CN112047115A - Automatic stacking process for cable bridge production and processing - Google Patents

Abstract

The invention belongs to the technical field of cable bridges, and particularly relates to an automatic stacking process for producing and processing cable bridges, which comprises the following steps: (1) continuously conveying the cut cable bridge to a turnover mechanism; (2) the cable bridge falls on the turnover mechanism firstly, falls on the stacking mechanism in a forward direction, falls on the cable bridge on the turnover mechanism, is turned over by the turnover mechanism, and then falls on the stacking mechanism in a reverse direction; (3) after the positive and negative cable bridges are mutually clamped, the cable bridges are orderly stacked on the collecting plate through the stacking mechanism; (4) and (3) continuing the subsequent cable bridge according to the steps (2) and (3), so that the automatic stacking of the cable bridge is realized, the cable bridge can automatically enter the turnover plate in the stacking groove, the stacking automation is realized, and the efficiency is higher.

Description

Automatic stacking process for cable bridge production and processing

Technical Field

The invention belongs to the technical field of cable bridges, and particularly relates to an automatic stacking process for producing and processing cable bridges.

Background

The cable bridge is a rigid structure system which is formed by groove type, tray type or ladder type straight line sections, bend-through, tee joints and four-way components, a supporting arm (arm type support), a hanger and the like and is used for tightly connecting and supporting a cable, and the rigid structure system is called as the cable bridge (the bridge for short).

The cable bridge is divided into structures of a groove type, a tray type, a ladder type, a grid type and the like, and comprises a support, a supporting arm, an installation accessory and the like. The inner bridge frame of the building can be independently erected and can also be attached to various buildings and pipe rack supports, the characteristics of simple structure, attractive appearance, flexible configuration, convenient maintenance and the like are reflected, and all parts need to be galvanized. The bridge frame installed outside the building in open air has the physical characteristics of corrosion resistance, moisture resistance, good adhesive force and high impact strength if the bridge frame is near seaside or belongs to a corrosion area.

The cable testing bridge is most similar with the frame shape of U-shaped, and all is rectangular form, and the finished product of producing and processing need carry out the pile up after cuting, and the current is most adopted the manual work to put two cable testing bridges that the size is the same, and the opening is relative, then crisscross block, forms a similar square whole, then unified pile up the pile up put, the transport, but the finished product that current manual work will cut the completion is taken up then carries out positive and negative mutual stack in proper order, and efficiency is slow.

Disclosure of Invention

Aiming at the problems in the prior art, the invention aims to provide an automatic stacking process for producing and processing a cable bridge.

In order to achieve the purpose, the invention adopts the following technical scheme:

an automatic stacking process for producing and processing a cable bridge comprises the following steps:

(1) continuously conveying the cut cable bridge to a turnover mechanism;

(2) the cable bridge falls on the turnover mechanism firstly, falls on the stacking mechanism in a forward direction, falls on the cable bridge on the turnover mechanism, is turned over by the turnover mechanism, and then falls on the stacking mechanism in a reverse direction;

(3) after the positive and negative cable bridges are mutually clamped, the cable bridges are orderly stacked on the collecting plate through the stacking mechanism;

(4) and (4) continuing the subsequent cable bridge frames according to the steps (2) and (3), thereby realizing the automatic stacking of the cable bridge frames.

Preferably, tilting mechanism puts things in good order the platform including putting things in good order, it puts things in good order the bench and is equipped with the groove of putting things in good order, put things in good order the groove for the through type, and put things in good order the inslot and be equipped with the swivelling chute, be equipped with rotatable rotatory piece in the swivelling chute, be equipped with the constant head tank of through type in the rotatory piece, be equipped with symmetric distribution and rotatable returning face plate in the constant head tank both sides wall.

Further, the both ends of rotatory piece are equipped with the pivot of symmetric distribution, the pivot rotates with the corresponding inner wall of swivelling chute to be connected, the platform bottom of putting things in good order is equipped with the rotating electrical machines, the rotating electrical machines output is equipped with the regulating spindle, the regulating spindle is connected with the pivot through first chain.

Furthermore, the both ends of the turnover plate are provided with connecting shafts which are symmetrically distributed, the two ends of each connecting shaft are rotatably connected with the corresponding inner wall of the positioning groove, the connecting shafts are located on the same side, an adjusting groove is formed in the rotating block, the end portions of the connecting shafts are located in the adjusting groove, a second chain connected with the connecting shafts is arranged between the connecting shafts, the second chain is 8-shaped, a turnover motor is arranged in the adjusting groove, and the output end of the turnover motor is connected with one of the connecting shafts.

Preferably, the stacking mechanism comprises a discharge plate and a collecting plate, the discharge plate is located at the bottom of the rotating block, the stacking groove is internally provided with the discharge plate capable of moving up and down, the bottom of the discharge plate is provided with a supporting plate, the supporting plate is provided with two sets of symmetrically distributed hydraulic rods, the end part of each hydraulic rod is rotatably connected with the bottom of the discharge plate, the discharge groove is formed in one side of the discharge plate, and the discharge groove is internally provided with an extension plate which is connected in a sliding manner and can move in a contraction manner.

Furthermore, the bottom of the discharge plate, which is positioned at the bottom of the extension plate, is provided with a communicating groove communicated with the discharge groove, the bottom of the extension plate is internally provided with uniformly distributed racks, and the communicating groove is internally provided with a gear which can rotate and is meshed with the racks.

Furthermore, an extension motor is arranged at the bottom of the discharge plate, an output shaft is arranged at the output end of the extension motor, and the output shaft is fixedly connected with a gear.

Furthermore, a collecting plate for stacking the cable bridges is arranged on one side of the supporting plate positioned at the extending end of the extending plate.

Furthermore, a plurality of uniformly distributed rollers are arranged at the bottom of the collecting plate, the upper surface of the collecting plate is inclined, and one side of the collecting plate is provided with a baffle which is fixedly connected and used for stacking and supporting.

Preferably, the inner wall of the rotary groove is flush with the inner wall of the stacking groove.

Compared with the prior art, the invention has the following technical effects:

the original manual stacking is replaced by machinery, the stacking automation is realized, the efficiency is higher, and the production efficiency is improved.

Drawings

FIG. 1 is a schematic top view of the present invention;

FIG. 2 is a schematic view of a main view of an inner structure of a stacking platform provided by the present invention;

FIG. 3 is a schematic view of a connection structure of a rotary block and a rotary motor according to the present invention;

FIG. 4 is a schematic side view of the connection shaft and the second chain according to the present invention;

FIG. 5 is a schematic side view of the stacking table according to the present invention;

FIG. 6 is a schematic side view of the discharging plate according to the present invention;

FIG. 7 is a schematic view of a connection structure of a discharge plate and an extension plate according to the present invention;

FIG. 8 is a schematic view of a stacked cable tray structure according to the present invention;

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further clarified by combining the specific drawings.

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

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Example 1

Referring to fig. 1-8, an automatic stacking process for cable bridge production includes the following steps:

(1) continuously conveying the cut cable bridge to a turnover mechanism;

(2) the cable bridge falls on the turnover mechanism firstly, falls on the stacking mechanism in a forward direction, falls on the cable bridge on the turnover mechanism, is turned over by the turnover mechanism, and then falls on the stacking mechanism in a reverse direction;

(3) after the positive and negative cable bridges are mutually clamped, the cable bridges are orderly stacked on the collecting plate through the stacking mechanism;

(4) and (4) continuing the subsequent cable bridge frames according to the steps (2) and (3), thereby realizing the automatic stacking of the cable bridge frames.

Further, tilting mechanism is including putting things in good order platform 1, it puts things in good order groove 11 to put things in good order on good order the platform 1, put things in good order groove 11 for the through type, and put things in good order and be equipped with swivel chute 12 in the groove 11, be equipped with rotatable rotatory piece 31 in the swivel chute 12, be equipped with the constant head tank 33 of through type in the rotatory piece 31, be equipped with symmetric distribution and rotatable returning face plate 32 in the both sides wall of constant head tank 33.

The combination of the rotating block and the turnover plate enables the cable bridge to be overturned when being stacked, so that the cable bridge can be automatically stacked up and down when being stacked, and the automatic stacking of the cable bridge is realized, and the cable bridge is rapid and efficient.

Further, rotatory piece 31 both ends are equipped with the pivot 13 of symmetric distribution, pivot 13 rotates with the corresponding inner wall of swivelling chute 12 and is connected, 1 bottom of putting things in good order is equipped with rotating electrical machines 15, the 15 output of rotating electrical machines is equipped with regulating spindle 14, regulating spindle 14 is connected with pivot 13 through first chain 16.

Further, connecting axle 34 that the both ends of returning face plate 32 were equipped with the symmetric distribution, connecting axle 34 both ends are rotated with the corresponding inner wall of constant head tank 33 and are connected, lie in connecting axle 34 with one side be equipped with adjustment tank 36 in the rotatory piece 31, connecting axle 34 tip lies in adjustment tank 36, lies in adjustment tank 36 be equipped with the second chain 37 that is connected between the connecting axle 34, second chain 37 is 8 font, be equipped with upset motor 35 in the adjustment tank 36, upset motor 35 output is connected with one of them connecting axle 34.

Further, the stacking mechanism comprises a discharge plate 43 and a collecting plate 51, and is located at the bottom of the rotating block 31, the discharge plate 43 capable of moving up and down is arranged in the stacking groove 11, a supporting plate 41 is arranged at the bottom of the discharge plate 43, two sets of hydraulic rods 42 symmetrically distributed are arranged on the supporting plate 41, the end of each hydraulic rod 42 is rotatably connected with the bottom of the discharge plate 43, a discharge groove 431 is arranged in one side of the discharge plate 43, and an extension plate 45 which is connected in a sliding manner and can move in a contraction manner is arranged in the discharge groove 431.

Further, a communicating groove 433 communicated with the discharging groove 431 is formed in the bottom of the discharging plate 43 and located at the bottom of the extending plate 45, racks 432 are uniformly distributed in the bottom of the extending plate 45, and a gear 451 which can rotate and is meshed with the racks 432 is arranged in the communicating groove 433.

Further, an extension motor 453 is arranged at the bottom of the discharging plate 43, an output shaft 452 is arranged at the output end of the extension motor 453, and the output shaft 452 is fixedly connected with the gear 451.

Further, a collecting plate 51 for stacking the cable trays is provided at one side of the supporting plate 41 at the extending end of the extending plate 45.

Further, a plurality of rollers 53 which are uniformly distributed are arranged at the bottom of the collecting plate 51, the upper surface of the collecting plate 51 is inclined, and a baffle 52 which is fixedly connected and used for stacking and supporting is arranged on one side of the collecting plate 51. The combination of the inclined design of the upper surface of the collecting plate 51 and the baffle plate 52 enables the cable bridge to be more efficient and rapid when being stacked.

Further, the inner wall of the rotating groove 33 is flush with the inner wall of the stacking groove 11.

Further, be located stacking groove 11 one side be equipped with feed chute 22 on stacking table 1, be equipped with rotatable feed roll 21 in the feed chute 22, feed roll 21 both ends are passed through feed shaft 23 and feed chute 22 swing joint, feed chute 22 one side is equipped with the feeding motor (not marked in the figure), the feeding motor output is connected with feed shaft 21.

The design of the feeding roller 21 ensures that the cable bridge can automatically enter the turnover plate 32 in the stacking groove 11 when the cable bridge is stacked, thereby realizing the automation of stacking and being more efficient.

Further, a plurality of fixedly connected support frames 17 are arranged at the bottom of the stacking platform 1.

The invention is used for the automatic stacking process for producing and processing the cable bridge, and when in use:

(1) the cut cable bridge moves to the upper end of the feeding roller 21, and the cable bridge moves towards the stacking groove 11 through the rotation of the feeding roller 21;

(2) when the cable bridge completely moves into the stacking groove 11, the cable bridge completely falls on the turnover plate 32, the turnover motor 32 is started to enable the turnover plate 32 to synchronously rotate downwards, the cable bridge falls on the discharging plate 43 in the positive direction due to gravity, and then the turnover motor 35 is started to enable the turnover plate 32 to recover the initial position to wait for the next cable bridge to enter;

(3) after the next cable bridge enters and the cable bridge completely falls on the turnover plate 32, the rotating motor 15 is started to enable the rotating block 31 to rapidly rotate 180 degrees and stop, the cable bridge also rotates 180 degrees, the cable bridge inevitably automatically falls on the previous cable bridge in a reverse direction due to gravity, and therefore the two cable bridges are overlapped in a vertically staggered mode, and after the cable bridge falls, the rotating block 31 is enabled to restore to the initial position to wait for the next cable bridge through the rotating motor 15;

(4) meanwhile, the discharging plate 43 is descended through the hydraulic rod 42, the discharging plate 43 can be inclined by controlling the descending heights of the symmetrical hydraulic rods 42, the superposed cable bridge can automatically slide downwards, and the position of the superposed cable bridge sliding downwards can be controlled by controlling the extending length of the extending plate 45;

(5) through the mutual combination of the descending height of the discharging plate 43, the inclination angle of the discharging plate 43 and the extension length of the extension plate 45, each group of stacked cable bridges can automatically slide to any position on the collecting plate 51, and therefore the orderly stacking of the stacked cable bridges is realized.

The foregoing shows and describes the general principles, essential features, and inventive features of this invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. The automatic stacking process for producing and processing the cable bridge is characterized by comprising the following steps of: the method comprises the following steps:

(1) continuously conveying the cut cable bridge to a turnover mechanism;

(2) the cable bridge falls on the turnover mechanism firstly, falls on the stacking mechanism in a forward direction, falls on the cable bridge on the turnover mechanism, is turned over by the turnover mechanism, and then falls on the stacking mechanism in a reverse direction;

(3) after the positive and negative cable bridges are mutually clamped, the cable bridges are orderly stacked on the collecting plate through the stacking mechanism;

(4) and (4) continuing the subsequent cable bridge frames according to the steps (2) and (3), thereby realizing the automatic stacking of the cable bridge frames.

2. The automatic stacking process for producing and processing the cable bridge as claimed in claim 1, wherein: the turnover mechanism comprises a stacking platform, wherein a stacking groove is formed in the stacking platform and is of a through type, a rotating groove is formed in the stacking groove, a rotatable rotating block is arranged in the rotating groove, a through type positioning groove is formed in the rotating block, and symmetrical distribution and rotatable turnover plates are arranged in two side walls of the positioning groove.

3. The automatic stacking process for producing and processing the cable bridge as claimed in claim 2, wherein: the stacking mechanism comprises a discharge plate and a collecting plate, the discharge plate is located at the bottom of the rotating block, the stacking groove is internally provided with the discharge plate capable of moving up and down, the bottom of the discharge plate is provided with a supporting plate, the supporting plate is provided with two sets of symmetrically distributed hydraulic rods, the end part of each hydraulic rod is rotatably connected with the bottom of the discharge plate, the discharge groove is formed in one side of the discharge plate, and the discharge groove is internally provided with an extension plate which is connected in a sliding manner and can move in a contraction manner.

4. The automatic stacking process for producing and processing the cable bridge as claimed in claim 3, wherein: the discharging plate bottom is provided with a communicating groove communicated with the discharging groove, the extending plate bottom is internally provided with uniformly distributed racks, and the communicating groove is internally provided with a gear which can rotate and is meshed with the racks.

5. The automatic stacking process for producing and processing the cable bridge as claimed in claim 4, wherein: the bottom of the discharging plate is provided with an extension motor, the output end of the extension motor is provided with an output shaft, and the output shaft is fixedly connected with a gear.

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