CN219151309U - Umbrella rib inner tube processing device - Google Patents

Abstract

The utility model discloses an umbrella rib inner tube processing device which comprises a machine table, wherein a processing channel for enabling an umbrella rib inner tube to flow is arranged on the machine table, a feeding component and a receiving hopper are respectively arranged at two ends of the processing channel, a first reduction shrinkage pipe component, a profiling punching component and a chamfering component are sequentially arranged on the machine table along the direction from the feeding component to the receiving hopper, the first reduction shrinkage pipe component is used for reducing, correcting and shrinking round tubes at two ends of the umbrella rib inner tube, and a conveying component is arranged on the machine table and used for conveying the umbrella rib inner tube among the feeding component, the first reduction shrinkage pipe component, the profiling punching component, the chamfering component and the receiving hopper. This application is through setting up reduction pipe subassembly, reduces the correction to the deformation that appears on the rib inner tube for follow-up processing procedure can be better go on, has guaranteed the processingquality of rib middle tube, thereby has improved the qualification rate of product, and then has guaranteed machining efficiency, has reduced the loss that causes because of the defective products is too much in the production.

Description

Umbrella rib inner tube processing device

Technical Field

The utility model relates to the technical field of umbrella rib processing, in particular to an umbrella rib inner tube processing device.

Background

The umbrella is an indispensable common tool in daily life, and mainly comprises structures such as umbrella rib middle bars, umbrella frames and cloth. With the continuous progress of society, the processing requirement of rib stick is also higher and higher, and rib stick generally includes outer tube, well pipe and inner tube. In the process of processing the inner pipe, the inner pipe is usually subjected to operations such as pipe shrinkage and shaping, and the like, and due to higher and higher processing requirements, the pipe orifice of some pipes can deform in the transportation process, such as the situation of sinking, and the like, so that the subsequent processing is unfavorable, the deformation needs to be reduced and corrected in advance, and the qualification rate of the products is not seriously affected.

Disclosure of Invention

Aiming at the defects of the prior art, the utility model provides an umbrella rib inner tube processing device.

The utility model discloses an umbrella rib inner tube processing device, which comprises:

the machine is provided with a processing channel for communicating the umbrella rib middle pipe;

the feeding components and the receiving hoppers are respectively arranged at two ends of the processing channel;

the first reduction pipe assembly, the profiling punching assembly and the chamfering assembly are sequentially arranged on the machine table along the direction from the feeding assembly to the receiving hopper;

the first reduction pipe shrinkage component is used for reducing, correcting and shrinking round pipes at two ends of the umbrella rib inner pipe;

the profiling punching assembly is used for profiling and punching two ends of the umbrella rib inner tube;

the conveying assembly is arranged on the machine table and used for conveying the umbrella rib middle pipe among the feeding assembly, the first reduction pipe shrinking assembly, the profiling punching assembly, the chamfering assembly and the receiving hopper.

Preferably, the feeding assembly comprises a material storage mechanism and a pushing mechanism;

the material storage mechanism comprises a material rack and a material guide channel arranged in the material rack, the material rack is arranged on a machine table, the material guide channel extends from the top end of the material rack to the bottom end of the material rack, the material guide channel comprises a material guide front end and a material guide rear end, the material guide front end is used for bearing pipes, and the material guide rear end is used for arranging the pipes;

the pushing mechanism comprises a first mounting seat arranged on the machine table, a first linear driving part arranged on the first mounting seat, a first sliding seat arranged at the output end of the first linear driving part and in sliding connection with the machine table, and a first bearing plate arranged on the first sliding seat, wherein the first bearing plate is positioned below the material rack, a groove is formed in the front end of the first bearing plate, and the pipe flows into the groove from the rear end of the material guide and is pushed out by the first linear driving part.

Preferably, the first reduction pipe assembly comprises a reduction mechanism and a pipe reduction mechanism which are oppositely arranged at two sides of the processing channel;

the reduction mechanism comprises a second mounting seat arranged on the machine table, a second linear driving part arranged on the second mounting seat, a first sliding seat which is connected on the machine table in a sliding manner and is connected with the output end of the second linear driving part, a second bearing plate arranged on the machine table, and a reduction mold core penetrating through the second bearing plate, wherein one end of the reduction mold core penetrates through the second bearing plate and is connected with the first sliding seat, the outer side wall of the reduction mold core is attached to the inner side wall of the umbrella rib middle pipe, and the reduction mold core moves back and forth towards the processing channel under the action of the second linear driving part;

the pipe shrinking mechanism comprises a third mounting seat arranged on the machine table, a third linear driving part arranged on the third mounting seat, a pipe shrinking mold core arranged at the output end of the third linear driving part and a third bearing plate arranged on the machine table, wherein the pipe shrinking mold core is slidably connected to the third bearing plate, a circular pipe inner core is arranged in a cavity of the pipe shrinking mold core, and the pipe shrinking mold core moves back and forth towards the processing channel under the action of the third linear driving part.

Preferably, the profiling punching assembly comprises profiling mechanisms and punching mechanisms which are oppositely arranged at two sides of the processing channel;

the profiling mechanism comprises a fourth mounting seat arranged on the machine table, a fourth linear driving part arranged on the fourth mounting seat, a first fixing seat arranged on the machine table, a second sliding seat connected to the first fixing seat in a sliding manner, a first mounting plate arranged on the machine table, a profiling mold arranged on the first mounting plate, and a profiling inner core arranged at one end of the second sliding seat, wherein a die orifice of the profiling mold faces to the processing channel, one end of the profiling inner core penetrates through the first mounting plate and stretches into a cavity of the profiling mold, and the profiling inner core moves back and forth towards the cavity of the profiling mold under the action of the fourth linear driving part;

the punching mechanism comprises a fifth mounting seat arranged on the machine table, a fifth linear driving part arranged on the fifth mounting seat, a third sliding seat arranged at the output end of the fifth linear driving part and in sliding connection with the machine table, a fourth bearing plate arranged on the third sliding seat, and a punching die arranged on the fourth bearing plate, wherein a die opening of the punching die is opposite to a die cavity of the profiling die, and the punching die moves back and forth towards a processing channel under the action of the fifth linear driving part.

Preferably, the profiling mold comprises a first top plate and a first bottom plate which are respectively arranged at the top and the bottom of the first mounting plate, a first upper mold which is connected to the side surface of the first mounting plate in a sliding manner, a first lower mold which is arranged on the first bottom plate and opposite to the first upper mold, and a sixth linear driving part which is arranged on the first top plate, wherein the output end of the sixth linear driving part extends downwards and is connected with the first upper mold, the side surface of the first upper mold opposite to the first lower mold is provided with a cavity groove, the first upper mold moves upwards and downwards under the driving of the sixth linear driving part, and the first upper mold and the first lower mold are matched with the cavity groove to form a cavity.

Preferably, the punching die comprises four first guide posts vertically arranged at four corners of the top of the fourth bearing plate, a second top plate arranged at the top of the first guide posts, a seventh linear driving part arranged on the second top plate, a first lifting plate movably sleeved on the outer side of the first guide posts, a punching knife arranged at the bottom of the first lifting plate, a first die holder arranged on the fourth bearing plate, a first die core arranged on the first die holder and provided with punching holes, wherein the output end of the seventh linear driving part extends downwards and is connected with the second lifting plate, and the punching knife moves back and forth towards the punching holes of the first die core under the action of the seventh linear driving part.

Preferably, the chamfering assembly comprises a chamfering mechanism and a positioning mechanism which are oppositely arranged at two sides of the processing channel;

the chamfering mechanism comprises a sixth mounting seat arranged on the machine table, an eighth linear driving part arranged on the sixth mounting seat, a fourth sliding seat connected to the machine table in a sliding way, a second mounting plate arranged on the machine table, a compaction die arranged on the second mounting plate, a rotating part arranged on the fourth sliding seat and a chamfering die core arranged at the output end of the rotating part, wherein one end of the chamfering die core penetrates through the second mounting plate and stretches into a cavity of the compaction die, and the chamfering die core moves back and forth towards the cavity of the compaction die under the action of the eighth linear driving part;

the positioning mechanism comprises a seventh mounting seat arranged on the machine table, a ninth linear driving part arranged on the seventh mounting seat, a fifth bearing plate arranged on the machine table and a positioning rod penetrating through the fifth bearing plate, wherein one end of the positioning rod is connected with the output end of the ninth linear driving part, and the other end of the positioning rod is opposite to the cavity of the compaction grinding tool.

Preferably, the compaction die comprises a third top plate and a second bottom plate which are respectively arranged at the top and the bottom of the second mounting plate, a second upper die which is connected to the side surface of the second mounting plate in a sliding manner, a second lower die which is arranged on the second bottom plate and opposite to the second upper die, and a tenth linear driving part which is arranged on the third top plate, wherein the output end of the tenth linear driving part extends downwards and is connected with the second upper die, the opposite side surfaces of the second upper die and the second lower die are respectively provided with a cavity groove, the second upper die moves up and down towards the second lower die under the driving of the tenth linear driving part, and the second upper die and the second lower die are matched with each other to form a cavity.

Preferably, the delivery assembly comprises:

the rack is arranged on the machine table, and the top of the rack extends to the position right above the processing channel;

the third mounting plate is arranged at the top of the rack;

an eleventh linear driving section provided on a side surface of the third mounting plate;

the fifth sliding seat is horizontally and slidably connected to the side surface of the third mounting plate, and one side of the fifth sliding seat is in transmission connection with the output end of the eleventh linear driving part;

a twelfth linear driving part, which is arranged on the fifth sliding seat, and the output end of which extends upwards;

a fourth top plate provided at an output end of the twelfth linear driving part;

one end of the second guide column is connected with the bottom of the fourth top plate, and the other end of the second guide column penetrates through the fifth sliding seat and extends downwards;

the supporting plate is arranged at the bottom of the second guide column, and the arrangement direction of the supporting plate is consistent with the length direction of the processing channel;

the clamping parts are arranged in a plurality of mode, and the clamping parts are arranged at intervals at the bottom of the supporting plate.

Preferably, a second reduction pipe assembly is arranged between the profiling punching assembly and the chamfering assembly and is used for reducing and shrinking the profiling punched rib inner pipe.

The beneficial effects of this application lie in: through setting up reduction pipe subassembly, reduce the correction to the deformation that appears on the rib inner tube for follow-up processing procedure can be better go on, the processingquality of pipe in the rib has been guaranteed, thereby has improved the qualification rate of product, and then has guaranteed machining efficiency, has reduced the loss that causes because of the defective products is too much in the production.

Drawings

The accompanying drawings, which are included to provide a further understanding of the application and are incorporated in and constitute a part of this application, illustrate embodiments of the application and together with the description serve to explain the application and do not constitute an undue limitation to the application. In the drawings:

FIG. 1 is a schematic view of a device for processing a tube in an umbrella rib according to the present embodiment;

FIG. 2 is a schematic view of a feeding assembly of the rib-in-tube processing apparatus according to the present embodiment;

FIG. 3 is a schematic view of a first reducer assembly of the rib-in-rib tube processing apparatus according to the present embodiment;

FIG. 4 is a schematic diagram of a press-type punching assembly of the rib-in-tube processing apparatus according to the present embodiment;

FIG. 5 is a schematic diagram of a press mechanism of the umbrella rib middle tube processing device of the present embodiment;

FIG. 6 is a schematic diagram showing the structure of a punching mechanism of the rib-in-tube processing apparatus according to the present embodiment;

FIG. 7 is an enlarged schematic view of FIG. 6A according to the present embodiment;

FIG. 8 is a schematic view showing the structure of a chamfering assembly of the umbrella rib-in-tube processing apparatus according to the present embodiment;

FIG. 9 is a schematic diagram showing the structure of a conveying assembly of the rib-in-tube processing apparatus according to the present embodiment.

Detailed Description

Various embodiments of the utility model are disclosed in the following drawings, in which details of the practice are set forth in the following description for the purpose of clarity. However, it should be understood that these practical details are not to be taken as limiting the utility model. That is, in some embodiments of the utility model, these practical details are unnecessary. Moreover, for the sake of simplicity of the drawing, some well-known and conventional structures and elements are shown in the drawings in a simplified schematic manner.

It should be noted that all directional indications such as up, down, left, right, front, and rear … … in the embodiments of the present utility model are merely used to explain the relative positional relationship, movement, etc. between the components in a particular posture such as that shown in the drawings, and if the particular posture is changed, the directional indication is changed accordingly.

In addition, the descriptions of the "first", "second", etc. in this application are for descriptive purposes only and are not intended to specifically indicate a sequential or a cis-position, nor are they intended to limit the utility model, but are merely intended to distinguish between components or operations described in the same technical term, and are not to be construed as indicating or implying a relative importance or implying that the number of technical features indicated is not necessarily limited. Thus, a feature defining "a first" or "a second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions of the embodiments may be combined with each other, but it is necessary to base that the technical solutions can be realized by those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should be considered to be absent and not within the scope of protection claimed in the present utility model.

For a further understanding of the utility model, its features and advantages, reference is now made to the following examples, which are illustrated in the accompanying drawings in which:

reference is made to fig. 1. The umbrella rib inner tube processing device in the embodiment comprises a machine table 1, wherein a processing channel for communicating an umbrella rib inner tube is arranged on the machine table 1; the feeding components 2 and the receiving hoppers 3 are respectively arranged at two ends of the processing channel; the first reduction pipe assembly 4, the profiling punching assembly 5 and the chamfering assembly 6 are arranged on the machine table 1 in sequence along the direction from the feeding assembly 2 to the receiving hopper 3; the first reduction pipe assembly 4 is used for reducing, correcting and shrinking round pipes at two ends of the umbrella rib inner pipe; the profiling punching assembly 5 is used for profiling and punching two ends of the rib inner tube, and is arranged on the machine table 1 and used for conveying the rib inner tube among the feeding assembly 2, the first reduction shrinkage tube assembly 4, the profiling punching assembly 5, the chamfering assembly 6 and the receiving hopper 3.

During operation, firstly, the feeding component 2 conveys the rib inner tube to the material taking position, meanwhile, after the processing of the rib inner tubes on other stations is completed, then the conveying component 7 takes out the rib inner tube on each station and synchronously conveys the rib inner tube to the next station, wherein the first reduction pipe reducing component 4 reduces one end of the rib inner tube, corrects a deformed surface and reduces the other end of the rib inner tube, the compression type punching component 5 compresses the end of the reduced rib inner tube into a regular hexagon, punches the end after the pipe reduction, the chamfering component 6 chamfer the end of the compressed rib inner tube, and finally the rib inner tube is uniformly conveyed into the material receiving hopper 3 by the conveying component 7. The processing device in this embodiment carries out the reduction operation to the rib inner tube before processing it for follow-up processing procedure can be better go on, follow-up processing's quality and the qualification rate of product have been guaranteed, and then production efficiency has been improved.

Referring to fig. 2, the feeding assembly 2 includes a stock mechanism 21 and a pushing mechanism 22. The stock mechanism 21 includes a material rack 211 and a material guiding channel 212 arranged in the material rack 211, the material rack 211 is arranged on the machine, the material guiding channel 212 extends from the top end of the material rack 211 to the bottom end of the material rack 211, the material guiding channel 212 includes a material guiding front end 2121 and a material guiding rear end 2122, the material guiding front end 2121 is used for bearing pipes, and the material guiding rear end is used for arranging the pipes 2122. The pushing mechanism 22 comprises a first mounting seat 221 arranged on the machine 1, a first linear driving part 222 arranged on the first mounting seat 221, a first sliding seat 223 arranged at the output end of the first linear driving part 222 and connected with the machine 1 in a sliding way, and a first bearing plate 224 arranged on the first sliding seat 223, wherein the first bearing plate 224 is positioned below the material rack 211, a groove 2241 is arranged at the front end of the first bearing plate 224, and a pipe flows into the groove 2241 from the rear end 2122 of the material guiding and is pushed out through the first linear driving part 222.

In the initial state, the rib inner tubes are all stacked in the material guiding channel 212, and the channel width of the material guiding rear end 2122 is matched with the diameter of the rib inner tubes, so that only one middle tube falls into the groove 2241 at a time, and then is pushed out to the material taking position by the first linear driving part 222, and is further sent to the next station by the conveying assembly 7.

Referring to fig. 3, the first reducing tube assembly 4 includes a reducing mechanism 41 and a reducing mechanism 42 disposed opposite to each other on two sides of the processing channel.

The reduction mechanism 41 comprises a second mounting seat 411 arranged on the machine table 1, a second linear driving part 412 arranged on the second mounting seat 411, a first sliding seat 413 which is connected with the output end of the second linear driving part 412 in a sliding manner and is arranged on the machine table 1, a second bearing plate 414 arranged on the machine table 1, and a reduction mold core 415 penetrating through the second bearing plate 414, wherein one end of the reduction mold core 415 penetrates through the second bearing plate 414 and is connected with the first sliding seat 413, the outer side wall of the reduction mold core 415 is attached to the inner side wall of the umbrella rib middle tube, and the reduction mold core 415 moves back and forth to a processing channel under the action of the second linear driving part 412.

The shrinking mechanism 42 comprises a third mounting seat 421 arranged on the machine table 1, a third linear driving part 422 arranged on the third mounting seat 421, a shrinking mold core 423 arranged at the output end of the third linear driving part 422 and a third bearing plate 424 arranged on the machine table 1, wherein the shrinking mold core 423 is slidably connected to the third bearing plate 424, a circular pipe inner core 4231 is arranged in a cavity of the shrinking mold core 423, and the shrinking mold core 423 moves back and forth towards a processing channel under the action of the third linear driving part 422.

When the conveying component 7 conveys the rib inner tube to the processing position of the reduction pipe component 4, the second linear driving part 412 is started to drive the reduction mold core 415 to move towards the direction of the rib inner tube, so that one end of the reduction mold core is inserted into the rib inner tube to repair the deformed position, meanwhile, the third linear driving part 422 moves the pipe reduction mold core 423 towards the direction of the rib inner tube, so that the other end of the rib inner tube is inserted into the pipe reduction mold core 423, pipe reduction is carried out on the rib inner tube, after the reduction and pipe reduction process is completed, the conveying component 7 clamps the rib inner tube, each linear driving part is reset, and then the conveying component 7 conveys the processed rib inner tube to the next process. In this embodiment, the circular tube inner core 4231 ensures that the inner wall of the rib inner tube is always circular in the shrinking process, and deformation is not generated.

Referring to fig. 4, the profiling punch assembly 5 includes profiling mechanisms 51 and punching mechanisms 52 disposed opposite to each other on both sides of the processing channel.

The profiling mechanism 51 comprises a fourth mounting seat 511 arranged on the machine table 1, a fourth linear driving part 512 arranged on the fourth mounting seat 511, a first fixed seat 513 arranged on the machine table 1, a second sliding seat 514 connected to the first fixed seat 513 in a sliding manner, a first mounting plate 515 arranged on the machine table 1, a profiling die 516 arranged on the first mounting plate 515, and a profiling inner core 517 arranged at one end of the second sliding seat 514, wherein a die orifice of the profiling die 516 faces to a processing channel, one end of the profiling inner core 517 penetrates through the first mounting plate 515 and stretches into a cavity of the profiling die 516, and the profiling inner core 517 moves back and forth towards the cavity of the profiling die 516 under the action of the fourth linear driving part 512.

The punching mechanism 52 includes a fifth mounting seat 521 provided on the machine 1, a fifth linear driving portion 522 provided on the fifth mounting seat 521, a third sliding seat 523 provided at an output end of the fifth linear driving portion 522 and slidably connected to the machine 1, a fourth bearing plate 524 provided on the third sliding seat 523, and a punching die 525 provided on the fourth bearing plate 524, wherein a die opening of the punching die 525 is opposite to a cavity of the profiling die 516, and the punching die 525 moves back and forth to the processing channel under the action of the fifth linear driving portion 522.

Referring to fig. 5, the pressing mold 516 includes a first top plate 5161 and a first bottom plate 5162 respectively disposed at the top and bottom of the first mounting plate 515, a first upper mold 5163 slidably connected to a side surface of the first mounting plate 515, a first lower mold 5164 disposed on the first bottom plate 5162 and opposite to the first upper mold 5163, and a sixth linear driving portion 5165 disposed on the first top plate 5161, wherein an output end of the sixth linear driving portion 5165 extends downward and is connected to the first upper mold 5163, cavity slots are disposed on opposite sides of the first upper mold 5163 and the first lower mold 5164, and the first upper mold 5163 moves up and down toward the first lower mold 5164 under the driving of the sixth linear driving portion 5165, and the two cavity slots cooperate to form a cavity when the first upper mold 5163 is pressed against the first lower mold 5164.

In this embodiment, the cross section of the shaping core 517 is hexagonal, the cross section of the cavity of the shaping mold 516 is also hexagonal, and during shaping, the first upper mold 5163 is driven by the six-line driving part 5165 to move downward to press the first upper mold and the first lower mold 5164 together, so that the inner rib tube is shaped, and due to the action of the shaping core 517, the cross sections of the inner wall and the outer wall of the inner rib tube are hexagonal, so that smooth shaping is ensured.

Preferably, the top of the first lower die 5164 is provided with a positioning column 51641, and the bottom of the first upper die 5163 is provided with a positioning hole matched with the positioning column 51641, so that the upper and lower dies can be ensured to always move up and down in the compression process, and no axial offset is generated.

Referring to fig. 6, the punching die 525 includes four first guide posts 5251 vertically disposed at four corners of the top of the fourth bearing plate 524, a second top plate 5252 disposed at the top of the first guide posts 5251, a seventh linear driving portion 5253 disposed on the second top plate 5252, a first lifting plate 5254 movably sleeved on the outer side of the first guide posts 5251, a punching blade 5255 disposed at the bottom of the first lifting plate 5254, a first die holder 5256 disposed on the fourth bearing plate 524, a first die core 5257 disposed on the first die holder 5256 and provided with a punching hole, wherein the output end of the seventh linear driving portion 5253 extends downward and is connected with the second lifting plate 5254, and the punching blade 5255 moves back and forth towards the punching hole of the first die core 5257 under the action of the seventh linear driving portion 5253.

During punching, the punching blade 5255 moves downward under the action of the seventh linear driving portion 5253 to punch the rib inner tube, and the punched fragments flow out from the notch on the punching bottom machine 1.

Referring to fig. 7, in the present embodiment, a spring post 52541 is provided at the bottom of the first lifting plate 5254, a pressing plate 52542 is provided at the bottom of the spring post 52541, and when punching an inner rib tube, the pressing plate 52542 first contacts the inner rib tube and cooperates with the first die holder 5256 to compress the inner rib tube, so that the inner rib tube is stable and does not deviate during punching, and punching accuracy is ensured.

Referring to fig. 8, the chamfering unit 6 includes a chamfering mechanism 61 and a positioning mechanism 62 disposed opposite to each other on both sides of the processing passage.

The chamfering mechanism 61 comprises a sixth mounting seat 611 arranged on the machine table 1, an eighth linear driving part 612 arranged on the sixth mounting seat 611, a fourth sliding seat 613 which is connected on the machine table 1 in a sliding way, a second mounting plate 614 arranged on the machine table 1, a compacting die 615 arranged on the second mounting plate 614, a rotating part 616 arranged on the fourth sliding seat 613, and a chamfering die core 617 arranged at the output end of the rotating part 616, wherein one end of the chamfering die core 617 passes through the second mounting plate 614 and stretches into a cavity of the compacting die 615, and the chamfering die core 617 moves back and forth towards the cavity of the compacting die 615 under the action of the eighth linear driving part 612.

The positioning mechanism 62 comprises a seventh mounting seat 621 arranged on the machine 1, a ninth linear driving part 622 arranged on the seventh mounting seat 621, a fifth bearing plate 623 arranged on the machine 1, and a positioning rod 624 penetrating through the fifth bearing plate 623, wherein one end of the positioning rod 624 is connected with the output end of the ninth linear driving part 622, and the other end is opposite to the cavity of the compaction grinding tool 616. During positioning, the ninth linear driving part 622 drives the positioning rod 624 to move so as to be abutted against the inner tube of the umbrella rib.

Preferably, the compacting mold 615 includes a third top plate 6151 and a second bottom plate 6152 respectively disposed at the top and bottom of the second mounting plate 614, a second upper mold 6153 slidingly connected to a side surface of the second mounting plate 615, a second lower mold 6154 disposed on the second bottom plate 6152 and opposite to the second upper mold 6153, and a tenth linear driving portion 6155 disposed on the third top plate 6151, wherein an output end of the tenth linear driving portion 6155 extends downward and is connected to the second upper mold 6153, a side surface of the second upper mold 6153 opposite to the second lower mold 6154 is provided with a cavity groove, and the second upper mold 6153 moves up and down toward the second lower mold 6154 under the driving of the tenth linear driving portion 6155, and the two cavity grooves cooperate to form a cavity when the second upper mold 6153 is pressed with the second lower mold 6154.

The pressing die 615 operates in the same manner as the pressing die 516 and is not described in detail herein.

The rotating part 616 comprises a transmission motor 6161 arranged at the top of the fourth sliding seat 614, a transmission wheel 6162 arranged on the output shaft of the transmission motor 6161, a driven wheel 6163 arranged on the side surface of the fourth sliding seat 614, wherein the transmission wheel 6162 is in transmission connection with the driven wheel 6163 through a transmission belt, and the chamfering mold core 617 is arranged on the driven wheel 6163. The chamfering mold core 617 is driven to rotate in a transmission mode of the transmission belt, so that chamfering of the umbrella rib inner tube is achieved, the principle is simple, and implementation is easy.

Referring to fig. 9, the conveying assembly 7 includes a frame 71, a third mounting plate 72, an eleventh linear driving portion 73, a fifth sliding seat 74, a twelfth linear driving portion 75, a fourth top plate 76, a second guide post 77, a support plate 78, and a clamping portion 79. The frame 71 is disposed on the machine 1, the top of the frame extends to a position right above the processing channel, the third mounting plate 72 is disposed at the top of the frame 71, the eleventh linear driving portion 73 is disposed on a side surface of the third mounting plate 72, the fifth sliding seat 74 is horizontally slidably connected to a side surface of the third mounting plate 72, one side of the fifth sliding seat is in transmission connection with an output end of the eleventh linear driving portion 73, the twelfth linear driving portion 75 is disposed on the fifth sliding seat 74, an output end of the twelfth linear driving portion extends upward, the fourth top plate 76 is disposed at an output end of the twelfth linear driving portion 75, one end of the second guide post 77 is connected with a bottom of the fourth top plate 76, the other end of the second guide post extends downward through the fifth sliding seat 74, the supporting plate 78 is disposed at a bottom of the second guide post 77, a setting direction of the supporting plate is consistent with a length direction of the processing channel, the clamping portions 79 are disposed in a plurality, and the plurality of clamping portions 79 are disposed at intervals at a bottom of the supporting plate 78.

In this embodiment, the clamping portion 79 includes two oppositely disposed first clamping plates 791 and second clamping plates 792 and a thirteenth linear driving portion 793, the first clamping plates 791 can slide relative to the second clamping plates 792, and an output end of the thirteenth linear driving portion 793 is connected to the first clamping plates 791 and is used for driving the first clamping plates 791 to move relative to the second clamping plates 792, so as to clamp the outer tube, and an arc-shaped slot is disposed between the first clamping plates 791 and the second clamping plates 792, so that the outer tube can be clamped better.

Preferably, a second reduction pipe assembly 8 is arranged between the profiling punching assembly 5 and the chamfering assembly 6, and the second reduction pipe assembly 8 is used for reducing and shrinking the profiling punched rib inner pipe. The structure of the second reduction pipe assembly 8 is the same as that of the first reduction pipe assembly 4, and the reduction pipe assembly can restore the inner pipe after the compression punching once again, so that the inner pipe can better meet the requirements.

In this embodiment, a pair of guiding optical axes are disposed between the bearing plate and the corresponding mounting seat, and the guiding optical axes pass through the corresponding sliding seat, so as to provide guidance for the movement of the sliding seat.

In this embodiment, the linear driving portion is one of a cylinder, an oil cylinder, and an electric push rod.

To sum up: through setting up reduction pipe assembly 4, reduce the correction to the deformation that appears on the rib inner tube for follow-up processing procedure can be better go on, the processingquality of pipe in the rib has been guaranteed, thereby has improved the qualification rate of product, and then has guaranteed machining efficiency, has reduced the loss that causes because of the defective products is too much in the production.

The foregoing description is only illustrative of the utility model and is not to be construed as limiting the utility model. Various modifications and variations of the present utility model will be apparent to those skilled in the art. Any modification, equivalent replacement, improvement, or the like, which is within the spirit and principles of the present utility model, should be included in the scope of the claims of the present utility model.

Claims (10)

1. An umbrella rib inner tube processing device, characterized by comprising:

the machine is provided with a processing channel for communicating the umbrella rib middle pipe;

the feeding components and the receiving hoppers are respectively arranged at two ends of the processing channel;

the first reduction pipe assembly, the profiling punching assembly and the chamfering assembly are sequentially arranged on the machine table along the direction from the feeding assembly to the receiving hopper;

the first reduction pipe shrinkage component is used for reducing, correcting and shrinking round pipes at two ends of the umbrella rib inner pipe;

the profiling punching assembly is used for profiling and punching two ends of the umbrella rib inner tube;

the conveying assembly is arranged on the machine table and used for conveying the umbrella rib middle pipe among the feeding assembly, the first reduction pipe shrinking assembly, the profiling punching assembly, the chamfering assembly and the receiving hopper.

2. The rib inner tube processing device of claim 1, wherein the feeding assembly comprises a stock mechanism and a pushing mechanism;

the material storage mechanism comprises a material rack and a material guide channel arranged in the material rack, the material rack is arranged on a machine table, the material guide channel extends from the top end of the material rack to the bottom end of the material rack, the material guide channel comprises a material guide front end and a material guide rear end, the material guide front end is used for bearing pipes, and the material guide rear end is used for arranging the pipes;

the pushing mechanism comprises a first mounting seat arranged on the machine table, a first linear driving part arranged on the first mounting seat, a first sliding seat arranged at the output end of the first linear driving part and in sliding connection with the machine table, and a first bearing plate arranged on the first sliding seat, wherein the first bearing plate is positioned below the material rack, a groove is formed in the front end of the first bearing plate, and the pipe flows into the groove from the rear end of the material guide and is pushed out by the first linear driving part.

3. The umbrella rib inner tube processing device of claim 1, wherein the first reduction tube assembly comprises a reduction mechanism and a reduction tube mechanism which are oppositely arranged at two sides of the processing channel;

the reduction mechanism comprises a second mounting seat arranged on the machine table, a second linear driving part arranged on the second mounting seat, a first sliding seat which is connected on the machine table in a sliding manner and is connected with the output end of the second linear driving part, a second bearing plate arranged on the machine table, and a reduction mold core penetrating through the second bearing plate, wherein one end of the reduction mold core penetrates through the second bearing plate and is connected with the first sliding seat, the outer side wall of the reduction mold core is attached to the inner side wall of the umbrella rib middle pipe, and the reduction mold core moves back and forth towards the processing channel under the action of the second linear driving part;

the pipe shrinking mechanism comprises a third mounting seat arranged on the machine table, a third linear driving part arranged on the third mounting seat, a pipe shrinking mold core arranged at the output end of the third linear driving part and a third bearing plate arranged on the machine table, wherein the pipe shrinking mold core is slidably connected to the third bearing plate, a circular pipe inner core is arranged in a cavity of the pipe shrinking mold core, and the pipe shrinking mold core moves back and forth towards the processing channel under the action of the third linear driving part.

4. The rib inner tube processing device according to claim 1, wherein the profiling punching assembly comprises profiling mechanisms and punching mechanisms which are oppositely arranged at two sides of the processing channel;

the profiling mechanism comprises a fourth mounting seat arranged on the machine table, a fourth linear driving part arranged on the fourth mounting seat, a first fixing seat arranged on the machine table, a second sliding seat connected to the first fixing seat in a sliding manner, a first mounting plate arranged on the machine table, a profiling mold arranged on the first mounting plate, and a profiling inner core arranged at one end of the second sliding seat, wherein a die orifice of the profiling mold faces to the processing channel, one end of the profiling inner core penetrates through the first mounting plate and stretches into a cavity of the profiling mold, and the profiling inner core moves back and forth towards the cavity of the profiling mold under the action of the fourth linear driving part;

the punching mechanism comprises a fifth mounting seat arranged on the machine table, a fifth linear driving part arranged on the fifth mounting seat, a third sliding seat arranged at the output end of the fifth linear driving part and in sliding connection with the machine table, a fourth bearing plate arranged on the third sliding seat, and a punching die arranged on the fourth bearing plate, wherein a die opening of the punching die is opposite to a die cavity of the profiling die, and the punching die moves back and forth towards a processing channel under the action of the fifth linear driving part.

5. The rib inner tube processing device according to claim 4, wherein the compression mold comprises a first top plate and a first bottom plate which are respectively arranged at the top and the bottom of the first mounting plate, a first upper mold which is connected to the side surface of the first mounting plate in a sliding manner, a first lower mold which is arranged on the first bottom plate and opposite to the first upper mold, and a sixth linear driving part which is arranged on the first top plate, wherein the output end of the sixth linear driving part extends downwards and is connected with the first upper mold, the side surfaces of the first upper mold opposite to the first lower mold are respectively provided with a cavity groove, the first upper mold moves upwards and downwards towards the first lower mold under the driving of the sixth linear driving part, and the first upper mold and the first lower mold are matched with each other to form a cavity.

6. The rib inner tube processing device according to claim 5, wherein the punching die comprises four first guide posts vertically arranged at four corners of the top of the fourth bearing plate, a second top plate arranged at the top of the first guide posts, a seventh linear driving part arranged on the second top plate, a first lifting plate movably sleeved on the outer side of the first guide posts, a punching knife arranged at the bottom of the first lifting plate, a first die holder arranged on the fourth bearing plate, a first die core arranged on the first die holder and provided with punching holes, wherein the output end of the seventh linear driving part extends downwards and is connected with the first lifting plate, and the punching knife moves back and forth towards the punching holes of the first die core under the action of the seventh linear driving part.

7. The umbrella rib inner tube processing device according to claim 1, wherein the chamfering assembly comprises a chamfering mechanism and a positioning mechanism which are oppositely arranged at two sides of the processing channel;

the chamfering mechanism comprises a sixth mounting seat arranged on the machine table, an eighth linear driving part arranged on the sixth mounting seat, a fourth sliding seat connected to the machine table in a sliding way, a second mounting plate arranged on the machine table, a pressing die arranged on the second mounting plate, a rotating part arranged on the fourth sliding seat and a chamfering die core arranged at the output end of the rotating part, wherein one end of the chamfering die core penetrates through the second mounting plate and stretches into a cavity of the pressing die, and the chamfering die core moves back and forth towards the cavity of the pressing die under the action of the eighth linear driving part;

the positioning mechanism comprises a seventh mounting seat arranged on the machine table, a ninth linear driving part arranged on the seventh mounting seat, a fifth bearing plate arranged on the machine table and a positioning rod penetrating through the fifth bearing plate, wherein one end of the positioning rod is connected with the output end of the ninth linear driving part, and the other end of the positioning rod is opposite to the cavity of the compaction die.

8. The apparatus for processing an inner tube of an umbrella rib according to claim 7, wherein the pressing mold comprises a third top plate and a second bottom plate which are respectively arranged at the top and the bottom of the second mounting plate, a second upper mold which is connected to the side surface of the second mounting plate in a sliding manner, a second lower mold which is arranged on the second bottom plate and is opposite to the second upper mold, and a tenth linear driving part which is arranged on the third top plate, the output end of the tenth linear driving part extends downwards and is connected with the second upper mold, cavity grooves are formed in the side surfaces of the second upper mold opposite to the second lower mold, the second upper mold moves up and down towards the second lower mold under the driving of the tenth linear driving part, and the second upper mold and the second lower mold are matched with each other to form a cavity when in pressing.

9. The rib inner tube processing device of claim 1, wherein the transport assembly comprises:

the rack is arranged on the machine table, and the top of the rack extends to the position right above the processing channel;

the third mounting plate is arranged at the top of the rack;

an eleventh linear driving section provided on a side surface of the third mounting plate;

the fifth sliding seat is horizontally and slidably connected to the side surface of the third mounting plate, and one side of the fifth sliding seat is in transmission connection with the output end of the eleventh linear driving part;

a twelfth linear driving part, which is arranged on the fifth sliding seat, and the output end of which extends upwards;

a fourth top plate provided at an output end of the twelfth linear driving part;

one end of the second guide column is connected with the bottom of the fourth top plate, and the other end of the second guide column penetrates through the fifth sliding seat and extends downwards;

the supporting plate is arranged at the bottom of the second guide column, and the arrangement direction of the supporting plate is consistent with the length direction of the processing channel;

the clamping parts are arranged in a plurality of mode, and the clamping parts are arranged at intervals at the bottom of the supporting plate.

10. The rib inner tube processing device according to any one of claims 1 to 9, wherein a second reduction tube assembly is arranged between the profiling punching assembly and the chamfering assembly, and the second reduction tube assembly is used for reducing and shrinking the profiling punched rib inner tube.

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