CN117068723A - Electronic accessory linkage conveying equipment - Google Patents

Abstract

The invention relates to electronic accessory linkage conveying equipment, which comprises a spiral conveying device; a waste discharge device is arranged at a waste discharge station on a spiral channel of the spiral conveying device; the waste discharge station is positioned before the cover buckling station; the waste discharge device comprises a waste discharge pressing driving shaft part arranged above the spiral channel, and a waste discharge downward opening and closing butt door is arranged at the bottom of the spiral channel of the waste discharge station; an input end of a waste discharge output part is arranged below the waste discharge downward opening and closing butt door; the waste discharge pressing-down driving shaft part is eccentrically provided with a waste discharge eccentric pressure head which is intermittently contacted with the upper surface of the box at the waste discharge station to detect whether the box is opened upwards or not, and push the box with the bottom upwards downwards, and the waste discharge pressing-down driving shaft part is propped up to open and close the opposite door downwards, so that the box with the opening downwards enters the input end of the waste discharge output part. The invention has reasonable design, compact structure and convenient use.

Description

Electronic accessory linkage conveying equipment

Technical Field

The invention relates to electronic accessory linkage conveying equipment.

Background

In the electronic industry, for example, in the aerospace field, a large number of electronic parts such as power supply components and controllers are required to be assembled on site, the existing assembly mode generally adopts a production line or a rotating disc to realize the assembly buckle cover effect on the accessory electronic parts, and the assembly buckle cover effect is characterized in that the existing electronic parts are distributed in a tidy way, but the existing electronic parts have large occupied area of a factory building, waste of fixed assets is caused, and how to improve the electronic parts on the production line is improved, so that the problem of land resource shortage is solved, the assembly area is saved, and the technical problem to be solved urgently is realized.

The invention is used as a matched improvement of the system, in order to ensure that the cover can be correctly buckled, the characteristics that the upper surface is sunken or does not exist due to the opening, and the bottom is plane are added, the detection is realized by utilizing the height difference, and the problem of high spiral output speed is solved through the involuted output part, so that the one-by-one output is realized. In order to solve the automation problem of falling lock upper cover, realize automatic assembly to the gliding casing to guaranteed the advancement of whole system, automation, smoothness, solved in the spiral passageway, the difficult problem of location of box, the material loading of the invention is the buckle closure, but not limited to the buckle closure, can combine the design needs, send the sign into processes such as batching and add and regard as equivalent replacement.

Disclosure of Invention

The invention aims to provide electronic accessory linkage conveying equipment.

In order to solve the problems, the invention adopts the following technical scheme:

an electronic accessory linkage conveying device comprises a spiral conveying device; a waste discharge device is arranged at a waste discharge station on a spiral channel of the spiral conveying device; the waste discharge station is positioned before the cover buckling station;

the waste discharge device comprises a waste discharge pressing driving shaft part arranged above the spiral channel, and a waste discharge downward opening and closing butt door is arranged at the bottom of the spiral channel of the waste discharge station; an input end of a waste discharge output part is arranged below the waste discharge downward opening and closing butt door;

the waste discharge pressing-down driving shaft part is eccentrically provided with a waste discharge eccentric pressure head which is intermittently contacted with the upper surface of the box at the waste discharge station to detect whether the box is opened upwards or not, and push the box with the bottom upwards downwards, and the waste discharge pressing-down driving shaft part is propped up to open and close the opposite door downwards, so that the box with the opening downwards enters the input end of the waste discharge output part.

As a further improvement of the above technical scheme:

an output separating device is arranged at an output station of the spiral conveying device;

the output separation device comprises an outlet diversion driving part arranged at the output station; the outlet turning driving part is meshed with an outlet forward shifting gear shaft through a gear, and is indirectly meshed with an outlet reverse shifting gear shaft through an outlet turning gear set serving as an intermediate gear shaft;

the structure of the outlet forward shifting gear shaft is the same as that of the outlet reverse shifting gear shaft, the steering is opposite, and the outlet forward shifting gear shaft and the outlet reverse shifting gear shaft are respectively provided with an outlet shifting arm which rotates in opposite directions so as to output boxes at the output station one by one.

A buckle cover feeding device is arranged at a buckle cover feeding station of the spiral conveying device; the buckle cover feeding device is positioned behind the waste discharge device;

the waste discharge downward-pressing driving shaft part, the outlet turning driving part and the cover turning output part of the cover feeding device are arranged in a linkage way.

A linkage conveying process of an aerospace electronic component, which is realized by a spiral conveying device; s4, performing a waste discharge station, and discharging the inverted box through a waste discharge device;

s5, executing a buckle cover feeding station, wherein the buckle cover feeding device buckles the box with the upward opening;

s6, outputting the boxes after the buckling cover one by an output separating device at an output station;

when the waste discharge eccentric pressure head is lifted for one stroke, the output separation device rotates for one stroke.

As a further improvement of the above technical scheme:

in step S4, the specific steps are as follows,

s4.1, pressing the waste discharge eccentric pressure head rotating on the driving shaft part through waste discharge to intermittently contact with the upper surface of the box at the waste discharge station, detecting whether the opening of the box is upward, and when the opening is upward, the waste discharge eccentric pressure head enters the opening, otherwise, pushing the box with the bottom upward downwards, pushing the waste discharge door to open and close downwards, so that the box with the opening downward enters the input end of the waste discharge output part.

When the waste discharge eccentric pressure head ascends and descends for one stroke, the buckle cover feeding device ascends and descends for one buckle cover stroke; when the buckle cover feeding device is empty, the falling buckle cover is recovered through the collecting channel.

In S6, the outlet turning driving part is meshed with an outlet forward stirring gear shaft through a gear and is indirectly meshed with an outlet reverse stirring gear shaft through an outlet turning gear set, so that the outlet stirring arms output boxes positioned at the output station one by one.

The invention has reasonable design, low cost, firmness, durability, safety, reliability, simple operation, time and labor saving, fund saving, compact structure and convenient use.

Drawings

Fig. 1 is a schematic diagram of a spiral output usage structure of the present invention.

Fig. 2 is a schematic diagram of the waste discharging structure of the present invention.

Fig. 3 is a schematic diagram of the output structure of the present invention.

Fig. 4 is a schematic view of the buckle cover of the present invention.

Wherein: 2. a screw conveyor; 3. a buckle cover feeding device; 4. a waste discharging device; 5. an output separation device; 52. waste discharge pushing down the driving shaft part; 53. waste discharge eccentric pressure heads; 54. waste discharge downward opening and closing door-to-door; 55. a waste discharge output unit; 56. an outlet turning driving part; 57. the outlet is used for pulling the gear shaft forward; 58. an outlet steering gear set; 59. the outlet reversely toggles the gear shaft; 60. an outlet poking arm;

61. a buckle cover feeding and conveying part; 62. covering the feeding terminal; 63. the buckle cover downwards closes the baffle; 64. a buckle cover turning output part; 65. the buckle cover lifts the rack; 66. the elastic radial telescopic arm is arranged on the buckle cover; 67. a lower supporting plate is covered; 68. the lower top is adsorbed by the buckle cover under negative pressure; 69. the buckle cover swings the bent arm; 70. a buckle cover hinge; 71. the first guide groove is covered; 72. a front stop driving arm of the buckle cover; 73. a buckle cover guide post; 74. a buckle cover linkage pin; 75. a buckle cover process bent arm; 76. a front blocking arm of the buckle cover; 77. a magnetic base is covered; 78. covering the process gap; 79. the buckle cover guides the conical surface.

Detailed Description

As shown in fig. 1 to 4, the electronic accessory linkage conveying device of the present embodiment includes a screw conveyor 2; a waste discharge device 4 is arranged at a waste discharge station on a spiral channel of the spiral conveying device 2; the waste discharge station is positioned before the cover buckling station;

the waste discharging device 4 comprises a waste discharging pressing driving shaft part 52 arranged above the spiral channel, and a waste discharging downward opening and closing opposite door 54 is arranged at the bottom of the spiral channel of the waste discharging station; an input end of a waste discharge output part 55 is arranged below the waste discharge downward opening and closing butt door 54;

a waste discharge eccentric pressing head 53 is eccentrically provided on the waste discharge pressing driving shaft 52 to intermittently contact with the upper surface of the box at the waste discharge station to detect whether the box is opened upward and push the box with the bottom upward downward, and push the waste discharge downward opening and closing door 54 so that the box with the opening downward enters the input end of the waste discharge output 55.

An output separating device 5 is arranged at the output station of the spiral conveying device 2;

the output separating device 5 comprises an outlet diversion driving part 56 arranged at the output station; the outlet turning driving part 56 is meshed with an outlet forward stirring gear shaft 57 through a gear, and the outlet turning driving part 56 is indirectly meshed with an outlet reverse stirring gear shaft 59 through an outlet turning gear set 58 serving as an intermediate gear shaft;

the exit forward-shifting gear shaft 57 and the exit reverse-shifting gear shaft 59 have the same structure and reverse directions, and the exit forward-shifting gear shaft 57 and the exit reverse-shifting gear shaft 59 are respectively provided with an exit shifting arm 60 which rotates in opposite directions so as to output the cassettes at the output station one by one.

A buckle cover feeding device 3 is arranged at the buckle cover feeding station of the spiral conveying device 2; the buckle cover feeding device 3 is positioned behind the waste discharging device 4;

the waste discharge pressing drive shaft 52, the outlet turning drive 56, and the cover turning output 64 of the cover loading device 3 are arranged in linkage.

The linkage conveying process of the aerospace electronic component of the embodiment is realized by means of the screw conveying device 2; s4 is executed at a waste discharge station, and the inverted box is discharged through a waste discharge device 4;

s5, executing a buckle cover feeding station, wherein the buckle cover feeding device 3 buckles a box with an upward opening;

s6, outputting the boxes after the buckling cover one by the output separating device 5 at an output station;

when the waste discharge eccentric ram 53 is lifted by one stroke, the output separating apparatus 5 is rotated by one stroke.

In step S4, the specific steps are as follows,

s4.1, detecting whether the box is opened upwards or not by intermittently contacting the upper surface of the box at a waste discharging station through the waste discharging eccentric pressing head 53 rotating on the waste discharging pressing driving shaft part 52, and when the opening is upward, the waste discharging eccentric pressing head 53 enters the opening, otherwise, pushing the box with the bottom upward downwards, and pushing the waste discharging downwards to open and close the opposite door 54, so that the box with the opening downward enters the input end of the waste discharging output part 55.

When the waste discharge eccentric pressure head 53 is lifted by one stroke, the cover buckling feeding device 3 is lifted by one cover buckling stroke; when the buckle closure feeding device 3 is empty, the falling buckle closure is recovered through the collecting channel.

In S6, the outlet diversion driving part 56 is meshed with the outlet forward-shifting gear shaft 57 through a gear and is indirectly meshed with the outlet reverse-shifting gear shaft 59 through the outlet steering gear group 58, so that the outlet shifting arm 60 outputs the cassettes located at the output station one by one.

As shown in fig. 1 to 4, as shown in fig. 1, the buckle cover feeding device of the electric component carrying box of the present embodiment includes a buckle cover feeding conveying part 61 provided above the buckle cover feeding station of the conical screw conveying passage; a buckle cover terminal baffle is arranged at a buckle cover feeding terminal 62 of the buckle cover feeding conveying part 61, and a buckle cover downward involution baffle 63 is arranged at the bottom of the buckle cover feeding terminal 62;

a buckle cover pressing manipulator is arranged above the buckle cover feeding terminal 62; the buckle cover pressing manipulator is linked with a buckle cover material blocking manipulator and is used for blocking a box which is positioned at a buckle cover feeding station and is preloaded with an electric device from moving forward.

The cover pressing manipulator comprises a cover turning output part 64, a cover lifting rack 65 which is vertically lifted is meshed with an output gear of the cover turning output part 64, a cover upper elastic radial telescopic arm 66 and a cover lower supporting plate 67 are distributed on a lifting rod at the lower end of the cover lifting rack 65, and a cover negative pressure absorption lower top 68 is arranged at the lower end of the lifting rod;

the buckle cover negative pressure suction lower plug 68 is positioned above the buckle cover downward closing baffle 63 to push down the buckle cover positioned on the buckle cover feeding terminal 62 onto the box preloaded with the electric accessories on the conical screw conveying channel for buckling.

The cover blocking manipulator comprises a cover swinging bent arm 69; the root of the buckle cover swinging bent arm 69 is arranged between the buckle cover upper elastic radial telescopic arm 66 and the buckle cover lower supporting plate 67; a buckle cover magnet is arranged on the buckle cover swing bent arm 69, and a buckle cover magnetic seat 77 is arranged at the stroke end of the buckle cover swing bent arm 69 so as to be attracted with the buckle cover magnet;

the lower end of the elastic radial telescopic arm 66 on the buckle cover is provided with a buckle cover guiding conical surface 79, and the buckle cover swinging bent arm 69 is provided with a buckle cover process gap 78 with a notch; after the buckle closure guide conical surface 79 descends into the buckle closure process gap 78, the buckle closure guide conical surface is elastically pressed and in friction contact with the outer side wall of the elastic radial telescopic arm 66 on the descending buckle closure; a buckle cover hinge 70 is provided on the buckle cover swing bent arm 69 so as to serve as a fulcrum of the buckle cover swing bent arm 69 swinging;

a cover first guide groove 71 is arranged in the middle of the lifting cover swing bent arm 69, and a cover linkage pin 74 of a cover front baffle driving arm 72 is arranged in the cover first guide groove 71 in a moving way;

a cover guiding post 73 is fixedly arranged in a guiding groove of the cover front baffle driving arm 72, a cover craft bent arm 75 is arranged on one side of the cover front baffle driving arm 72 in a swinging mode, a rotating shaft is arranged at one end of the cover craft bent arm 75, a cover front baffle arm 76 is arranged at the other end of the cover craft bent arm 75, and the cover front baffle arm 76 is inserted into the conical screw conveying channel in a downward swinging mode so as to baffle the box at a cover feeding station.

The buckle cover assembling process comprises the following steps of S5, covering a buckle cover on a box in a conical screw conveying channel at a buckle cover feeding station; the method specifically comprises the following steps of;

s5.1, firstly, conveying the buckle closure to a buckle closure feeding terminal 62 through a buckle closure feeding conveying part 61; then, the buckle closure direction changing output part 64 drives the buckle closure lifting rack 65 to descend; secondly, after the buckling cover guide conical surface 79 passes through the buckling cover process gap 78 downwards, the outer side wall of the buckling cover upper elastic radial telescopic arm 66 elastically contacts with the corresponding side wall of the buckling cover process gap 78 in a pressure mode; thirdly, the corresponding side wall of the buckle closure process gap 78 is in dynamic friction contact with the elastic radial telescopic arm 66 on the buckle closure, so that the buckle closure swinging bent arm 69 swings; thereafter, the buckle closure linkage pin 74 slides in the buckle closure first guide groove 71, so that the buckle closure front-stop driving arm 72 descends along the buckle closure guide post 73; then, the cover front blocking driving arm 72 drives the cover craft bent arm 75 to swing downwards and insert into the conical screw conveying channel so as to block the box at the cover feeding station, and meanwhile, the cover magnet of the cover swing bent arm 69 is attracted to the corresponding cover magnetic seat 77 and is blocked from continuing to move downwards;

s5.2, firstly, the elastic radial telescopic arm 66 on the buckle closure moves and rubs against the corresponding side wall of the buckle closure process gap 78 and continues to move downwards; then, the buckle cover negative pressure adsorbs the lower top 68 to push down the buckle cover located on the buckle cover feeding terminal 62, and the buckle cover is pushed open to the downward closing baffle 63, so that the buckle cover is buckled on the box preloaded with the electric fittings on the conical screw conveying channel.

After the buckling, after S5.2, S5.3 is executed, first, the buckle cover lifting rack 65 is driven to move reversely, and the elastic radial telescopic arm 66 on the buckle cover moves and rubs against the corresponding sidewall of the buckle cover process gap 78 and moves upwards reversely, so that the buckle cover magnet of the buckle cover swinging bent arm 69 is separated from the buckle cover magnetic base 77, and the buckle cover is automatically and elastically reset and closed upwards towards the buckling baffle 63; then, the buckle cover lifting rack 65 continues to ascend, so that the elastic radial telescopic arm 66 on the buckle cover is separated from the corresponding side wall of the buckle cover process gap 78; finally, the buckle cover lower support plate 67 lifts the tail of the buckle cover swing bent arm 69 and is attracted to the corresponding buckle cover magnetic seat 77, so that the buckle cover front baffle arm 76 lifts, and the buckled box continues to move forward and leaves the buckle cover feeding station.

According to the invention, aiming at the problem of cover buckling on a spiral channel, automatic feeding is realized through the cover buckling feeding conveying part 61, the cover buckling feeding terminal 62 finishes the installation of the cover buckling on a box, the cover buckling baffle 63 is reset by a spring and is opened by downward stress, the cover buckling direction changing output part 64 can realize linkage control with other stations, so that a sensor is replaced, the design is ingenious, the cost is reduced, the cover buckling lifting rack 65 realizes linear driving, the cover buckling elastic radial telescopic arm 66 can realize outer top supporting opening through a clamp spring, thereby realizing elastic pressure contact with the cover buckling process gap 78, realizing downward movement of friction force and keeping clamping restriction, thereby solving the problem of poor action, and ensuring that the box is prefabricated and positioned when the cover buckling falls. The clamping part can be automatically reset through the buckle cover lower supporting plate 67, the problem of non-opening is avoided, the buckle cover negative pressure absorption lower top 68 is used for absorbing, pressing and blowing and loosening, the buckle cover swing bent arm 69, the buckle cover hinge part 70, the buckle cover first guide groove 71, the buckle cover front baffle driving arm 72, the buckle cover guide post 73, the buckle cover linkage pin 74 and the buckle cover process bent arm 75 are linked to realize the opening and closing control of the buckle cover front baffle arm 76, the buckle cover magnetic seat 77 is used for realizing magnetic attraction and positioning, and the buckle cover guide conical surface 79 is used for realizing the guide function.

According to the invention, aiming at the problem of cover buckling on a spiral channel, automatic feeding is realized through the cover buckling feeding conveying part 61, the cover buckling feeding terminal 62 finishes the installation of the cover buckling on a box, the cover buckling baffle 63 is reset by a spring and is opened by downward stress, the cover buckling direction changing output part 64 can realize linkage control with other stations, so that a sensor is replaced, the design is ingenious, the cost is reduced, the cover buckling lifting rack 65 realizes linear driving, the cover buckling elastic radial telescopic arm 66 can realize outer top supporting opening through a clamp spring, thereby realizing elastic pressure contact with the cover buckling process gap 78, realizing downward movement of friction force and keeping clamping restriction, thereby solving the problem of poor action, and ensuring that the box is prefabricated and positioned when the cover buckling falls. The clamping part can be automatically reset through the buckle cover lower supporting plate 67, the problem of non-opening is avoided, the buckle cover negative pressure absorption lower top 68 is used for absorbing, pressing and blowing and loosening, the buckle cover swing bent arm 69, the buckle cover hinge part 70, the buckle cover first guide groove 71, the buckle cover front baffle driving arm 72, the buckle cover guide post 73, the buckle cover linkage pin 74 and the buckle cover process bent arm 75 are linked to realize the opening and closing control of the buckle cover front baffle arm 76, the buckle cover magnetic seat 77 is used for realizing magnetic attraction and positioning, and the buckle cover guide conical surface 79 is used for realizing the guide function.

The invention realizes electric control, the spiral conveying device 2 realizes driving by gravity sliding downwards or pushing by a mechanical arm, and the like, the buckle cover feeding device 3, the waste discharging device 4, the output separating device 5 can be expanded into auxiliary processes of packaging, weighing, marking, and the like, the waste discharging downwards presses the driving shaft part 52, the waste discharging eccentric pressing head 53, the waste discharging downwards opens and closes the opposite door 54, the waste discharging output part 55 realizes automatic separation, and compared with electronic control, the cost is saved, the outlet turning driving part 56, the outlet forward stirring gear shaft 57, the outlet turning gear set 58, the outlet reverse stirring gear shaft 59 and the outlet stirring arm 60 realize automatic involution output materials.

The present invention is fully described for more clarity of disclosure and is not set forth in the prior art.

Finally, it should be noted that: the above embodiments are only for illustrating the technical solution of the present invention, and are not limiting; although the invention has been described in detail with reference to the foregoing embodiments, it will be understood by those of ordinary skill in the art that: the technical scheme described in the foregoing embodiments can be modified or some of the technical features thereof can be replaced by equivalents; it is obvious to a person skilled in the art to combine several embodiments of the invention. Such modifications and substitutions do not depart from the spirit and scope of the technical solutions of the embodiments of the present invention.

Claims (3)

1. An electronic accessory linkage conveying equipment which is characterized in that: comprises a screw conveyor (2); a waste discharge device (4) is arranged at a waste discharge station on a spiral channel of the spiral conveying device (2); the waste discharge station is positioned before the cover buckling station;

the waste discharge device (4) comprises a waste discharge pressing driving shaft part (52) arranged above the spiral channel, and a waste discharge downward opening and closing opposite door (54) is arranged at the bottom of the spiral channel of the waste discharge station; an input end of a waste discharge output part (55) is arranged below the waste discharge downward opening and closing opposite door (54);

a waste discharge eccentric pressure head (53) is eccentrically arranged on the waste discharge pressing driving shaft part (52) and is intermittently contacted with the upper surface of a box at a waste discharge station to detect whether the box is opened upwards and push the box with the bottom upwards downwards, and the waste discharge pressing driving shaft part pushes the waste discharge pressing driving shaft part to open and close a counter door (54) downwards, so that the box with the opening downwards enters the input end of a waste discharge output part (55).

2. The electronic accessory linkage conveying apparatus according to claim 1, wherein: an output separating device (5) is arranged at the output station of the spiral conveying device (2);

the output separating device (5) comprises an outlet turning driving part (56) arranged at the output station; the outlet turning driving part (56) is meshed with an outlet forward stirring gear shaft (57) through a gear, and the outlet turning driving part (56) is indirectly meshed with an outlet reverse stirring gear shaft (59) through an outlet turning gear set (58) serving as an intermediate gear shaft;

the structure of the outlet forward shifting gear shaft (57) is the same as that of the outlet reverse shifting gear shaft (59), the steering directions are opposite, and the outlet forward shifting gear shaft (57) and the outlet reverse shifting gear shaft (59) are respectively provided with an outlet shifting arm (60) which rotates oppositely so as to output boxes at the output station one by one.

3. The electronic accessory linkage conveying apparatus according to claim 2, wherein: a buckle cover feeding device (3) is arranged at the buckle cover feeding station of the spiral conveying device (2); the buckle cover feeding device (3) is positioned behind the waste discharge device (4);

the waste discharge downward-pressing driving shaft part (52), the outlet turning driving part (56) and the cover turning output part (64) of the cover feeding device (3) are arranged in a linkage way.