pump are started, the glue body is centrifuged, pressurized and shaken until no relative change exists in monitoring data of the pressure monitoring ball, the monitoring data are fed back to the air pump, the first motor, the second motor and the shaking rod, the taking-out of the forming glue body is completed by matching with the clamping device, the resetting of the outer shell of the mold and the inner shell of the mold is completed, and the mold is continuously and circularly operated.

The above description is only for the preferred embodiment of the present invention, but the scope of the present invention is not limited thereto, and any person skilled in the art should be considered as the technical solutions and the inventive concepts of the present invention within the technical scope of the present invention.

Claims

1. A molding apparatus for computer network connectors, comprising: from top to bottom stack gradually the shape of returning ring frame (1), the shape of returning conveying strip (8), the shape of returning conveyer belt (5) that correspond the setting, its characterized in that: fixing seats are respectively arranged on the left side and the right side of the clip-shaped ring frame (1), glue injection devices (2) and clamping devices (3) which are independent and arranged in a circumferential arrangement are respectively arranged on the fixing seats on the left side and the right side, and cold-hot devices (4) which cover partial surface areas of the clip-shaped ring frame (1) are fixedly arranged close to the left sides of the clamping devices (3);

the collecting boxes (6) are arranged on the clip-shaped conveying surface belt (5) at equal intervals;

and the forming device (7) is arranged corresponding to the collecting box (5), is arranged in the middle of the corresponding collecting box (5), and is arranged at the upper end of the forming device on the corresponding clip-shaped conveying strip (8).

2. The molding apparatus for a computer network connector as claimed in claim 1, wherein: the molding device (7) comprises:

the first motor (71) is fixed in the middle of the collecting box (6), a rotating shaft (72) is fixed at the output end of the first motor, and the top end of the rotating shaft (72) is embedded into the corresponding clip-shaped conveying strip (8) through a bearing seat (73);

the single-lug seats (74) are arranged in multiple groups, are horizontally and circumferentially arranged and are symmetrically fixed on the outer ring walls close to the upper end and the lower end of the rotating shaft (72) in an up-down mode, and the single-lug seats (74) below are hinged with corresponding shaking rods (75);

the Z-shaped frames (76) are configured into a plurality of groups, the right side ends of the Z-shaped frames are correspondingly hinged to the single lug seats (74) above and the output ends of the shaking rods (75) below respectively, the left side ends of the Z-shaped frames (76) are matched and provided with strip-shaped guide rail plates (77) on the same side and the same longitudinal surface, driving seats (78) are correspondingly arranged on the outer side surfaces of the strip-shaped guide rail plates (77) close to the upper end and the lower end respectively, fixed blocks (79) are arranged on the driving seats (78), and bearing sleeves (710) are fixed on the fixed blocks (79) above;

and the forming assembly (9) is arranged in parallel with the strip-shaped guide rail plate (77), the lower end of the forming assembly is fixed with the lower part of the strip-shaped guide rail plate (79), and the upper end of the forming assembly coaxially slides to penetrate into the upper part of the forming assembly to correspond to the inside of the bearing sleeve (710).

3. The molding apparatus for a computer network connector as claimed in claim 2, wherein: the inclination angle between the rotation of the shaking rod (75) adjustable forming assembly (9) around the single lug seat above and the longitudinal plane is 0-30 degrees.

4. The molding apparatus for a computer network connector as claimed in claim 2, wherein: the forming assembly (9) comprises:

the second motor (91) is arranged on the corresponding fixed block (79) through a concave shell frame, a double-lug seat (92) is coaxially fixed at the output end of the second motor, and a first magnet (93) is arranged in the middle of the double-lug seat (92);

the die shell (94) is of a left half shell clamping cover and right half shell clamping cover splicing structure, the lower ends of the die shell are hinged to the double-lug seats (92) on the corresponding sides respectively, and an arc-shaped hole cavity which takes the left hinged end of the double-lug seats (92) as the circle center is formed in the shell wall of the left half shell clamping cover close to the top end;

the bottom end of the inner die shell (95) is fixed with a second magnet (96) attracted with the first magnet (93), and the upper end of the inner die shell is provided with a sealing pressurizing assembly (99);

the lower ends of the first telescopic rod (97) and the second telescopic rod (98) are correspondingly hinged to the middle of the corresponding double-lug seat (92) in a front-back mode respectively, the upper ends of the first telescopic rod and the second telescopic rod are correspondingly hinged to connecting shafts respectively, the connecting shafts are correspondingly mounted on the corresponding outer side walls of the left plate shell cover and the right plate shell cover respectively, and the bottom end of the second telescopic rod (98) is of a fixed hinged structure.

5. The molding apparatus for a computer network connector as defined in claim 4, wherein: the driving force of the second motor (91) is slightly smaller than that of the first motor (71).

6. The molding apparatus for a computer network connector as defined in claim 4, wherein: the sealed plenum assembly (99) comprises:

the ventilation hole column (991) is coaxially fixed at the top end of the corresponding die inner shell (95), a cylindrical shell cover (993) is fixed at the upper end of the ventilation hole column, and a pressure monitoring ball (992) is embedded in the ventilation hole column;

the rough rod (994) penetrates and is fixed at the bottom of the cylindrical shell cover (993), the right end of the rough rod is contacted and attached with the inner shell (95) of the die, and the left end of the rough rod is provided with an arc rod which is embedded into the corresponding arc hole cavity and is in sliding friction connection;

the sealing air bag (997) is hermetically connected with and covered on the outer side of the corresponding vent hole column (991);

the air pump (995) is arranged in the cylindrical shell cover (993) and is communicated with the upper end of the corresponding air vent column (991);

and the air guide pipe (996) penetrates through the outer end of the arc-shaped rod and is guided into the cylindrical shell cover (993), and communicates external air with the inner cavity of the cylindrical shell cover (993).

7. The molding apparatus for a computer network connector as claimed in claim 1, wherein: the gripping device (3) comprises:

the guide clamp sliding frames (31) are arranged in a left-right symmetrical mode;

the double-rack sliding plate (32) is embedded into the guide clamp sliding frame (31) and is in sliding connection, the left side and the right side of the double-rack sliding plate are respectively provided with a corresponding driving gear (33) and are in meshing connection, and the bottom end of the double-rack sliding plate is hinged with four groups of clamping rods (37) which are arranged in a circumferential manner;

the lifting rod (34) is arranged at the lower end of the double-rack sliding plate (32), and the output end of the lifting rod is provided with a quadrilateral shaft seat (35);

the connecting rods (36) are arranged into four groups, and the upper ends and the lower ends of the connecting rods are correspondingly hinged on the corresponding four-standard shaft seat (35) and the clamping rod (37) respectively.