CN214241529U - Tubular busbar automatic production line - Google Patents

Abstract

The utility model discloses an automatic production line of tubular buses, which comprises a frame, a plurality of lifting transmission mechanisms, a pick-and-place mechanism, a sleeve heating mechanism and a film coating mechanism; the film coating mechanism is arranged on the rack and can move along the length direction of the rack, comprises a rotatable turntable and at least one film tape unwinding assembly connected to the turntable, the turntable is provided with a cavity for the pipe to pass through, and the film tape unwinding assembly is used for unwinding the film tape. The utility model discloses can realize the automatic production processing of cast generating line, improve production efficiency.

Description

Tubular busbar automatic production line

[ technical field ] A method for producing a semiconductor device

The utility model relates to a tubular product processing equipment technical field especially relates to a tubular bus automatic production line.

[ background of the invention ]

At present, in the processing and production process of a tubular wind power bus, a heat-shrinkable sleeve is required to be sleeved outside a raw material long pipe firstly, then the heat-shrinkable sleeve is heated, so that the heat-shrinkable sleeve is tightly wrapped on the raw material long pipe after being shrunk to play an insulating protection role, and finally a protective film is wound to complete the processing of a finished product. However, the diameter of the raw material pipe is about 100m, and the length of the raw material pipe can reach 24 m, so that the automatic production equipment for the tubular bus is not applied at present. A series of processes such as conveying pipes, sleeving heat-shrinkable sleeves outside, heating the heat-shrinkable sleeves, wrapping protective films and receiving materials on a production line all need manual independent operation, the production efficiency is extremely low, the working strength of manual operation is high, the pipes are easy to damage by a crashing object, scald and the like, the safety is low, and the quality of finished products is difficult to guarantee. In view of the above, it is desirable to provide an automatic production line for tubular bus bars to overcome the above-mentioned drawbacks.

[ Utility model ] content

The utility model aims at providing a tubular bus automatic production line carries out automatic production operations such as outside cover heat shrinkage bush, heating shrinkage bush, package protection film to raw and other materials tubular product, and production efficiency is high, and the security performance is high.

In order to achieve the above object, the utility model provides a pyrocondensation sheath automatic production line, include:

a frame;

the lifting transmission mechanisms are arranged on the rack at intervals along the length direction of the rack and are used for supporting and conveying pipes;

the picking and placing mechanism is provided with a grabbing part, and the grabbing part is used for clamping the pipe to be close to or far away from the lifting transmission mechanism;

the sleeve heating mechanism is arranged on the rack and can move along the length direction of the rack, and comprises a heating assembly and a clamping assembly; the clamping assembly is used for clamping a heat-shrinkable sleeve, the heating assembly is provided with a heating cavity through which a pipe can pass, and the heating assembly is used for heating the pipe sleeved with the heat-shrinkable sleeve;

the film coating mechanism is arranged on the rack and can move along the length direction of the rack, the film coating mechanism comprises a rotatable turntable and at least one film tape unwinding assembly connected to the turntable, a cavity for the pipe to pass through is formed in the turntable, and the film tape unwinding assembly is used for unwinding the film tape.

In a preferred embodiment, the lifting transmission mechanism comprises a bottom plate, a driving assembly, a movable plate and a transmission assembly; the movable plate and the bottom plate are arranged at intervals, the transmission assembly is arranged on the movable plate and comprises a synchronous belt for horizontally transmitting the pipes, and the driving assembly is arranged on the bottom plate; the driving assembly is connected with the movable plate and used for driving the movable plate to move up and down.

In a preferred embodiment, the movable plate is provided with a rotatable supporting seat; the bottom plate is fixedly provided with a guide rod, one end, far away from the bottom plate, of the guide rod penetrates through the movable plate and is connected to the supporting seat, the supporting seat comprises a rotating rod, and the rotating rod is movably connected with the guide rod.

In a preferred embodiment, the sleeve heating mechanism includes a moving seat for mounting the heating assembly and the clamping assembly, an unwinding frame for unwinding the heat-shrinkable sleeve is arranged at one end of the rack, and the clamping assembly is arranged at one end of the heating assembly far away from the unwinding frame.

In a preferred embodiment, the film coating mechanism comprises a mounting seat and a rotary driving part arranged on the mounting seat, the turntable is limited on the mounting seat, and the rotary driving part is used for driving the turntable to rotate; the film tape unreeling assembly comprises a guide shaft fixed on the turntable and a film tape roll limited on the guide shaft and capable of moving.

In a preferred embodiment, the rack comprises a pair of crossbearers and a power assembly, wherein the crossbearers and the power assembly are arranged in parallel at intervals, the power assembly drives the mounting base to move along the crossbearers through a chain, and a chain pull rod connected with the chain is fixed on the mounting base.

In a preferred embodiment, one end of the rack is further provided with an ejection mechanism, the ejection mechanism includes an ejection driving member and an ejection rod connected to the ejection driving member, the ejection rod is arranged along the length direction of the rack, and an ejection block is arranged at one end of the ejection rod away from the ejection driving member.

In a preferred embodiment, the pipe conveying device further comprises a conveying mechanism, and the gripping part is further used for clamping the pipe to be close to or far away from the conveying mechanism; the conveying mechanism comprises a support, a material placing assembly and a guide wheel set; the bracket comprises a base frame, a first side frame and a second side frame, wherein the first side frame and the second side frame are fixed on two sides of the upper part of the base frame; the material placing assembly comprises a rotating shaft arranged on the support along the vertical direction and a plurality of material storing plates arranged at intervals along the longitudinal direction of the rotating shaft, and the material storing plates can rotate around the rotating shaft in the horizontal direction; the guide wheel set is fixed at the bottom end of the underframe to enable the support to move.

In a preferred embodiment, the material storage plate is provided with a plurality of accommodating grooves for accommodating the tubes, and each accommodating groove correspondingly accommodates one tube.

In a preferred embodiment, the material storage plate is provided with a limiting groove for limiting the movement of the pipe.

The beneficial effects of the utility model reside in that: raw and other materials tubular product is placed on a plurality of lift transmission device of frame through getting the mechanism of putting, the sheathed tube heating mechanism makes the centre gripping subassembly drive the heat shrinkage bush cover in the tubular product outside along the frame removal, rethread heating element heaies up and moves along the frame, make the heat shrinkage bush be heated and contract back parcel tubular product, diolame mechanism moves along the frame and drives the membrane area through the carousel simultaneously and unreel the subassembly and rotate, accomplish the diolame processing, at last through getting the unloading of the mechanism of putting, realize the automatic production of wind-powered electricity generation cast generating line, be favorable to improving production efficiency. In the automatic production process, the lifting transmission mechanism carries out lifting movement without interfering the movement of the sleeve heating mechanism and the film coating mechanism, the integral automation degree is high, and the safety performance of the equipment is high.

In order to make the aforementioned and other objects, features and advantages of the present invention comprehensible, preferred embodiments accompanied with figures are described in detail below.

[ description of the drawings ]

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a three-dimensional structure diagram of a bus bar heat-shrinkable sheath production line according to a preferred embodiment of the present invention;

fig. 2 is a schematic partial structure view of a bus bar heat-shrinkable sheath production line according to a preferred embodiment of the present invention;

fig. 3 is a three-dimensional structure diagram of the lifting transmission mechanism according to the preferred embodiment of the present invention;

fig. 4 is a perspective structural view of a pick-and-place mechanism according to a preferred embodiment of the present invention;

fig. 5 is a perspective structural view of a sleeve heating mechanism according to a preferred embodiment of the present invention;

fig. 6 is a perspective structural view of a film coating mechanism according to a preferred embodiment of the present invention;

fig. 7 is a schematic partial structural view of a rack according to an embodiment of the present invention;

FIG. 8 is a schematic view of the transport mechanism shown in FIG. 1 in transporting the pipe;

fig. 9 is a perspective view of a transportation mechanism according to an embodiment of the present invention;

fig. 10 is a perspective view of a transport mechanism according to another embodiment of the present invention.

The reference numbers illustrate:

reference numerals	Name (R)	Reference numerals	Name (R)	Reference numerals	Name (R)
						100	Rack	320	Walking hanger body	700	Transport mechanism
110	Unreeling rack	321	First slide rail	710	Support frame
						120	Cross frame	330	Sideslip subassembly	711	Chassis
121	Second slide rail	340	Hanging platform assembly	712	First side frame
						130	Power assembly	350	Boom assembly	713	Second side frame
131	Chain	400	Sleeve heating mechanism	7131	Horizontal rod
						200	Lifting transmission mechanism	410	Heating assembly	7132	Vertical rod
210	Base plate	411	Heating cavity	7133	Gear lever
						211	Guide rod	420	Clamping assembly	720	Material placing component
212	Linear bearing	430	Movable seat	721	Rotating shaft
						213	Fixed seat	500	Film coating mechanism	722	Material storage plate
220	Drive assembly	510	Rotary disc	7221	Containing groove
						221	Driving cylinder	520	Membrane belt unwinding assembly	7222	Lightening hole
222	Guide shaft	521	Guide shaft	7223	Limiting groove
						230	Movable plate	522	Film roll	723	Fixed seat
240	Transmission assembly	530	Mounting seat	724	Linear bearing
						241	Synchronous belt	531	Chain pull rod	725	Spring
242	Driving wheel	532	Guide wheel	726	Spring seat
						243	Driven wheel	540	Rotary driving member	727	Bottom material storage plate
250	Supporting seat	600	Ejection mechanism	730	Guide wheel set
						251	Rotary rod	610	Ejection driving piece	731	Movable caster
252	Limiting rod	620	Ejector rod	732	Guide bearing
						300	Pick and place mechanism	630	Ejection block	800	Pipe material
310	Gripping part

[ detailed description ] embodiments

In order to make the objects, technical solutions and advantageous technical effects of the present invention more clearly understood, the present invention is further described in detail with reference to the accompanying drawings and the following detailed description. It should be understood that the detailed description and specific examples, while indicating the present invention, are given by way of illustration only and not by way of limitation.

Referring to fig. 1 to 6, an embodiment of the present invention provides an automatic production line for tubular bus bars, which is used for wrapping a heat-shrinkable sheath and a protective film on a metal pipe. The automatic production line of the tubular bus comprises a rack 100, a plurality of lifting transmission mechanisms 200, a pick-and-place mechanism 300, a sleeve heating mechanism 400 and a film coating mechanism 500.

A plurality of lifting transmission mechanisms 200 are arranged on the machine frame 100 at intervals along the length direction of the machine frame 100, and are used for supporting and conveying the pipes 800. The pick and place mechanism 300 is provided with a gripping part 310, and the gripping part 310 is used for gripping the tube 800 to approach or depart from the elevating transfer mechanism 200.

The sleeve heating mechanism 400 is disposed on the rack 100 and can move along the length direction of the rack 100, and the sleeve heating mechanism 400 includes a heating assembly 410 and a clamping assembly 420. The holding assembly 420 is used for holding the heat shrinkable sleeve, the heating assembly 410 is provided with a heating cavity 411 for the pipe 800 to pass through, and the heating assembly 410 is used for heating the pipe 800 sleeved with the heat shrinkable sleeve.

The film wrapping mechanism 500 is disposed on the frame 100 and can move along the length direction of the frame 100, the film wrapping mechanism 500 includes a rotatable turntable 510 and at least one film tape unwinding assembly 520 connected to the turntable 510, the turntable 510 is provided with a cavity through which the tube 800 can pass, and the film tape unwinding assembly 520 is used for unwinding the film tape.

The utility model discloses a cast generating line automatic production line snatchs tubular product 800 through getting put mechanism 300 and places on a plurality of lift transmission mechanism 200, and sleeve pipe heating mechanism 400 moves along frame 100 and makes clamping component 420 drive the heat shrinkage bush cover in tubular product 800 outsidely, then heating component 410 heaies up and follows frame 100 slow movement again, makes the heat shrinkage bush be heated and wraps up tubular product 800 behind the shrink. The film wrapping mechanism 500 moves along the frame 100 and drives the film tape unwinding assembly 520 to rotate through the turntable 510, thereby completing the film wrapping process. In the moving process of the sleeve heating mechanism 400 and the film wrapping mechanism 500, the lifting transmission mechanism 200 performs lifting movement, that is, the lifting transmission mechanism 200 close to the sleeve heating mechanism 400 or the film wrapping mechanism 500 descends, so that the movement of the heating mechanism 400 and the movement of the wrapping mechanism 500 are not interfered, and the pipe 800 can be supported.

Specifically, referring to fig. 3, the lifting transmission mechanism 200 includes a bottom plate 210, a driving assembly 220, a movable plate 230 and a transmission assembly 240. The movable plate 230 and the bottom plate 210 are arranged at intervals, the transmission assembly 240 is arranged on the movable plate 230, the transmission assembly 240 comprises a synchronous belt 241 for horizontally transmitting the tube 800, and the driving assembly 220 is arranged on the bottom plate 210; the driving assembly 220 is connected to the movable plate 230, and the driving assembly 220 is used for driving the movable plate 230 to move up and down.

The movable plate 230 is provided with a rotatable supporting seat 250, the bottom plate 210 is fixed with a guide rod 211, one end of the guide rod 211 far away from the bottom plate 210 penetrates through the movable plate 230 and is connected to the supporting seat 250, the supporting seat 250 comprises a rotating rod 251, and the rotating rod 251 is movably connected with the guide rod 211. It can be understood that, when the driving assembly 220 drives the movable plate 230 to move up and down, the supporting base 250 moves up and down relative to the bottom plate 210, and the guide rod 211 is fixed, so as to drive the rotating rod 251 to rotate. Further, the supporting seat 250 further comprises two limiting rods 252 connected to the rotating rod 251, an included angle is formed between the two limiting rods 252 to support and limit the pipe 800, and the rotating rod 251 can drive the limiting rods 252 to rotate to a vertical position from a horizontal position when rotating, so that the pipe 800 is supported and limited.

In this embodiment, the driving assembly 220 includes a driving cylinder 221 fixed on the bottom plate 210, the bottom plate 210 is movably connected with the movable plate 230 through a guide shaft 222, the bottom plate 210 is provided with a linear bearing 212, and the linear bearing 212 is sleeved on the guide shaft 222, so as to ensure stability and smoothness of the driving assembly 220 in the process of driving the movable plate 230 to move. One end of the guide shaft 222 away from the bottom plate 210 passes through the movable plate 230, and the guide shaft 222 is fixedly connected with the movable plate 230 through the fixing seat 213.

Specifically, the transmission assembly 240 further includes a driving wheel 242, a driven wheel 243 and a motor for driving the driving wheel 242, and the synchronous belt 241 is sleeved on the driving wheel 242 and the driven wheel 243. In this embodiment, the timing belt 241 is an endless chain belt or a belt.

Referring to fig. 1 and 4, the pick and place mechanism 300 further includes a traveling crane body 320, a traverse assembly 330, a platform assembly 340 and a boom assembly 350, wherein the traveling crane body 320 is provided with a first slide rail 321. The traverse assembly 330 is arranged on the row hanger body 320; the hanging platform assembly 340 is slidably arranged on the first slide rail 321 and connected with the traverse assembly 330; the boom assembly 350 is movably disposed on the platform assembly 340, the boom assembly 350 is provided with two spaced gripping portions 310, and each gripping portion 310 is provided with a clamping space for clamping the pipe 800. In this embodiment, the traverse assembly 330 drives the platform assembly 340 to move along the first sliding rail 321, and the platform assembly 340 drives the boom assembly 350 to move up and down, so as to drive the boom assembly 350 to approach or move away from the pipe 800, so that the gripping portion 310 can grip the pipe 800 in the gripping space.

Referring to fig. 1, 2 and 5, the sleeve heating mechanism 400 includes a movable base 430 for mounting a heating element 410 and a clamping element 420, an unwinding frame 110 for unwinding the heat shrinkable sleeve is disposed at one end of the frame 100, and the clamping element 420 is disposed at one end of the heating element 410 away from the unwinding frame 110. It can be understood that, before processing, the sleeve heating mechanism 400 is close to the unreeling frame 110, the heat-shrinkable sleeve unreeled by the unreeling frame 110 passes through the heating element 410 and is sleeved at one end of the pipe 200, and is fixed on the clamping element 420, and moves towards the end far away from the unreeling frame 110 through the moving seat 430, so that the heat-shrinkable sleeve can be completely sleeved outside the pipe 800, the sleeving efficiency is high, after the clamping element 420 is loosened, redundant heat-shrinkable sleeve can be cut off through manual work or cutting equipment, the heating element 410 is heated and then slowly moves towards the end close to the unreeling frame 110, and the heat-shrinkable sleeve is heated and shrunk to wrap the pipe 800. In this embodiment, the heating assembly 410 is a cylinder structure using electric heating, and the clamping assembly 420 is a pair of quick clamps respectively disposed on two sides of the moving seat 430, so as to conveniently and quickly clamp the heat-shrinkable sleeve.

Referring to fig. 2 and fig. 6, the film coating mechanism 500 further includes a mounting seat 530 and a rotary driving member 540 disposed on the mounting seat 530, the rotary disc 510 is limited on the mounting seat 530, and the rotary driving member 540 is used for driving the rotary disc 510 to rotate. The film tape unwinding assembly 520 includes a guide shaft 521 fixed on the turntable 510 and a film tape roll 522 movably limited on the guide shaft 521. It will be appreciated that the mounting block 530 slides along the frame 100, and the rotary drive 540 rotates the turntable 510 to rotate the film roll 522, thereby winding the film roll onto the tube 800. The film roll 522 may be a PVC film, and the rotary driving member 540 may be a driving motor, a servo motor, or the like, which is not limited herein. In this embodiment, the mounting base 530 has a plurality of sets of guide wheels 532, and the rotary driving member 540 drives the guide wheels 532 to rotate through a pulley, a gear or a sprocket, so as to drive the rotating disc 510 to rotate. Preferably, a plurality of guide wheels 532 are spaced around the edge of the rotating plate 510 to limit the rotating plate 510 and maintain stability during rotation of the rotating plate 510.

Referring to fig. 1, 2 and 7, the frame 100 includes a pair of cross frames 120 and a power assembly 130, which are disposed in parallel and spaced, and the power assembly 130 drives the sleeve heating mechanism 400 and the film coating mechanism 500 to move along the cross frames 120 through a chain 131, so that the transmission efficiency is high. As shown in fig. 6, a chain link 531 connected to the chain 131 is fixed to the mount 530. In this embodiment, the driving portion of the power assembly 130 is sealed by a box structure, the cross frame 120 is provided with a second slide rail 121, and the sleeve heating mechanism 400 and the film wrapping mechanism 500 are both in sliding fit with the second slide rail 121.

Specifically, one end of the rack 100 is further provided with an ejection mechanism 600, the ejection mechanism 600 includes an ejection driving member 610 and an ejection rod 620 connected to the ejection driving member 610, the ejection rod 620 is disposed along the length direction of the rack 100, and an ejection block 630 is disposed at one end of the ejection rod 620 far away from the ejection driving member 610. In this embodiment, the ejection driving element 610 may be a driving motor, a servo motor, or the like, and is not limited herein. Specifically, the ejection mechanism 600 is disposed at one end of the frame 100 away from the unreeling frame 110, the ejection block 630 is matched with one end of the tube 800, and after wrapping a heat-shrinkable sleeve or a protective film, the tube 800 can be pushed by the ejection block 630, so that the tube 800 is located at a proper processing position.

Further, referring to fig. 1, 8 and 9, the automatic production line for tubular buses of the present invention further includes a transportation mechanism 700, which can transport the tubular product 800 in the same direction through a plurality of transportation mechanisms 700. It will be appreciated that the gripping portion 310 also serves to grip the tubing 800 to move closer to or further away from the transport mechanism 700. The transportation mechanism 700 includes a support 710, a material placing assembly 720 and a guide wheel set 730.

The bracket 710 comprises a bottom frame 711, and a first side frame 712 and a second side frame 713 which are fixed on two sides of the upper part of the bottom frame 711, wherein a space for placing the pipe 800 is formed between the first side frame 712 and the second side frame 713; the material placing assembly 720 includes a rotating shaft 721 provided on the bracket 710 in a vertical direction and a plurality of material storing plates 722 arranged at intervals in a longitudinal direction of the rotating shaft 721, and the material storing plates 722 can rotate in a horizontal direction around the rotating shaft 721. The guide roller set 730 is fixed to the bottom end of the base frame 711 to move the support frame 710.

In one embodiment, the storage plate 722 is provided with a plurality of accommodating grooves 7221 for accommodating the tubes 800, and each accommodating groove 7221 correspondingly accommodates one tube 800.

The material placing assembly 720 further comprises a fixing seat 723 and a linear bearing 724, one end of the material storing plate 722 is sleeved on the rotating shaft 721 through the linear bearing 724, and the fixing seat 723 is used for fixedly connecting the rotating shaft 721 with the first side frame 712.

A spring 725 and a spring seat 726 are further arranged between every two adjacent material storage plates 722 in the material placing assembly 720, the spring 725 is sleeved on the rotating shaft 721, and the spring seat 726 is fixed on the rotating shaft 721 and used for limiting the spring 725. It will be appreciated that the reservoir plate 722 can be received within the first side frame 712 when rotated to a position longitudinally coincident with the tube 800, and the reservoir plate 722 can abut the second side frame 713 when rotated to a position perpendicular to the longitudinal direction of the tube 800. In this embodiment, a magnetic member for attracting the second side frame 713 is further disposed at an end of the storage plate 722 away from the rotating shaft 721. In this embodiment, the magnetic member is a magnet, and the magnetic member is embedded in the material storage plate 722.

Preferably, the material storage plate 722 is provided with a plurality of lightening holes 7222, in this embodiment, the lightening holes 7222 are circular. The bottom of the material storage plates 722 is provided with a sliding plate which is easily slid when interference occurs between adjacent two material storage plates 722.

Further, the second side frame 713 includes a horizontal rod 7131 and a vertical rod 7132 connected to the horizontal rod 7131, a movable stopper 7133 is further disposed on the second side frame 713, the stopper 7133 is movable to a vertical position to limit the material storage plate 722 between the vertical rod 7132 and the stopper 7133, so as to prevent the material storage plate 722 from shaking due to the fact that the surface of the tube 800 is smooth and is easy to roll during transportation.

One end of the blocking rod 7133 is connected with the bottom frame 711 through a hinge, the blocking rod 7133 can be rotated to a vertical position from a horizontal position through folding of the hinge, a bolt is arranged at one end, away from the hinge, of the blocking rod 7133, a bolt hole matched with the bolt is formed in the horizontal rod 7131, and the blocking rod 7133 is convenient to fix.

The material placing assembly 720 further comprises a bottom material storing plate 727, wherein the bottom material storing plate 727 is fixed on the bottom frame 711, and the bottom material storing plate 727 is perpendicular to the longitudinal direction of the tube 800. Before the pipe 800 is processed, the pipe 800 may be placed on the bottom end material storage plate 727, and after the bottom end material storage plate 727 is full, the material storage plate 722 adjacent to the bottom end material storage plate 727 is rotated to a position vertical to the longitudinal direction of the pipe 800, and the operations are sequentially performed to place the pipe layer by layer.

The rack 10 is provided with a pair of material placing components 720 distributed at intervals, and it can be understood that the material storing plates 722 of the pair of material placing components 720 are correspondingly arranged for supporting the same pipe 800. The number of the material placing components 720 is set according to specific needs. The guiding wheel set 730 includes a movable caster 731 and a guiding bearing 732 disposed on the bottom frame 711, and the guiding bearing 732 is matched with a guiding rail disposed on the ground for guiding and positioning, and can move to a designated position along the guiding rail when the transporting mechanism 700 is pushed, for example, to one side of the rack 100, so as to facilitate loading or unloading of the pick-and-place mechanism 300.

As can be understood, the raw material pipe for producing the wind power bus pipe is a metal pipe, the length is long, the surface is smooth, the transportation mechanism 700 shown in the figure 9 can be used for transportation, each pipe 800 is arranged at intervals, the collision is avoided, and the quality of the pipe 800 is guaranteed.

In another embodiment, the tube 800 after being processed by the heat-shrinkable sleeve and the envelope is not easy to slip, and in order to save space and improve transportation efficiency, the transportation mechanism 700 shown in fig. 10 may be adopted, the storage plates 722 are provided with limiting grooves 7223 for limiting the movement of the tube 800, and the tubes 800 placed on each storage plate 722 may be attached side by side to save space.

The embodiment of the utility model provides a tubular bus automatic production line, place raw and other materials tubular product on a plurality of lift transmission device 200 of frame 100 through getting mechanism 300 of putting, bushing heating mechanism 400 moves along frame 100 and makes clamping component 420 drive heat shrinkable sleeve cover in tubular product 800 outside, rethread heating component 410 heaies up and moves along frame 100, make heat shrinkable sleeve cover tubular product 800 after being heated and shrunk, diolame mechanism 500 moves along frame 100 and drives the membrane area through carousel 510 simultaneously and unreel subassembly 520 and rotate, accomplish the diolame processing, at last through getting mechanism 300 unloading, realize the automatic production of wind-powered electricity generation cast generating line, be favorable to improving production efficiency. In the automatic production process, the lifting transmission mechanism 200 does lifting movement without interfering with the movement of the sleeve heating mechanism 400 and the coating mechanism 500, so that the whole automation degree is high, and the equipment safety performance is high.

The invention is not limited solely to that described in the specification and the embodiments, and additional advantages and modifications will readily occur to those skilled in the art, and it is not intended to be limited to the specific details, representative apparatus, and illustrative examples shown and described herein, without departing from the spirit and scope of the general concept as defined by the appended claims and their equivalents.

Claims (10)

1. An automatic production line for tubular buses, characterized by comprising:

a frame;

the lifting transmission mechanisms are arranged on the rack at intervals along the length direction of the rack and are used for supporting and conveying pipes;

the picking and placing mechanism is provided with a grabbing part, and the grabbing part is used for clamping the pipe to be close to or far away from the lifting transmission mechanism;

the sleeve heating mechanism is arranged on the rack and can move along the length direction of the rack, and comprises a heating assembly and a clamping assembly; the clamping assembly is used for clamping a heat-shrinkable sleeve, the heating assembly is provided with a heating cavity through which a pipe can pass, and the heating assembly is used for heating the pipe sleeved with the heat-shrinkable sleeve;

the film coating mechanism is arranged on the rack and can move along the length direction of the rack, the film coating mechanism comprises a rotatable turntable and at least one film tape unwinding assembly connected to the turntable, a cavity for the pipe to pass through is formed in the turntable, and the film tape unwinding assembly is used for unwinding the film tape.

2. The tubular busbar automatic production line according to claim 1, wherein the lifting transmission mechanism comprises a bottom plate, a driving assembly, a movable plate and a transmission assembly; the movable plate and the bottom plate are arranged at intervals, the transmission assembly is arranged on the movable plate and comprises a synchronous belt for horizontally transmitting the pipes, and the driving assembly is arranged on the bottom plate; the driving assembly is connected with the movable plate and used for driving the movable plate to move up and down.

3. The tubular busbar automatic production line according to claim 2, wherein the movable plate is provided with a rotatable support seat; the bottom plate is fixedly provided with a guide rod, one end, far away from the bottom plate, of the guide rod penetrates through the movable plate and is connected to the supporting seat, the supporting seat comprises a rotating rod, and the rotating rod is movably connected with the guide rod.

4. The automatic production line of tubular bus bar of claim 1, wherein the sleeve heating mechanism comprises a moving seat for mounting the heating assembly and the clamping assembly, one end of the rack is provided with an unwinding frame for unwinding the heat-shrinkable sleeve, and the clamping assembly is arranged at one end of the heating assembly far away from the unwinding frame.

5. The automatic production line of the tubular busbar according to claim 1, wherein the coating mechanism comprises a mounting seat and a rotary driving piece arranged on the mounting seat, the rotary table is limited on the mounting seat, and the rotary driving piece is used for driving the rotary table to rotate; the film tape unreeling assembly comprises a guide shaft fixed on the turntable and a film tape roll limited on the guide shaft and capable of moving.

6. The tubular busbar automatic production line of claim 5, wherein the rack comprises a pair of cross frames and a power assembly, the cross frames and the power assembly are arranged in parallel at intervals, the power assembly drives the mounting base to move along the cross frames through a chain, and a chain pull rod connected with the chain is fixed on the mounting base.

7. The automatic production line of tubular bus bars according to claim 1, wherein an ejection mechanism is further disposed at one end of the rack, the ejection mechanism includes an ejection driving member and an ejection rod connected to the ejection driving member, the ejection rod is disposed along the length direction of the rack, and an ejection block is disposed at one end of the ejection rod away from the ejection driving member.

8. The automatic production line of tubular bus bar according to claim 1, further comprising a transport mechanism, wherein the gripping portion is further for gripping the tubular product to approach or depart from the transport mechanism; the conveying mechanism comprises a support, a material placing assembly and a guide wheel set; the bracket comprises a base frame, a first side frame and a second side frame, wherein the first side frame and the second side frame are fixed on two sides of the upper part of the base frame; the material placing assembly comprises a rotating shaft arranged on the support along the vertical direction and a plurality of material storing plates arranged at intervals along the longitudinal direction of the rotating shaft, and the material storing plates can rotate around the rotating shaft in the horizontal direction; the guide wheel set is fixed at the bottom end of the bottom frame to enable the support to move.

9. The automatic production line of tubular bus-bar according to claim 8, wherein the material storage plate is provided with a plurality of receiving slots for receiving tubes, and each receiving slot receives a tube.

10. The automatic production line of tubular bus-bar according to claim 8, wherein the storage plate is provided with a limiting groove for limiting the movement of the tubular product.

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