CN112960363A - High-efficient directional conveyor of connector who prevents blocking up - Google Patents

Abstract

The invention relates to a high-efficiency anti-blocking connector directional conveying device which comprises a first support, a second support, a third support, a storage box, a discharge box and a conveying belt, wherein the first support is arranged on the first support; the upper part of the first support is rotatably connected with a rotating connecting column, a square block is arranged on the first support, a first slide way and a second slide way are arranged in the square block, the second slide way is arc-shaped, and the center of the arc-shaped circle is the same as the center of the rotating connecting column; a sliding groove is formed in the first support, a sliding block is assembled in the sliding groove in a sliding mode, a third sliding way is formed in the sliding block, and the sliding block horizontally slides in a reciprocating mode; the upper part of the material storage box is connected in the rotating connecting column in a sliding manner, the bottom of the material storage box is provided with a cylinder, and the cylinder penetrates through the first slideway or the second slideway and is assembled in the third slideway in a sliding manner; the discharge box is inclined, the top of the discharge box is connected with the bottom of the storage box, and the bottom of the discharge box is connected with the conveyor belt. The invention has simple structure and convenient control; not only can be high-efficient, orderly ejection of compact, can effectively prevent to vibrate moreover and block up.

Description

High-efficient directional conveyor of connector who prevents blocking up

The technical field is as follows:

the invention relates to the field of terminals and connectors, in particular to a high-efficiency anti-blocking connector directional conveying device.

Background art:

the connector is generally an electrical connector, that is, a device for connecting two active devices to transmit current or signals, the connector is arranged at a blocked position in a circuit or between isolated and non-communicated circuits to erect a communicating bridge so as to circulate the current and enable the circuit to realize a predetermined function, because the devices of the connector are small, the connectors produced in the same batch are often intensively stored, the connectors which are disorderly and intensively stored are orderly and regularly arranged and accurately conveyed to a next procedure by using a vibration disc when the next processing is required, the vibration disc can generate larger vibration frequency during working, because the devices of the connector are small and light, part of the connectors cannot be orderly and regularly arranged and accurately conveyed to the next procedure, and the speed is slow and the efficiency is low when the connectors disorderly and intensively stored are orderly conveyed by the vibration disc, a continuous processing connector device needs to be developed, the vibration disc solves the problems that the vibration disc can generate larger vibration frequency when in work, and because the connector is small in size and light in weight, part of connectors cannot be orderly and directionally arranged to be conveyed to the next procedure accurately, and the vibration disc is slow in speed and low in efficiency when conveying the connectors which are stored in an unordered and concentrated mode orderly.

The invention content is as follows:

the invention aims to provide a high-efficiency anti-blocking connector directional conveying device aiming at the defects in the prior art so as to at least solve one of the technical problems in the prior art; the efficient anti-blocking connector directional conveying device is simple in structure and convenient to control; not only can be high-efficient, orderly ejection of compact, can effectively prevent to vibrate moreover and block up.

The technical solution of the invention is as follows:

a high-efficiency anti-blocking connector directional conveying device comprises a first support, a second support, a third support, a material storage box, a material discharge box and a conveying belt; the discharging box is arranged on the first support and the second support, and the conveying belt is arranged on the second support and the third support; the upper part of the first support is rotatably connected with a rotating connecting column, a square block is arranged on the first support, a first slide way and a second slide way are arranged in the square block, the second slide way is arc-shaped, and the center of the arc-shaped circle is the same as the center of the rotating connecting column; the first support is provided with a sliding chute, a sliding block is assembled in the sliding chute in a sliding mode, a third sliding way is arranged on the sliding block, and the sliding block horizontally slides in a reciprocating mode; the upper part of the material storage box is connected in the rotating connecting column in a sliding manner, a cylinder is arranged at the bottom of the material storage box, and the cylinder is inserted into the first slideway and the second slideway and assembled in the third slideway in a sliding manner; the discharge box is inclined, the top of the discharge box is connected with the bottom of the storage box, and the bottom of the discharge box is connected with the conveyor belt.

Preferably, the driving source for the horizontal reciprocating sliding of the sliding block comprises a motor, and the motor is fixedly arranged on the second support through a motor base; the motor is equipped with dual output shaft, all installed first drive wheel, quarter butt on the output shaft, the quarter butt is kept away from output shaft connection one end and is rotated and be connected with the stock, the stock is kept away from the quarter butt and is connected one end and rotate and connect on the slider.

Preferably, a rectangular through hole is formed in the second support and is arranged under the first transmission wheel, a transmission belt is arranged on the first transmission wheel, one end, far away from the first transmission wheel, of the transmission belt is arranged on the second transmission wheel, and the second transmission wheel is arranged on a connecting shaft between the transmission belt and the second support.

Preferably, the conveyor belt comprises two rollers respectively disposed at two ends of the conveyor belt, and the rollers are respectively fixed to the second support and the third support.

Preferably, the storage box comprises a storage box discharge port and a fixing seat arranged on the storage box, a sliding shaft is arranged on one side, far away from the storage box, of the fixing seat, a first flange is arranged at the upper end of the sliding shaft, and a second flange is arranged at the lower end of the sliding shaft.

Preferably, the rotation connecting column comprises a column body and a rotation connecting part, the rotation connecting part is rotatably connected to the first support of the first support, a sliding shaft is slidably assembled in the column body, and a first spring is arranged between the second flange and the column body.

Preferably, the discharging box comprises a discharging box top plate, a discharging channel, a feeding hole and an arc-shaped surface; the feed inlet is located under the storage box discharge port, discharging channel can only hold single connector current, the radian of arcwall face suits with the rotation orbit of storage box discharge port lower extreme.

Preferably, the top of the discharging box is slidably provided with a pushing piece, the pushing piece comprises a first pushing plate and a second pushing plate, a second spring is arranged between the second pushing plate and the top of the discharging box, and the first pushing plate is located in the feeding hole.

Preferably, the left side of the storage box is provided with a folded push plate which comprises a push plate part, and the push plate part is contacted with the second push plate.

The invention has the beneficial effects that:

the rotary connecting column can rotate, the upper end of the storage box is assembled on the rotary connecting column in a sliding mode, a cylinder at the lower end of the storage box penetrates through a first slide way and a second slide way in the square block and is assembled in a third slide way on the sliding block in a sliding mode, and the cylinder can be driven to slide in the first slide way and the second slide way through the movement of the sliding block; when the slider slides from a left side to the right side, the storage case descends earlier and rotates, when the slider slides from the right side to the left side, the storage case rotates earlier and rises again, rises at the storage case, the connector in the storage case can be made to vibrate out the storage case to the in-process that descends, falls into in the ejection of compact case, at storage case pivoted in-process, can overturn the gathering at the connector of storage bottom of the case portion, the slope, avoid the storage case discharge gate to block up, also can make the vibration ejection of compact more smooth and easy simultaneously.

The automatic connector discharging device comprises a discharging box, wherein the discharging box is inclined, so that the connector can automatically fall under the action of gravity, and the automatic connector discharging device is simple and efficient; the discharging box is provided with a discharging channel only allowing a single connector to pass through, so that the connectors conveyed to the conveying belt are orderly arranged in a single row.

The connector feeding device comprises an arc-shaped surface, the radian of the arc-shaped surface is matched with the rotating track of the lower end of the discharge port of the storage box, so that the connectors in the storage box are prevented from being thrown out in the rotating process of the storage box, and all the connectors are guaranteed to be conveyed to a conveying belt through the discharge box in a single row.

The material pushing device comprises a folded push plate and a material pushing piece, wherein when a material storage box rotates, the folded push plate rotates along with the material storage box, the material pushing piece is pushed in the rotating process of the folded push plate, a spring is compressed, a second material pushing plate moves in a material inlet, connectors at the material inlet are pushed to a material outlet channel, and certain connectors are prevented from being retained in the material inlet; when the material storage box is rotated back to the vertical state, the first material pushing plate can return to the original position under the action of the elastic force of the spring, so that the material is prevented from being blocked; the folded push plate and the pushing piece are combined with the storage box to rotate, so that the hidden danger of accumulation and blockage of the connector in the discharge box can be effectively avoided.

The automatic feeding device comprises a first driving wheel and a second driving wheel, wherein the first driving wheel and the second driving wheel are connected through a driving belt, so that the driving belt and a material storage box move under the control of the same motor, the problems of difficulty in controlling excessive driving sources and high cost are solved, the frequency of discharging can correspond to the transmission rate of the driving belt under the control of the same motor, and connectors on the driving belt can be orderly transmitted to the next production process; by changing the size ratio of the first transmission wheel 11 and the second transmission wheel 13, the proportional relation between the transmission speed of the conveyor belt 14 and the sliding speed of the sliding block 7 can be adjusted, and the arrangement interval of the connectors on the conveyor belt 14 can be adjusted.

Description of the drawings:

the invention is further described below with reference to the accompanying drawings:

fig. 1 is a schematic view of the overall assembly of the present invention.

Fig. 2 is a right side schematic view of the integral assembly of the present invention.

Fig. 3 is a schematic structural diagram of the first support of the present invention.

Fig. 4 is a front cross-sectional schematic view of the overall assembly of the present invention.

FIG. 5 is a schematic partial sectional view of the connecting structure of the connecting column and the material storage box according to the present invention.

Fig. 6 is a schematic structural diagram of the transmission mechanism of the present invention.

Fig. 7 is a schematic structural diagram of the discharging mechanism of the present invention.

In the figure: a first support-1, a first support-101, a square block-102, a first slideway-1021, a second slideway-1022, a chute-103, a second support-2, a through hole-201, a third support-3, a storage box-4, a storage box outlet-404, a fixed seat-401, a sliding shaft-402, a first flange-4021, a second flange-4022, a cylinder-403, a rotary connecting column-5, a cylinder-501, a rotary connecting part-502, a first spring-6, a slide block-7, a third slideway-701, a long rod-8, a short rod-9, a motor-10, a motor seat-1001, a first transmission wheel-11, a transmission belt-12, a second transmission wheel-13, a transmission belt-14, a roller-1401, a second transmission wheel-10, a second transmission wheel-3, a second transmission, The device comprises a discharge box-15, a discharge box top plate-1501, a discharge channel-1502, a feed inlet-1503, a first connecting rod-1504, a second connecting rod-1505, an arc-shaped surface-1506, a folded push plate-16, a push plate part-1601, a second spring-17, a pusher-18, a first pusher-1801 and a second pusher-1802.

The specific implementation mode is as follows:

the following description is of the preferred embodiment of the present invention only, and is not intended to limit the scope of the present invention, and it will be apparent to those skilled in the art that various modifications and variations can be made in the present invention; any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

In addition, references to the terms "vertical," "horizontal," "top," "bottom," "front," "back," "upper," "lower," "inner," "outer," and the like in embodiments of the invention are based on the orientation or positional relationship shown in FIG. 1, or the orientation or positional relationship in which the product is conventionally used, for convenience in describing and simplifying the description, and do not indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the invention.

In the description of the present invention, it should be noted that, unless otherwise explicitly specified or limited, terms such as "mounted," "connected," and "fixed" in the description are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; either directly or indirectly through intervening media, or through both elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art. The present invention will be described in detail below with reference to the embodiments with reference to the attached drawings.

A high-efficiency anti-blocking connector directional conveying device is shown in attached figures 1 to 7 and comprises a first support 1, a second support 2, a third support 3, a material storage box 4, a discharge box 15 and a conveying belt 14; the discharging box 15 is arranged on the first support 1 and the second support 2, and the conveying belt 14 is arranged on the second support 2 and the third support 3; the upper part of the first support 1 is rotatably connected with a rotating connecting column 5, a square block 102 is arranged on the first support 1, a first slideway 1021 and a second slideway 1022 are arranged in the square block 102, the second slideway 1022 is arc-shaped, and the center of the arc-shaped circle is the same as the center of the rotating connecting column 5; a sliding groove 103 is formed in the first support 1, a sliding block 7 is assembled in the sliding groove 103 in a sliding mode, a third sliding way 701 is formed in the sliding block 7, and the sliding block 7 horizontally slides in a reciprocating mode; the upper part of the material storage box 4 is slidably connected into the rotating connecting column 5, a cylinder 403 is arranged at the bottom of the material storage box 4, and the cylinder 403 is inserted through a first slideway 1021 and a second slideway 1022 and slidably assembled in a third slideway 701; the discharging box 15 is inclined, the top of the discharging box is connected with the bottom of the material storage box 4, and the bottom of the discharging box is connected with the conveying belt 14.

Preferably, the first slide track 1021 is in a vertical bar shape, and when the cylinder 403 slides in the first slide track 1021, the storage box 4 is in a motion state of vibrating up and down, so that the connector can fall out of the storage box 4 along with the vibration; the arc of the second slideway 1022 is adapted to the track of the cylinder 403 when the material storage box 4 rotates, to be exact, when the cylinder 403 moves in the second slideway 1022, the material storage box 4 and the rotary connecting column 5 can be driven to rotate around the rotary connecting part of the rotary connecting column 5 and the first support 1, the material storage box 4 is inclined, the connector inside the material storage box 4 is driven to turn over and incline, and the connector at the bottom of the material storage box 4 is prevented from being accumulated and blocked; the third slide way 701 is an inclined strip-shaped slide way, and the cylinder 403 can be driven to slide between the first slide way 1021 and the second slide way 1022 in a reciprocating manner by the horizontal reciprocating sliding of the slide block 7.

Further preferably, in the embodiment, when the slider 7 slides to the leftmost end, the third slide way 701 drives the cylinder 403 to slide to the top end of the first slide way 1021, and when the slider 7 slides to the leftmost end, the third slide way 701 drives the cylinder 403 to slide to the rightmost end of the second slide way 1022, and the cycle is repeated.

Still further preferably, as shown in fig. 1, the first support 1, the second support 2 and the third support 3 are all in an axisymmetrical structure.

Preferably, the driving source for the horizontal reciprocating sliding of the sliding block 7 comprises a motor 10, and the motor 10 is fixedly mounted on the second support 2 through a motor base 1001; the motor 10 is equipped with dual output shaft, all installed first drive wheel 11, quarter butt 9 on the output shaft, quarter butt 9 is kept away from output shaft connection one end and is rotated and be connected with stock 8, stock 8 is kept away from quarter butt 9 and is connected one end and rotate and connect on slider 7.

Further preferably, in the embodiment, a slider link mechanism is formed among the short rod 9, the long rod 8 and the slider 7, and the short rod 9 and the long rod 8 are sized according to the motion track of the slider 7, which is common knowledge and can be fully understood by those skilled in the art in combination with the present disclosure, and therefore, the details are not described herein; the motor 10 is also of an axisymmetrical structure, that is, the output shafts at the two ends of the motor 10 have the same size.

Still further preferably, the driving source for the horizontal reciprocating sliding of the sliding block 7 can be a push rod cylinder or a push rod motor, and in the embodiment, a rotating motor is combined with a sliding block link mechanism, so that the movement stability of the sliding block 7 is ensured, the conveying belt 14 can be connected with the rotating motor, the whole device is controlled by a single driving source, the structure is simpler, the control is more convenient, meanwhile, the conveying speed of the conveying belt 14 and the sliding speed of the sliding block 7 are kept stable, and the connector can be conveyed to the next procedure uniformly and orderly.

Preferably, a rectangular through hole 201 is formed in the second support 2 under the first driving wheel 11, a driving belt 12 is mounted on the first driving wheel 11, one end of the driving belt 12, far away from the first driving wheel 11, is mounted on the second driving wheel 13, and the second driving wheel 13 is mounted on a connecting shaft between the driving belt 14 and the second support 2.

Further preferably, in the embodiment, the first driving wheel 11 is vertically opposite to the second driving wheel 13, the driving belt 12 passes through the through hole 201 to connect the first driving wheel 11 with the second driving wheel 13, the kinetic energy of the motor 10 is transmitted to the conveying belt 14, the conveying belt 14 is moved, and by changing the size ratio of the first driving wheel 11 to the second driving wheel 13, the proportional relationship between the transmission speed of the conveying belt 14 and the sliding speed of the sliding block 7 can be adjusted, so as to adjust the size of the arrangement interval of the connectors on the conveying belt 14.

Preferably, the conveyor 14 includes two rollers 1401, the rollers 1401 are respectively disposed at two ends of the conveyor 14, and the rollers 1401 are respectively fixed on the second support 2 and the third support 3.

Further preferably, in the embodiment, the second transmission wheel 13 is mounted on a fixed connecting shaft of the roller 1401 and the second support 2.

Preferably, the storage box 4 comprises a storage box discharge port 404 and a fixing seat 401 mounted on the storage box 4, a sliding shaft 402 is arranged on one side of the fixing seat 401, which is far away from the connection side of the storage box 4, a first flange 4021 is arranged at the upper end of the sliding shaft 402, and a second flange 4022 is arranged at the lower end of the sliding shaft.

Further preferably, in the embodiment, the storage bin outlet 404 can only accommodate a single connector drop; the bottom of the storage box 4 is of a slope structure, the connector in the storage box 4 can be pushed to the upper end of the storage box discharge port 404 under the action of gravity, vibration and discharging are facilitated, when the storage box 4 rotates, the connector stacked at the upper end of the storage box discharge port 404 can be dumped onto the slope, a sharp corner can be stacked at the intersection of the slope and the storage box discharge port 404 by the connector, when the storage box 4 is rotated back to a vertical state to vibrate up and down, the connector on the slope can fall into the storage box discharge port 404 in sequence, stacking and blocking cannot occur.

Preferably, the rotation connection column 5 comprises a cylinder 501 and a rotation connection part 502, the rotation connection part 502 is rotatably connected to the first bracket 101 of the first pedestal 1, the slide shaft 402 is slidably assembled in the cylinder 501, and the first spring 6 is assembled between the second flange 4022 and the cylinder 501.

Further preferably, in the embodiment, the first spring 6 is used for buffering and improving the vertical vibration effect of the material storage tank 4.

Preferably, the discharging box 15 comprises a discharging box top plate 1501, a discharging channel 1502, a feeding hole 1503 and an arc-shaped surface 1506; the feed inlet 1503 is located right below the discharge port 404 of the storage box, the discharge channel 1502 can only accommodate a single connector to pass through, and the radian of the arc-shaped surface 1506 is adapted to the rotation track of the lower end of the discharge port 404 of the storage box; specifically, when the storage bin 4 rotates, the outlet end of the storage bin discharge port 404 is connected to the arc-shaped surface 1506, and the radius of the arc-shaped surface 1506 is larger, so that the gap between the storage bin discharge port 404 and the arc-shaped surface 1506 is very small, and the connector cannot fall out of the storage bin discharge port 404.

Further preferably, the feed inlet 1503 is provided with a large upper part and a small lower part, and the lower end of the feed inlet 1503 is connected with the discharge channel 1502 to guide the connector falling into the feed inlet 1503.

Still further as preferred, storage case discharge gate 404 bottom can be the arc, just the arc pastes with arcwall face 1506 mutually, and when storage case 4 rotated, the curved storage case discharge gate 404 laminating arcwall face 1506 of bottom rotated, avoided the connector to fall out the feed inlet 1503 region outside at storage case 4 pivoted in-process.

Preferably, the ejection box 15 is slidably provided with an ejection member 18 at the top, the ejection member 18 includes a first ejection plate 1801 and a second ejection plate 1802, a second spring 17 is provided between the second ejection plate 1802 and the top of the ejection box 15, and the first ejection plate 1801 is located in the feed opening 1503.

Preferably, the left side of the storage box 4 is provided with a folded push plate 16, which includes a push plate portion 1601, and the push plate portion 1601 contacts with the second push plate 1802.

The specific use mode is as follows:

the motor 10 controls the short rod 9 to rotate to drive the long rod 8 to move, and further drives the slider 7 to perform horizontal reciprocating motion, when the slider 7 slides from the leftmost end to the rightmost end, the slider 7 drives the cylinder 403 assembled in the third slide way 701 to slide from the top of the first slide way 1021 to the bottom of the first slide way 1021, and then drives the cylinder 403 to move from the left end of the second slide way 1022 to the right end of the second slide way 1022, in the process, the material storage box 4 firstly performs top-to-bottom movement in the rotating connecting column 5, and then drives the rotating connecting column 5 to rotate together around the rotating connecting column 5 and the rotating connecting part of the first bracket-101; in the process of rotating the material storage box 4, the folded push plate 16 also rotates along with the rotation of the material storage box 4, so that the push plate portion 1601 pushes the material pushing member 18, and the first material pushing plate 1801 moves; when the slider 7 slides from the rightmost end to the leftmost end, the movement is reversed in accordance with the above movement.

When the cylinder 403 moves up and down on the first slideway 1021, the material storage box 4 vibrates up and down, and the connector which is vibrated falls into the feeding hole 1503, then falls onto the conveyor belt 14 through the discharging channel 1502, and is conveyed to the next process along with the conveyor belt 14; cylinder 403 is during side-to-side motion in second slide 1022, storage case 4 slopes, and the connector in term also keeps the slope, avoids storage case 4 bottom to block up, makes things convenient for the vibration ejection of compact next time, and at the rotation in-process, push pedal portion 1601 promotes and pushes away material spare 18, and then makes first scraping wings 1801 parallel translation in feed inlet 1503, pushes discharging channel 1502 with the connector that screens or other reasons can't drop automatically in, keeps the spacious of feed inlet 1503, prepares for blanking next time.

In the description herein, references to the description of the terms "embodiment," "one embodiment," "some embodiments," "illustrative embodiments," "examples," "specific examples," or "some examples," etc., mean that a particular feature, structure, material, or characteristic described in connection with the embodiment or example is included in at least one embodiment or example of the invention. In this specification, the schematic representations of the terms used above do not necessarily refer to the same embodiment or example. Furthermore, the particular features, structures, materials, or characteristics described may be combined in any suitable manner in any one or more embodiments or examples.

While embodiments of the invention have been shown and described, it will be understood by those of ordinary skill in the art that: various changes, modifications, substitutions and alterations can be made to the embodiments without departing from the principles and spirit of the invention, the scope of which is defined by the claims and their equivalents.

Claims (9)

1. A high-efficiency anti-blocking connector directional conveying device comprises a first support (1), a second support (2), a third support (3), a storage box (4), a discharge box (15) and a conveying belt (14); the discharging box (15) is arranged on the first support (1) and the second support (2), and the conveying belt (14) is arranged on the second support (2) and the third support (3); the method is characterized in that:

the upper part of the first support (1) is rotatably connected with a rotating connecting column (5), a square block (102) is arranged on the first support (1), a first slide way (1021) and a second slide way (1022) are arranged in the square block (102), the second slide way (1022) is arc-shaped, and the center of the arc-shaped circle is the same as the center of the rotating connecting column (5); a sliding groove (103) is formed in the first support (1), a sliding block (7) is assembled in the sliding groove (103) in a sliding mode, a third sliding way (701) is formed in the sliding block (7), and the sliding block (7) horizontally slides in a reciprocating mode;

the upper part of the storage box (4) is connected in the rotating connecting column (5) in a sliding manner, a cylinder (403) is arranged at the bottom of the storage box (4), and the cylinder (403) penetrates through the first slideway (1021) or the second slideway (1022) to be assembled in the third slideway (701) in a sliding manner;

the discharging box (15) is inclined, the top of the discharging box is connected with the bottom of the storage box (4), and the bottom of the discharging box is connected with the conveying belt (14).

2. The high-efficiency anti-blocking connector directional conveying device according to claim 1, characterized in that: the driving source for the sliding block (7) to horizontally slide in a reciprocating manner comprises a motor (10), and the motor (10) is fixedly arranged on the second support (2) through a motor base (1001); motor (10) are equipped with dual output shaft, all installed first drive wheel (11), quarter butt (9) on the output shaft, output shaft connection one end is kept away from in quarter butt (9) and is rotated and be connected with stock (8), stock (8) are kept away from quarter butt (9) and are connected one end rotation and connect on slider (7).

3. The high-efficiency anti-blocking connector directional conveying device according to claim 2, characterized in that: the novel transmission device is characterized in that a rectangular through hole (201) is formed in the second support (2) under the first transmission wheel (11), a transmission belt (12) is arranged on the first transmission wheel (11), one end, far away from the first transmission wheel (11), of the transmission belt (12) is arranged on the second transmission wheel (13), and the second transmission wheel (13) is arranged on a connecting shaft between the transmission belt (14) and the second support (2).

4. The high-efficiency anti-blocking connector directional conveying device according to claim 3, characterized in that: the conveyor belt (14) comprises two rollers (1401), the rollers (1401) are respectively arranged at two ends of the conveyor belt (14), and the rollers (1401) are respectively and fixedly arranged on the second support (2) and the third support (3).

5. The high-efficiency anti-blocking connector directional conveying device according to claim 1, characterized in that: storage case (4) include storage case discharge gate (404), install fixing base (401) on storage case (4), fixing base (401) are kept away from storage case (4) and are connected one side and are equipped with slide (402), slide (402) upper end is equipped with first flange (4021), and the lower extreme is equipped with second flange (4022).

6. The high-efficiency anti-blocking connector directional conveying device according to claim 5, characterized in that: the rotating connecting column (5) comprises a column body (501) and a rotating connecting part (502), the rotating connecting part (502) is rotatably connected to the first support (101) of the first support (1), a sliding shaft (402) is assembled in the column body (501) in a sliding mode, and a first spring (6) is arranged between the second flange (4022) and the column body (501).

7. The high-efficiency anti-blocking connector directional conveying device according to claim 1, characterized in that: the discharging box (15) comprises a discharging box top plate (1501), a discharging channel (1502), a feeding hole (1503) and an arc-shaped surface (1506); the feeding hole (1503) is located right below the discharging hole (404) of the storage box, the discharging channel (1502) can only accommodate a single connector to pass through, and the radian of the arc-shaped surface (1506) is adapted to the rotating track of the lower end of the discharging hole (404) of the storage box.

8. The high-efficiency anti-blocking connector directional conveying device according to claim 7, characterized in that: the material pushing device is characterized in that a material pushing piece (18) is installed on the top of the discharging box (15) in a sliding mode, the material pushing piece (18) comprises a first material pushing plate (1801) and a second material pushing plate (1802), a second spring (17) is installed between the second material pushing plate (1802) and the top of the discharging box (15), and the first material pushing plate (1801) is located in the feeding hole (1503).

9. The high-efficiency anti-blocking connector directional conveying device according to claim 8, characterized in that: folded push plates (16) are arranged on the left side of the storage box (4) and comprise push plate portions (1601), and the push plate portions (1601) are in contact with the second push plates (1802).

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