阅读说明：本技术 自动化线材修剪站和样品质量评估 (Automated wire trimming station and sample quality assessment ) 是由 S·迪加瓦拉普 M·D·波尔弗里曼 J·策勒 W·X·沈 于 2019-03-14 设计创作，主要内容包括：提供了一种自动化修剪系统,其包括视觉系统,该视觉系统识别定位于线圈内的环的数量以及需要切割环的剪切位置。一个或多个修剪机构接收剪切位置并继续在剪切位置处切割环。钩装置与线圈对接,用于将线圈转移到修剪区域。此外,提供了一种自动化修剪系统,其包括具有多个环的线圈。一个或多个修剪机构通过切割环的一部分而从线圈中选择多个环并继续形成所需长度的样品。接收器单元从一个或多个修剪机构接收样品以评估样品的质量。(An automated trimming system is provided that includes a vision system that identifies the number of loops positioned within a loop and the cutting location at which the loops need to be cut. One or more trim mechanisms receive the cutting position and continue to cut the loop at the cutting position. The hook means interfaces with the loop for transferring the loop to the cutback area. Further, an automated trimming system is provided that includes a loop having a plurality of loops. One or more trimming mechanisms select a plurality of loops from the loop by cutting a portion of the loop and continue to form a sample of a desired length. The receiver unit receives samples from one or more trimming mechanisms to assess the quality of the samples.)

1. An automated trimming system, comprising:

a vision system that identifies the number of loops positioned within a coil and the cutting locations at which the loops need to be cut;

one or more trimming mechanisms that receive the cutting position and continue to cut the loop at the cutting position; and

a hook device interfacing with the loop for transferring the loop to a cutback area, once the loop is positioned in the cutback area, the ends of the loop are separated using a plurality of spiral rollers or the one or more cutting mechanisms to expose the loops positioned therein.

2. The automated trimming system of claim 1, wherein the hook device interfaces with the loop handling area to transfer the loops to the trimming area.

3. The automated trimming system of claim 1, wherein the helical roller is positioned on a side of the hook device.

4. The automated trimming system of claim 1, wherein the vision system includes a plurality of cameras.

5. The automated trimming system of claim 4, wherein the camera is positioned on a guide rail to allow inspection of the loop positioned within the separated end of the loop.

6. The automated trimming system of claim 1, wherein the vision system generates a contour of the exposed ring.

7. The automated trimming system of claim 1, wherein the vision system detects a proper edge of the exposed loop.

8. The automated trimming system of claim 1, wherein the vision system generates a depth of field for the exposed coil.

9. The automated trimming system of claim 1, wherein the one or more trimming mechanisms comprise one or more trimming robots.

10. The automated trimming system of claim 9, wherein the one or more trimming robots receive commands for cutting the exposed loop via a controller.

11. The automated trimming system of claim 9, wherein the one or more trimming robots deploy loops to be trimmed.

12. The automated trimming system of claim 1, wherein the one or more trimming mechanisms comprise a wire cutter and a hook assembly.

13. The automated trimming system of claim 13, wherein the hook assembly is for separating the loops to expose the loops.

14. A method of performing operations of an automated trimming system, comprising:

identifying, using a vision system, a number of loops positioned within a coil and a cutting location at which the loops need to be cut;

using one or more trimming mechanisms that receive the cutting position and continue cutting the loop at the cutting position;

providing hook means interfacing with a loop handling area for transferring the loops to a trim area; and

separating the ends of the coil using a plurality of helical rollers or the one or more trimming mechanisms to expose the plurality of loops therein.

15. The method of claim 14 wherein the hook means interfaces with a loop handling area to transfer the loops to the cutback area.

16. The method of claim 16 wherein the helical rollers are positioned on the sides of the hook devices.

17. The method of claim 14, wherein the vision system includes a plurality of cameras.

18. The method of claim 17, wherein the camera is positioned on a guide rail to allow inspection of the loops positioned within the separated ends of the coil.

19. The method of claim 14, wherein the vision system generates a contour of the exposed ring.

20. The method of claim 14, wherein the vision system detects the appropriate edge of the exposed coil.

21. The method of claim 14, wherein the vision system generates a depth of field for the exposed coil.

22. The method of claim 14, wherein the one or more trimming mechanisms comprise one or more trimming robots.

23. The method of claim 22, wherein the one or more trimming robots receive commands for cutting the exposed loops via a controller.

24. The method of claim 22, wherein the one or more trimming robots deploy loops to be trimmed.

25. The method of claim 14, wherein the one or more trimming mechanisms comprise a string cutter and a hook assembly.

26. The method of claim 25, wherein the hook component is used to separate the loops to expose the loops.

27. An automated trimming system, comprising:

a coil comprising a plurality of loops;

one or more trimming mechanisms that select a plurality of loops from the coil and continue to form a sample of a desired length by cutting a portion of the loops; and

a receiver unit that receives the sample from the one or more trimming mechanisms to assess a quality of the sample.

28. The automated trimming system of claim 27, wherein the coil is positioned on a support structure.

29. The automated trimming system of claim 27, wherein the number of loops selected by the one or more trimming mechanisms is predefined by a controller.

30. The automated trimming system of claim 27, wherein the receiver unit comprises a tilt structure.

31. The automated trimming system of claim 30, wherein the inclined structure comprises a channel or a sliding structure.

32. A method of performing operations of an automated trimming system, comprising:

providing a coil comprising a plurality of loops;

selecting a plurality of loops from the loop and continuing to form a sample of a desired length by cutting a portion of the loops using one or more trimming mechanisms; and

receiving the sample from the one or more trimming mechanisms using a receiver unit to assess the quality of the sample.

33. The method of claim 32, wherein the coil is positioned on a support structure.

34. The method of claim 32, wherein the number of loops selected by the one or more trimming mechanisms is predefined by a controller.

35. The method of claim 32, wherein the receiver unit comprises a slanted structure.

36. The method of claim 35, wherein the sloped structure comprises a channel or a sliding structure.

Technical Field

The invention relates to the field of wire trimming stations, and in particular to an automated wire trimming station.

Background

Traditionally, an in-line high speed shear would be used to trim the head and tail of each billet "coil" rolled in the mill, the high speed shear being located directly before the laying head in the wire line, and therefore must be able to trim 5.5 mm of the line while travelling at 120 to 130 m/s. This results in a complex machine with a complicated control system requiring a high degree of maintenance and attention to the details to operate it correctly and consistently. Due to its complex nature, the machine has high capital costs and has high operating costs because it uses two main tracks, two motors of 200 kW to 300 kW and a plurality of switching tubes, all of which need to be modified according to the size of the material to be trimmed.

Disclosure of Invention

According to one aspect of the present invention, an automated trimming system is provided. The automated trimming system includes a loop including a plurality of loops. One or more trimming mechanisms select multiple loops from the loop and continue to form the sample by cutting a portion of the loops. The receiver unit receives samples from one or more trimming mechanisms to assess the quality of the samples.

According to another aspect of the invention, a method of performing the operation of an automated trimming system is provided. The method includes providing a coil including a plurality of loops. Further, the method includes selecting a plurality of loops from the loop and continuing to form the sample by cutting a portion of the loops using one or more trimming mechanisms. Further, the method includes receiving the sample from the one or more trimming mechanisms using the receiver unit to assess a quality of the sample.

According to another aspect of the present invention, an automated trimming system is provided. The automated trimming system includes a vision system that identifies the number of loops positioned within the loop and the cutting location at which the loops need to be cut. One or more trim mechanisms receive the cutting position and continue to cut the loop at the cutting position. The hook device interfaces with the loop for transferring the loop to a cutback area, and once the loop is positioned in the cutback area, the ends of the loop are separated using a plurality of spiral rollers or one or more cutting mechanisms to expose the loops positioned therein.

According to another aspect of the invention, a method of performing the operation of an automated trimming system is provided. The method includes identifying, using a vision system, a number of loops positioned within the coil and a cutting location at which the loops need to be cut. Also, the method includes using one or more trimming mechanisms that receive the cutting position and continue cutting the loop at the cutting position. A hook device is provided that interfaces with the loop handling area for transferring loops to the trim area. In addition, the method includes separating the ends of the loop handling system using a plurality of spiral rollers or one or more trimming mechanisms to expose the plurality of loops positioned therein.

Drawings

FIGS. 1A-1C are schematic diagrams illustrating a novel trimming station for use in conjunction with a loop handling system;

FIG. 2 is a schematic diagram illustrating a detailed view of the novel hook device used in accordance with the present invention;

fig. 3A to 3B are schematic views illustrating detailed views of the trimming robot;

fig. 4A-4C are schematic diagrams illustrating various operations of a vision system;

5A-5C are schematic diagrams illustrating another embodiment of a trim station for use in conjunction with a loop handling system; and

fig. 6A to 6B show another embodiment of the invention in which a sample of the coil is used to test its quality.

Detailed Description

The present invention relates to an automated trimming station included in a loop handling area where loops have been formed and collected and transported on a pallet or hook transport to a compactor for strapping. A new station would be included prior to the compactor to allow automated trimming of the head and tail of each coil without operator intervention. The trimming station will include a side shifting device with a unique hook arrangement to allow the ends of the loops to be spread out to enable trimming of the desired number of head and tail end loops, the cutting or trimming of the loops to be performed by an automated trimming robot, controlled through a vision system interface. The purpose of the vision system is to ensure that the correct number of loops are trimmed from each coil.

The performance of the high speed shear is dependent on the mill speed, and the invention is not so limited. For example, when the mill speed is 120 m/s, the cut time of the high speed shear is less than 0.05 seconds, whereas the cut time of the present invention is about 45 seconds. According to the concept of trimming at the coil treatment area, the coils can be trimmed while stationary, and individual coils can remain stationary for a minimum time of about 45 seconds or more, depending on the productivity of the mill. If the initial part of the coil handling system is a vertical pallet system, the invention works within the coil handling system via a coil upender as a standard product.

The custom designed hook device is then docked with the tucked loops to remove the loops and transfer the loops to a trimming station. The hook includes two loop separating means which spread the leading and trailing ends of the loop a predetermined amount. This deployment may also be performed by a trimming robot. This unwinding of the coil then allows the vision system to count the number of loops that are separated from the coil and instruct the arm of the trimming robot to position the loop or loops to be cut at the cutting position. The loops are cut using a hydraulic shear and then the arm of the trimming robot removes the discarded loops from the hooks before they place the loops back on the upender, which then rolls them up for transfer to a compactor for handling. If the loop is on a hook device, the process is similar, but no turning of the loop is required, and the loop is transferred from hook to hook.

Fig. 1A to 1C are schematic views illustrating a novel pruning station 2 for use in accordance with the present invention. The coil 12 is positioned on a mandrel 14, the mandrel 14 being part of a central pallet-tipper 16. The trimming station 2 comprises a hook device 8 and a plurality of trimming robots 10. As shown in fig. 1A, the coil 12 is brought to a lapper 16 after processing. The area around the mandrel 14 includes multiple lasers to measure and ensure accurate centering of the coil. A hooking means 8 is provided which interfaces with the mandrel 14 in order to transfer the loop as shown in figure 1B to the trimming station 2 as shown in figure 1C. The hook means 8 allow the ends of the loops to be spread apart so as to be able to trim the required number of head and tail end loops at the trimming station 2 at one time.

There are many cameras 6 used as part of the vision system to detect the shape and edges of the coils. At the trimming station 2, the camera is mounted on a rail 18, allowing easy movement over the loop 12. The trimming robot 10 helps to spread the ends of the loop 12 to expose the loops placed therein. The vision system uses the camera 6 to analyze the rings to correctly identify the number of rings and their corresponding positions. Using the information detected by the vision system, the trimming robot 10 correctly identifies the number of loops to be trimmed from each loop. The trimming robot has a selective trimmer specifically designed for trimming.

Fig. 2 is a schematic view illustrating a detailed view of the hook device 26. The hook device 26 includes a plurality of helical rollers 28, the helical rollers 28 being attached on each side of the hook device 26. Once the hook device 26 transfers the loop to the trimming station, the end of the loop is pulled a distance using a helical roller 28 to create loop separation via one of the trimming robots. A plurality of servo drives 30 on each side of the hook device are used to automatically pull the ends of the loops. The vision system calculates the number of rings at the ring spacing and instructs the robotic arm to position the ring or rings to be cut at the cutting position. Inset 32 shows a detailed view of a spiral roller used in accordance with the present invention. The vision system and the trimming robot communicate with each other via a wireless or wired control system to coordinate the recognition and trimming operations.

Alternatively, the unfolding of the coil loop may be performed by the robot itself using a customized pruning tool designed in a way that allows for multipurpose use, the tool comprising the unfolding tool, the aforementioned cutting tool and the clamping tool to transport the cutting loop to a disposal location

Fig. 3A is a schematic diagram illustrating a detailed view of a trimming robot 42 used in accordance with the present invention. The trimming robot 42 includes an arm arrangement 44, which arm arrangement 44 is coupled to a fixed surface via a stabilizer system 46. The arm device 44 is coupled to a rotating shaft 48. The rotating shaft 48 is coupled to a lance and shear mechanism 50. Fig. 3B shows a detailed view of the lance and the shearing mechanism 50. The lance and shearing mechanism 50 includes a lance 52 for deploying or separating the coil and a cutter mechanism 54 for trimming the coil. A clamp 60 is also included. The lance 52 and the cutter and gripper mechanism 54 are positioned on a rotatable shaft 56, permitting rotation of the lance 52, cutter mechanism 54 and gripper 60 when in operation. The rotatable shaft 56 is positioned on an anchor mechanism 58 that permits the lance 52, cutter mechanism 54 and grip 60 to move laterally when operated.

The trimming robot 42 is a 6-axis unit that allows flexible movement in 6 degrees of freedom. As previously described, the trimming robot 42 operates using information collected by one or more cameras 52 of the vision system to determine the appropriate location to cut the loop at each of the cut locations.

Fig. 4A to 4C are schematic diagrams illustrating various operations of the vision system. Fig. 4A shows the profile 68 of each coil end positioned between the loop spaces. The position of each ring is indexed by its position and sent to the controller. The controller uses this information to control the trimming robot to perform accurate positioning of the cut. Fig. 4B shows edge/object detection 70 developed by the vision system to detect the appropriate edge of the ring. This information is provided to the controller for processing. Fig. 4C shows the depth of the field of view 72 of the ring being inspected, and the vision system provides this information to the controller. After receiving the above-mentioned various information through the vision system, the controller evaluates the information and sends a corresponding command to the trimming robot as to which evaluated loop is to be cut and discarded.

Fig. 5A to 5C are schematic views illustrating another embodiment of the present invention. This embodiment 80 uses a pair of trimming systems 82, 84 positioned on a rail 86, the rail 86 being placed over a hook device 90 and a loop 94 that allows easy movement, as shown in fig. 5A. The operation of the hook device 90 is similar to the hook device 8 described above. In particular, the hook system 90 places the loop 94 in a trim station for further processing. Each trimming system 82, 84 includes a wire cutter 88 and a hook assembly 90. In addition, the hook assembly 90 of the trimming system 82 is hooked to the edge of the loop 94 to separate the loop 96 on the latch 92 of the hook device 90, as shown in fig. 5B. The same is true for other trimming systems 84, where both trimming systems 82, 84 separate loops 96 on both ends of the coil 94 over the latch 92 simultaneously or separately.

After the loops 96 are placed on the latches 92, the trimming systems 82, 84 trim or cut the respective loops 96 at selected locations using their wire cutters 88 at both ends of the coil 94, as shown in fig. 5C. The determination of these designated locations is provided to the trimming systems 82, 84 by the vision system described herein. The controller is used to interface between the trimming systems 82, 84 and the vision system for cutting or trimming the loop 96.

Fig. 6A-6B illustrate another embodiment of the invention in which a sample of the coil is collected for quality testing. Fig. 6A shows a trimming robot 100 that selects a predetermined number of loops 106 from loops 102 positioned on a hook 110. A pinch roller assembly as part of the end effector allows for variation in the length of the sample to be cut. Fig. 6B shows the trimming robot 100 trimming the sample 104 from the coil and the receiver unit 108 receiving the sample 104. A controller coupled to the trimming robot 100 provides a trimming position for trimming the portion of the loop 106 forming the specimen 104. Also, the metallurgical or mechanical properties of sample 104 are then analyzed to determine if it meets a particular quality. Testing of the sample 104 may be performed at the other end of the receiver unit 108, or a user may manually pick the sample from the receiver unit and perform the necessary testing, or an automated system may be utilized to pick and test the sample. The receiver unit 108 may include a tilting structure such as a channel or a sliding structure. Moreover, the present invention does allow more than one trimming robot 100 to select samples for testing at different points of the coiling system.

Although the present invention has been shown and described with respect to several preferred embodiments thereof, various changes, omissions and additions to the form and detail thereof, may be made therein, without departing from the spirit and scope of the invention.