CN217316435U - Automatic batch processing equipment for heavy-load pipes - Google Patents

Abstract

The utility model provides an automatic batch processing equipment of heavy-duty type tubular product, which belongs to the technical field of tubular product processing equipment, and comprises a diagonal bed body, one side of the diagonal bed body is provided with an inclined fixing surface, a horizontal X-axis guide rail is arranged on the inclined fixing surface, and a front chuck assembly, a middle chuck assembly and a tail chuck assembly are sequentially connected on the X-axis guide rail in a sliding manner; the cutting head assembly is arranged in the middle of one side, provided with the inclined fixing surface, of the inclined pulling bed body, the feeding assembly is arranged on one side, close to the front chuck assembly, of the cutting head assembly, and the short material discharging assembly and the long material discharging assembly are sequentially arranged on one side, close to the tail chuck assembly, of the cutting head assembly. Therefore, when the short pipes are subjected to blanking action, the blanking action can be directly performed through the short material blanking assembly, and when the longer pipes are subjected to blanking action, the blanking action can be performed through the long material blanking assembly.

Description

Automatic batch processing equipment for heavy-load pipes

Technical Field

The utility model belongs to the technical field of the tubular product processing equipment, concretely relates to automatic batch processing equipment of heavy load type tubular product.

Background

The laser pipe cutting machine utilizes laser beams emitted from a laser generator, the laser beams are focused into laser beams with high power density through an external circuit system to irradiate a workpiece, meanwhile, laser heat is absorbed by workpiece materials, the temperature of the workpiece rises sharply, after the temperature of the workpiece reaches a boiling point, the materials of the workpiece begin to vaporize and form holes, and simultaneously, the materials form cutting seams along with the movement of the relative position of the beams and the workpiece, and the processing and the cutting of pipes are realized. And because it possesses obvious advantages such as machining precision is high, the fracture is level and smooth no burr, material loss is few, and laser pipe cutting machine begins to replace traditional tubular product processing equipment gradually, and the current pipe cutting machine on the market can satisfy the processing demand of most tubular products, also can realize that the full-automatic batch processing of tubular product need not manual intervention. However, for the oversized and overweight pipes in the industries of iron towers, petroleum pipelines, engineering machinery and the like, the manual feeding mode is mostly adopted, the production efficiency is low, and the popularity is poor. In addition, the cut pipes are generally directly fed into the collecting frame through the overturning supporting plate on the existing laser pipe cutting machine, but the blanking mode is only suitable for common finished pipes with shorter length, if the finished pipes are longer pipes, the collecting frame with larger size needs to be arranged, and the occupied space of the whole blanking assembly is increased; meanwhile, when a long pipe directly falls off from the supporting plate, the pipe is easy to deform and the use function of the pipe is affected.

Disclosure of Invention

The utility model provides a technical problem provide a can select different unloading subassemblies to carry out the unloading action according to the length of finished product tubular product, and avoid the automatic batch processing equipment of heavy load type tubular product that finished product tubular product takes place to warp.

In order to solve the technical problem, the utility model discloses the technical scheme who takes does: the heavy-duty automatic pipe batch processing equipment comprises a diagonal lathe bed, wherein an inclined fixing surface is arranged on one side of the diagonal lathe bed, a horizontal X-axis guide rail is arranged on the inclined fixing surface, and a front chuck assembly, a middle chuck assembly and a tail chuck assembly are sequentially connected onto the X-axis guide rail in a sliding manner; the cutting head assembly is arranged in the middle of one side, provided with the inclined fixing surface, of the inclined pulling bed body, the feeding assembly is arranged on one side, close to the front chuck assembly, of the cutting head assembly, and the short material discharging assembly and the long material discharging assembly are sequentially arranged on one side, close to the tail chuck assembly, of the cutting head assembly. When the blanking action is carried out on the shorter pipe, the blanking action can be directly carried out through the short material blanking assembly, and when the blanking action is carried out on the longer pipe, the blanking action can be carried out through the long material blanking assembly.

Further, short material unloading subassembly includes turns over board supporting mechanism, turn over board supporting mechanism vertical sliding connection on the oblique-pulling lathe bed, turn over one side of board supporting mechanism on keeping away from the oblique-pulling lathe bed and be provided with the finished product skip to collect tubular product through the finished product skip.

Furthermore, the turning plate supporting mechanism comprises a supporting frame and a finished product blanking turning plate, the supporting frame is vertically and slidably connected to the inclined broaching machine body, one end, far away from the finished product skip car, of the finished product blanking turning plate is hinged to the upper end of the supporting frame through a rotating shaft, one end, close to the finished product skip car, of the finished product blanking turning plate is connected with the middle or lower portion of the supporting frame through a turning plate cylinder, and the turning plate cylinder can drive the finished product blanking turning plate to rotate around the rotating shaft; an air cylinder mounting seat is arranged below the finished product blanking turning plate, a small material distribution turning plate is hinged to one end, close to the cutting head assembly, of the finished product blanking turning plate, the lower end of the small material distribution turning plate is connected with the air cylinder mounting seat through a material distribution air cylinder, and the material distribution air cylinder can drive the small material distribution turning plate to rotate around a hinged shaft of the small material distribution turning plate and the finished product blanking turning plate; and a waste trolley is arranged below the small material distributing turning plate. In the process of processing the pipe, the pipe can be supported by the finished product blanking turnover plate, and waste materials generated in the cutting process are discharged through a blanking port formed between the small material distribution turnover plate and the finished product blanking turnover plate; after the pipe is processed, the pipe can be guided into the finished product skip car through the inclined finished product blanking turnover plate and the small material distribution turnover plate.

Furthermore, the finished product blanking turning plate is provided with a support roller, and the friction force between the pipe and the finished product blanking turning plate is reduced through the support roller.

Furthermore, the long material blanking assembly comprises at least two groups of long material blanking units, all the long material blanking units are in synchronous transmission connection through a transmission shaft, and synchronous work among the long material blanking units is guaranteed.

Further, the long material blanking unit comprises a supporting bottom frame, a supporting seat is horizontally and slidably connected to the supporting bottom frame, the horizontal sliding direction of the supporting seat is perpendicular to the length direction of the X-axis guide rail, a V-shaped support II is vertically and slidably connected to the supporting seat, and the V-shaped support II can be positioned below a pipe clamped by the middle chuck assembly and/or the tail chuck assembly; the long material blanking unit further comprises a conveying frame, a conveying belt is arranged at the upper end of the conveying frame, the conveying direction of the conveying belt is parallel to the horizontal sliding direction of the supporting seat, all the conveying belts are connected through transmission shaft synchronous transmission, at least one V-shaped support I is arranged on each conveying belt, and the V-shaped support I can be aligned to the V-shaped support II. When the longer tubular product is unloaded to move like this, can take off it from the chuck subassembly that corresponds through V type support two earlier, then the horizontal motion of rethread supporting seat and the vertical motion of V type support two transfer it to V type support one on to transport it to regulation position department through the conveyer belt.

Furthermore, one end of the support chassis, which is close to the diagonal bed body, is detachably mounted at the lower part of the diagonal bed body, so that the whole long material blanking assembly is positioned.

Further, the structure of the feeding assembly is the same as that of the long material blanking assembly.

Furthermore, the inclined-pulling bed body is of a spliced bed body structure, the X-axis guide rail is of a spliced guide rail structure, and the splicing position of the inclined-pulling bed body and the splicing position of the X-axis guide rail are staggered with each other, so that the equipment is guaranteed to have high running precision.

Furthermore, at least two X-axis guide rails are arranged on the inclined fixing surface of the inclined pulling bed body in parallel, and the splicing positions of any two adjacent X-axis guide rails are staggered mutually, so that the bearing capacity of the whole X-axis guide rail is effectively improved.

According to the technical solution provided by the utility model, the utility model has the advantages of it is following:

1. the bed body has good stability, the diagonal draw bed body in the utility model has a unique triangular tenon-and-mortise structure, higher rigidity, better stability, larger bearing load, greatly improved damping performance and better running performance;

2. the processing precision is high, the feeding assembly, the short material blanking assembly and the long material blanking assembly in the utility model can support the pipe, and can effectively prevent the straw rope phenomenon from occurring when the pipe is cut at high speed and the crowbar phenomenon generated by the external gravity center when the chuck assembly is too long when the pipe stretches out, so that the operation of the whole equipment is more stable and the cutting precision is higher;

3. the cutting machine has the advantages that the cutting machine can realize reversing cutting through the matching of the three chuck assemblies and realize cutting of the pipe tail materials, so that the consumption of raw materials is reduced, and the production cost is reduced;

4. the pipe has high load capacity, because the utility model is provided with a plurality of groups of supporting structures and adopts three chuck assemblies for clamping, the load capacity is 1.5-2 times of that of the common two-chuck pipe cutting machine, and the pipe can be used for heavy pipe cutting;

5. the diagonal draw lathe bed, the feeding assembly and the long material blanking assembly are in sectional modular design, so that the preparation is facilitated, the finished product period is shortened, the crane hoisting is convenient, and the transportation cost is low; meanwhile, the machine can prevent short workpieces from being stuck due to the fact that the short workpieces are drilled into the equipment;

6. the utility model discloses a subregion formula blanking structure, promptly the utility model discloses it is regional with whole unloading region divide into short material unloading region and long material unloading to satisfy the processing demand of all tubular product lengths.

Drawings

In order to more clearly illustrate the technical solution of the present invention, the drawings used in the description will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural diagram of an embodiment of the present invention.

Fig. 2 is the schematic structural diagram of the middle inclined-pulling bed body of the utility model.

Fig. 3 is the structure schematic diagram of the short material blanking assembly and the long material blanking assembly of the utility model.

Fig. 4 is a schematic structural view of the middle turning plate supporting mechanism of the present invention.

Fig. 5 is a schematic structural view of the blanking unit for medium and long materials of the present invention.

In the figure: 1. front chuck component, 2, oblique-pulling lathe bed, 3, middle chuck component, 4, tail chuck component, 5, long material blanking component, 6, short material blanking component, 7, cutting head component, 8, pipe to be processed, 9, feeding component, 10, X-axis guide rail, 11, rack I, 12, rear supporting leg, 13, front supporting leg, 14, adjusting foot margin, 15, hoisting hole, 16, inclined fixing surface, 17, cutting head component fixing frame, 18, turning plate supporting mechanism, 19, waste trolley, 20, finished product skip, 21, transmission shaft, 22, long material blanking unit, 23, supporting frame, 24, lifting driving mechanism, 25, turning plate cylinder, 26, material distributing cylinder, 27, material distributing small turning plate, 28, rotating shaft, 29, finished product turning plate, 30, supporting roller, 31, V-shaped bracket II, 32, supporting seat, 33, V-shaped bracket I, 34, conveying belt, 35, conveying frame, 36. the support chassis 39, the rack II and the rack 40 are connected with the fixing plate.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative efforts all belong to the protection scope of the present invention.

As shown in fig. 1 to 5, the utility model provides an automatic batch processing equipment of heavy load type tubular product, it includes draws lathe bed 2 to one side, draw lathe bed 2 to one side, one side be provided with slope stationary plane 16, be provided with horizontally X axle guide rail 10 on the slope stationary plane 16, just sliding connection has preceding chuck subassembly 1, well chuck subassembly 3 and tail chuck subassembly 4 in proper order on the X axle guide rail 10. In addition, a cutting head assembly 7 is installed in the middle of one side, provided with an inclined fixing surface 16, of the inclined pull bed body 2, a feeding assembly 9 is arranged on one side, close to the front chuck assembly 1, of the cutting head assembly 7, and a short material blanking assembly 6 and a long material blanking assembly 5 are sequentially arranged on one side, close to the tail chuck assembly 4, of the cutting head assembly 7.

The structure of the feeding assembly 9 is the same as that of the long material blanking assembly 5, and the feeding action of the feeding assembly 9 is opposite to that of the long material blanking assembly 5. Specifically, taking the long material blanking assembly 5 as an example, the long material blanking assembly 5 includes at least two groups of long material blanking units 22, and all the long material blanking units 22 are in synchronous transmission connection through the transmission shaft 21. Further, the long material blanking unit 22 comprises a supporting chassis 38, one end of the supporting chassis 38 is mounted at the lower part of the diagonal bed body 2 through a connecting and fixing plate 40, the upper end of the supporting chassis 38 is horizontally and slidably connected with a supporting seat 32 through a linear guide rail 37, and the horizontal sliding direction of the supporting seat 32 is perpendicular to the length direction of the X-axis guide rail 10; still vertical sliding connection has two 31V type supports on the supporting seat 32, two 31V type supports are used for placing, bearing tubular product, just two 31V type supports can be located the below of chuck assembly 3 and/or the tail chuck assembly 4 centre gripping tubular product to can support and the unloading to chuck assembly 3 and/or the tail chuck assembly 4 centre gripping tubular product. In addition, the long material blanking unit 22 further comprises a conveying frame 35, the upper end of the conveying frame 35 is provided with a conveying belt 34, the conveying direction of the conveying belt 34 is parallel to the horizontal sliding direction of the supporting seat 32, all the conveying belts 34 are in synchronous transmission connection through the transmission shaft 21, each conveying belt 34 is provided with at least one first V-shaped support 33, the first V-shaped support 33 is used for placing and supporting a pipe, the first V-shaped support 33 can be aligned with the second V-shaped support 31, and when the second V-shaped support 31 is located at the highest position, the first V-shaped support 33 is lower than the second V-shaped support 31; when the V-shaped bracket two 31 is located at the lowest position, the V-shaped bracket one 33 is higher than the V-shaped bracket two 31, so that the V-shaped bracket two 31 in the long material blanking assembly 5 can transfer the pipe clamped on the middle chuck assembly 3 and/or the tail chuck assembly 4 to the V-shaped bracket one 33.

In addition, the short material blanking assembly 6 comprises a flap support mechanism 18 and a finished product skip 20. The turning plate supporting mechanism 18 comprises a supporting frame 23 and a finished product blanking turning plate 29, the supporting frame 23 and the finished product blanking turning plate 29 are located on the same side of the finished product skip car 20, the supporting frame 23 is vertically and slidably connected with the lower portion of the diagonal-pulling bed body 2, one end, far away from the finished product skip car 20, of the finished product blanking turning plate 29 is hinged to the upper end of the supporting frame 23 through a rotating shaft 28, one end, close to the finished product skip car 20, of the finished product blanking turning plate 29 is connected with the middle portion or the lower portion of the supporting frame 23 through a turning plate cylinder 25, a cylinder body of the turning plate cylinder 25 is hinged to the middle portion or the lower portion of the supporting frame 23, and the end of a piston rod of the turning plate cylinder 25 is hinged to the end of the finished product blanking turning plate 29. Under the action of the flap cylinder 25, the finished product blanking flap 29 can be driven to rotate and tilt around the rotating shaft 28, so that the shorter pipe on the finished product blanking flap 29 is blanked and guided into the finished product skip 20. In addition, the supporting frame 23 is further provided with a lifting driving mechanism 24, and the lifting driving mechanism 24 is used for driving the supporting frame 23 to ascend or descend relative to the inclined-pulling bed body 2, so that the height of the finished product blanking turning plate 29 is always adapted to the height of the pipe clamped on the middle chuck assembly 3 and/or the tail chuck assembly 4.

In addition, when avoiding tubular product in the course of working to draw 2 length direction movements along one side, tubular product and finished product blanking turn over the board 29 between and produce great frictional resistance, the utility model discloses the finished product blanking turns over and rotates on the board 29 and install supporting roller 30. Further, as preferred, the utility model discloses it is still in the finished product blanking turns over that the one end that is close to cutting head subassembly 7 on the board 29 articulates there is the branch material and turns over board 27 for a short time the finished product blanking turns over the below that board 29 was provided with the cylinder mount pad be provided with branch material cylinder 26 on the cylinder mount pad, just divide material cylinder 26's cylinder body with the cylinder mount pad is articulated, divide material cylinder 26's piston rod with divide the material to turn over the board 27 for a short time the lower extreme articulated, just divide material cylinder 26 to order about to divide material to turn over board 27 for a short time and rotate around its articulated shaft that turns over board 29 with the finished product blanking. In addition, a waste trolley 19 is arranged below the small material-separating turning plate 27. In the process of processing the pipe, the utility model can drive the small turning plate 27 to rotate through the material distributing cylinder 26 and form a blanking port, and simultaneously, the waste materials generated in the process of processing the pipe are discharged into the waste material trolley 19 through the blanking port; and after tubular product processing accomplished, the utility model discloses accessible divides material cylinder 26 to order about to divide material to turn over board 27 for a short time and carries out the rotation in the opposite direction, turns over board 29 and is located same inclined plane until it and finished product blanking, then turns over board 27 and finished product blanking through dividing material for a short time and guides short tubular product to the finished product skip 20 in.

In addition, in order to transport the equipment conveniently, the diagonal bed body 2 in the equipment preferably adopts a spliced bed body structure, and each section of bed body is provided with a hoisting hole 15; in addition, the X-axis guide rail 10 arranged on the diagonal bed body 2 also preferably adopts a spliced guide rail structure, and the spliced part of the diagonal bed body 2 and the spliced part of the X-axis guide rail 10 are staggered; and when two or more X-axis guide rails 10 are arranged on the inclined fixing surface 16 in parallel, the splicing positions of any two adjacent X-axis guide rails 10 are staggered, so that the equipment is ensured to have higher operation precision.

In order to further improve the stability of the whole equipment, the utility model is also provided with a front supporting leg 13 and a rear supporting leg 12 on two sides of the diagonal bed body 2; adjusting feet 14 are arranged at the bottoms of the inclined-pull bed body 2, the conveying frame 35 and the supporting bottom frame 38, and after the inclined-pull bed body 2, the conveying frame 35 and the supporting bottom frame 38 are leveled, the adjusting feet 14 are fixed on the ground through expansion bolts, so that the inclined-pull bed body 2, the conveying frame 35 and the supporting bottom frame 38 are prevented from shifting after long-term operation.

The terms "first," "second," "third," "fourth," and the like in the description and in the claims, as well as in the drawings, if any, are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order. It is to be understood that the data so used is interchangeable under appropriate circumstances such that the embodiments of the invention described herein are capable of operation in sequences other than those illustrated or otherwise described herein. Furthermore, the terms "include" and "have," as well as any variations thereof, are intended to cover a non-exclusive inclusion.

The previous description of the disclosed embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention. Thus, the present invention is not intended to be limited to the embodiments shown herein but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims (10)

1. The automatic heavy-load type pipe batch processing equipment is characterized by comprising an oblique-pulling lathe bed, wherein one side of the oblique-pulling lathe bed is provided with an inclined fixing surface, a horizontal X-axis guide rail is arranged on the inclined fixing surface, and a front chuck assembly, a middle chuck assembly and a tail chuck assembly are sequentially connected onto the X-axis guide rail in a sliding manner; the cutting head assembly is arranged in the middle of one side, provided with the inclined fixing surface, of the inclined pulling bed body, the feeding assembly is arranged on one side, close to the front chuck assembly, of the cutting head assembly, and the short material discharging assembly and the long material discharging assembly are sequentially arranged on one side, close to the tail chuck assembly, of the cutting head assembly.

2. The automatic heavy-duty batch processing equipment for pipes according to claim 1, wherein the short material blanking assembly comprises a flap support mechanism, the flap support mechanism is vertically and slidably connected to the inclined-pulling bed body, and a finished material trolley is arranged on one side of the flap support mechanism, which is far away from the inclined-pulling bed body.

3. The automatic heavy-duty tubular product batch processing equipment according to claim 2, wherein the turning plate support mechanism comprises a support frame and a finished product blanking turning plate, the support frame is vertically and slidably connected to the inclined broaching machine body, one end of the finished product blanking turning plate, which is far away from the finished product skip car, is hinged to the upper end of the support frame through a rotating shaft, one end of the finished product blanking turning plate, which is close to the finished product skip car, is connected to the middle or lower part of the support frame through a turning plate cylinder, and the turning plate cylinder can drive the finished product blanking turning plate to rotate around the rotating shaft; an air cylinder mounting seat is arranged below the finished product blanking turning plate, a small material distribution turning plate is hinged to one end, close to the cutting head assembly, of the finished product blanking turning plate, the lower end of the small material distribution turning plate is connected with the air cylinder mounting seat through a material distribution air cylinder, and the material distribution air cylinder can drive the small material distribution turning plate to rotate around a hinged shaft of the small material distribution turning plate and the finished product blanking turning plate; and a waste trolley is arranged below the small material distributing turning plate.

4. The automated heavy-duty tubular product batch processing equipment according to claim 3, wherein the finished product blanking turning plate is provided with a support roller.

5. The automatic heavy-duty pipe batch processing equipment according to claim 1, wherein the long material blanking assembly comprises at least two groups of long material blanking units, and all the long material blanking units are in synchronous transmission connection through a transmission shaft.

6. The automatic heavy-duty pipe batch processing equipment according to claim 5, wherein the long material blanking unit comprises a support chassis, a support seat is horizontally and slidably connected to the support chassis, the horizontal sliding direction of the support seat is perpendicular to the length direction of the X-axis guide rail, a second V-shaped support is vertically and slidably connected to the support seat, and the second V-shaped support can be positioned below a pipe clamped by the middle chuck assembly and/or the tail chuck assembly; the long material blanking unit further comprises a conveying frame, a conveying belt is arranged at the upper end of the conveying frame, the conveying direction of the conveying belt is parallel to the horizontal sliding direction of the supporting seat, all the conveying belts are connected through transmission shaft synchronous transmission, at least one V-shaped support I is arranged on each conveying belt, and the V-shaped support I can be aligned to the V-shaped support II.

7. The automated batch processing equipment for heavy-duty pipes according to claim 6, wherein one end of the support chassis near the diagonal bed is detachably mounted on the lower part of the diagonal bed.

8. The automated heavy-duty pipe batch processing equipment according to claim 5, wherein the structure of the feeding assembly is the same as that of the long material blanking assembly.

9. The automated heavy-duty pipe batch processing apparatus according to any one of claims 1 to 8, wherein the inclined pull bed is of a split bed structure, the X-axis guideway is of a split guideway structure, and a split of the inclined pull bed and a split of the X-axis guideway are staggered from each other.

10. The automatic heavy-duty tubular product batch processing equipment according to claim 9, wherein at least two X-axis guide rails are arranged in parallel on the inclined fixing surface of the inclined-pulling bed body, and the splicing positions of any two adjacent X-axis guide rails are staggered.

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