transmission line

By setting a branched stator and a straight stator in the transmission line and connecting the optical fiber lines in series, the problem of messy optical fiber wiring is solved, achieving precise workpiece transmission and cost reduction.

CN224449178UActive Publication Date: 2026-07-03SHANGHAI GOLYTEC AUTOMATION CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI GOLYTEC AUTOMATION CO LTD
Filing Date
2025-07-21
Publication Date
2026-07-03

AI Technical Summary

Technical Problem

When there is a branched stator in the transmission line, the fiber optic cable threading sequence becomes complicated, leading to confusion and increased costs.

Method used

By setting up a bifurcated stator, a first straight stator, and a second straight stator, and connecting the optical fibers in series sequentially, the wiring order is optimized to achieve the merging and splitting of the current in the mover.

Benefits of technology

It effectively improves the problem of messy fiber optic cable installation, reduces the length of fiber optic cables used, and reduces costs.

✦ Generated by Eureka AI based on patent content.

Smart Images

  • Figure CN224449178U_ABST
    Figure CN224449178U_ABST
Patent Text Reader

Abstract

This application provides a transmission line comprising a branched stator, a first straight stator, a second straight stator, and an optical fiber. The branched stator includes a merging end, a first shunting end, and a second shunting end. A mover can shun current from the merging end to either the first shunting end or the second shunting end, or merge current from the first shunting end and the second shunting end to the merging end. The first straight stator is connected to the merging end; the second straight stator is connected to the first shunting end; and the optical fiber connects the first straight stator, the branched stator, and the second straight stator in series. This structural design optimizes the fiber optic cable threading sequence, effectively improving the problem of messy fiber optic cable threading and thus reducing costs.
Need to check novelty before this filing date? Find Prior Art

Description

Technical Field

[0001] This application relates to the field of conveying devices, and more particularly to a transmission line. Background Technology

[0002] In related technologies, transmission lines typically consist of multiple spliced ​​stators. To fulfill the communication function of the transmission line, fiber optic cables are usually connected in series with the stators. To broaden the applications of the transmission line and meet the needs of workpiece sorting and convergence operations within the line, branched stators are often incorporated to enable splitting and merging functions. However, the presence of branched stators complicates the threading sequence of the fiber optic cables when connecting them to the stators, leading to chaotic and disordered cable threading. This can result in overuse of fiber optic cables, thereby increasing costs. Utility Model Content

[0003] This application provides a transmission line designed to improve the wiring problem of optical fiber lines when there is a branched stator in the transmission line.

[0004] This application provides a transmission line, including:

[0005] The bifurcated stator includes a confluence end, a first branch end, and a second branch end. The mover can branch from the confluence end to the first branch end or the second branch end, or merge from the first branch end and the second branch end to the confluence end.

[0006] The first linear stator is spliced ​​with the confluence end;

[0007] The second linear stator is spliced ​​with the first shunt end; and

[0008] An optical fiber is used to connect the first straight stator, the bifurcated stator, and the second straight stator in series.

[0009] In some embodiments, the bifurcated stator includes an intermediate bifurcated stator located in the middle of the transmission line, and the transmission line further includes a third straight stator spliced ​​with the second shunt end;

[0010] The optical fiber connects the first straight stator, the intermediate bifurcated stator, the second straight stator, and the third straight stator in series.

[0011] In some embodiments, the number of intermediate bifurcated stators is at least two;

[0012] The transmission line further includes a first intermediate straight stator, which is disposed between the third straight stator and the first straight stator adjacent to the third straight stator.

[0013] The optical fiber connects the third linear stator, the first intermediate linear stator, and the first linear stator in series.

[0014] In some embodiments, the bifurcated stator further includes a first-end bifurcated stator located at the beginning of the transmission line, and the transmission line further includes a fourth straight stator and a fifth straight stator, wherein the fourth straight stator is spliced ​​with the confluence end of the first-end bifurcated stator, and the fifth straight stator is spliced ​​with the first shunting end of the first-end bifurcated stator;

[0015] The optical fiber connects the fourth linear stator, the first-end bifurcated stator, and the fifth linear stator in series.

[0016] In some embodiments, the transmission line further includes a second intermediate straight stator disposed between the fifth straight stator and the first straight stator adjacent to the fifth straight stator;

[0017] The optical fiber connects the fifth linear stator, the second intermediate linear stator, and the first linear stator in series.

[0018] In some embodiments, the transmission line is a multilayer transmission line, which includes at least an upper layer transmission line and a lower layer transmission line;

[0019] The optical fiber line connects the fourth straight stator, the first-end bifurcated stator, the fifth straight stator, the second intermediate straight stator, the first straight stator, the intermediate bifurcated stator, the second straight stator, the third straight stator, and the first intermediate straight stator located on the upper transmission line in series, and then connects the first intermediate straight stator, the first straight stator, the intermediate bifurcated stator, the second straight stator, and the third straight stator located on the lower transmission line in series.

[0020] In some embodiments, the lower transmission line further includes an end-branching stator located at the end of the lower transmission line, and the lower transmission line further includes a sixth straight stator and a seventh straight stator, wherein the sixth straight stator is spliced ​​to the confluence end of the end-branching stator, and the seventh straight stator is spliced ​​to the first shunting end of the end-branching stator;

[0021] The optical fiber connects the sixth straight stator, the end-branched stator, and the seventh straight stator in series.

[0022] In some embodiments, the lower transmission line further includes a third intermediate straight stator disposed between the sixth straight stator and the third straight stator adjacent to the sixth straight stator;

[0023] The optical fiber connects the third straight stator, the end-branched stator, and the sixth straight stator in series.

[0024] In some embodiments, the first-end bifurcated stator in the upper transmission line and the last-end bifurcated stator in the lower transmission line are arranged vertically opposite each other.

[0025] In some embodiments, the intermediate bifurcated stator in the upper transmission line is arranged vertically opposite to the intermediate bifurcated stator in the lower transmission line.

[0026] Based on the above structural configuration, this application establishes a bifurcated stator, a first linear stator, and a second linear stator. The first linear stator and the bifurcated stator are joined at their merging ends to achieve current merging of the moving part; the second linear stator and the first branching end of the bifurcated stator are joined to achieve current branching of the moving part. In other words, depending on the workpiece carried by the moving part, current merging or branching is achieved through the bifurcated stator, thereby enabling precise workpiece transmission. Furthermore, this application connects the first linear stator, the bifurcated stator, and the second linear stator sequentially in series using optical fiber lines, optimizing the fiber optic cable threading sequence, effectively improving the problem of messy fiber optic cable threading, and thus reducing costs. Attached Figure Description

[0027] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0028] Figure 1 This is a schematic diagram of the transmission line structure in one embodiment of this application. Figure 1 ;

[0029] Figure 2 This is a schematic diagram of the transmission line structure in one embodiment of this application. Figure 2 .

[0030] Explanation of reference numerals in the attached figures:

[0031] 1. Transmission line; 1a. Upper layer transmission line; 1b. Lower layer transmission line; 10. Bifurcation stator; 11. Intermediate bifurcation stator; 12. First-end bifurcation stator; 13. End-end bifurcation stator; 21. First straight stator; 22. Second straight stator; 23. Third straight stator; 24. Fourth straight stator; 25. Fifth straight stator; 26. Sixth straight stator; 27. Seventh straight stator; 30. Optical fiber; 41. First intermediate straight stator; 42. Second intermediate straight stator; 43. Third intermediate straight stator; 50. Power line. Detailed Implementation

[0032] To make the objectives, technical solutions, and advantages of this application clearer, the following detailed description is provided in conjunction with the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative and not intended to limit the scope of this application.

[0033] In related technologies, transmission line 1 typically includes multiple spliced ​​stators. To fulfill the communication function of transmission line 1, fiber optic cables 30 are usually used to connect the stators in series. To enrich the applications of transmission line 1 and meet the needs of workpiece sorting and aggregation operations within transmission line 1, branched stators 10 are usually set in transmission line 1 to realize the splitting and aggregation functions of transmission line 1. However, when branched stators 10 are present in transmission line 1, the threading sequence of fiber optic cables 30 connected to the stators becomes complicated, resulting in messy and disordered threading of fiber optic cables 30, which can easily lead to overuse of fiber optic cables 30 and thus increase costs.

[0034] To address the aforementioned problems, this application provides a transmission line 1, which is primarily used for transporting workpieces. The transmission line 1 includes, but is not limited to, belt transmission lines, chain transmission lines, spiral transmission lines, magnetic drive transmission lines, etc., and this application does not specifically limit its application to any particular type. In this embodiment, a magnetic drive transmission line is used as an example for illustration.

[0035] Magnetic drive transmission lines utilize magnetic fields for power transmission. Compared to mechanical transmission devices such as belt and chain transmission lines, magnetic drive transmission lines do not require mechanical contact, resulting in lower wear and maintenance costs and a longer equipment lifespan. Due to these advantages, magnetic drive transmission lines are widely used in precision manufacturing, medical device manufacturing, food processing, automotive manufacturing, logistics, and warehousing.

[0036] Magnetic drive transmission lines typically consist of a conveyor body and a mover. The mover, as a load-bearing component, stably supports and transports the product and usually contains a permanent magnet or electromagnet. The conveyor body is equipped with linear windings. When the permanent magnet or electromagnet on the mover magnetically couples with the linear windings on the conveyor body, the mover can move along the transport direction of the conveyor body under the influence of the magnetic field generated by the coil, thereby realizing the transport of the workpiece.

[0037] Please refer to the following: Figure 1 and Figure 2 The transmission line 1 includes a bifurcated stator 10, a first linear stator 21, and a second linear stator 22.

[0038] The bifurcated stator 10 includes a merging end, a first splitting end, and a second splitting end. The transmission directions of the first splitting end and the second splitting end are different. The mover can split from the merging end to the first splitting end or the second splitting end, or merge from the first splitting end and the second splitting end to the merging end. Understandably, the bifurcated stator 10 enables the mover to merge or split in different transmission directions, thereby achieving flexible switching of the mover between different paths.

[0039] The first linear stator 21 is spliced ​​with the confluence end, which enables the mover on the first linear stator 21 to move to the first or second shunt end to achieve the shunt operation of the mover; and also enables the mover on the first or second shunt end to move to the first linear stator 21 through the confluence end, so that after the mover moves to the confluence end, it continues to move on the transmission line 1 along the transmission direction of the first linear stator 21.

[0040] The second linear stator 22 is connected to the first shunt end. In this way, the mover on the second linear stator 22 can move to the merging end to realize the merging and transmission operation of the mover from the first shunt end to the merging end; and the mover on the merging end can move to the second linear stator 22 through the first shunt end, so that after moving to the first shunt end, the mover continues to move along the transmission direction of the second linear stator 22 on the transmission line 1.

[0041] Please see Figure 1 and Figure 2 The transmission line 1 also includes an optical fiber line 30, which connects the first linear stator 21, the branched stator 10, and the second linear stator 22 in series. It should be understood that the optical fiber line 30 is used to transmit signals so as to monitor the position, power on / off status, and other information of the first linear stator 21, the branched stator 10, and the second linear stator 22 in real time, and can also realize the communication function between stators.

[0042] Based on the above structural configuration, this application sets up a bifurcated stator 10, a first linear stator 21, and a second linear stator 22. The first linear stator 21 is spliced ​​with the confluence end of the bifurcated stator 10 to achieve the confluence of the moving parts; the second linear stator 22 is spliced ​​with the first shunting end of the bifurcated stator 10 to achieve the shunting of the moving parts. That is, depending on the workpiece carried by the moving parts, the bifurcated stator 10 can be used to confluence or shun the moving parts, thereby achieving precise transmission of the workpiece. In addition, this application also uses an optical fiber line 30 to connect the first linear stator 21, the bifurcated stator 10, and the second linear stator 22 in series, optimizing the threading sequence of the optical fiber line 30, effectively improving the problem of messy threading of the optical fiber line 30, and thus achieving the effect of reducing costs.

[0043] Please see Figure 1 In some embodiments, the bifurcated stator 10 includes a middle bifurcated stator 11, which is located at the middle position of the transmission line 1. The transmission line 1 also includes a third straight stator 23, which is spliced ​​with the second shunt end. In this way, the mover on the third straight stator 23 can move to the merging end to realize the merging transmission operation of the mover from the second shunt end to the merging end; and the mover on the merging end can move to the third straight stator 23 through the second shunt end, so that after moving to the second shunt end, the mover continues to move along the transmission direction of the third straight stator 23 on the transmission line 1.

[0044] Understandably, when there is an intermediate bifurcated stator 11 in the transmission line 1, the merging end of the intermediate bifurcated stator 11 is connected to the first straight stator 21, the first splitting end is connected to the second straight stator 22, and the second splitting end is connected to the third straight stator 23. In this way, by setting the intermediate bifurcated stator 11, the moving parts in the transmission line 1 can be merged or split, thereby achieving precise transmission of the workpiece.

[0045] For example, the intermediate bifurcated stator 11 can be used for sorting workpieces during secondary processing. In some embodiments, the workpiece carried by the mover can be detected by a visual recognition device. If it is detected that the workpiece does not require secondary processing, the first linear stator 21, the intermediate bifurcated stator 11, and the third linear stator 23 are magnetically coupled with the mover to drive the mover to the intermediate bifurcated stator 11. The coil between the second shunt end and the merging end of the intermediate bifurcated stator 11 is energized, so that the mover moves to the second shunt end and further moves to the third linear stator 23, thereby achieving workpiece sorting. Alternatively, if it is detected that the workpiece requires secondary processing, the first linear stator 21, the intermediate bifurcated stator 11, and the second linear stator 22 are magnetically coupled with the mover to drive the mover to the intermediate bifurcated stator 11. The coil between the first shunt end and the merging end of the intermediate bifurcated stator 11 is energized, so that the mover moves to the first shunt end and further moves to the second linear stator 22, thereby achieving workpiece sorting. It should be noted that this application does not specifically limit the aforementioned visual recognition technology device.

[0046] See Figure 1 and Figure 2 Furthermore, the fiber optic cable 30 connects the first straight stator 21, the intermediate branch stator 11, the second straight stator 22, and the third straight stator 23 in series. This configuration provides an orderly threading method for the fiber optic cable 30 when the intermediate branch stator 11 is present in the transmission line 1, optimizing the threading sequence of the fiber optic cable 30 at the intermediate branch stator 11, effectively improving the problem of messy threading of the fiber optic cable 30, thereby saving the length of the fiber optic cable 30 used and achieving cost reduction.

[0047] Continue reading Figure 1 and Figure 2 In some embodiments, the number of intermediate branch stators 11 is at least two. This allows for further diversion of the movers in the transmission line 1, helping to improve sorting accuracy. The transmission line 1 also includes a first intermediate straight stator 41, which is located between two adjacent intermediate branch stators 11 and between a third straight stator 23 and a first straight stator 21 adjacent to the third straight stator 23. The number of first intermediate straight stators 41 can be one, two, three, or other numbers; this application does not impose a specific limitation on this.

[0048] See Figure 1 and Figure 2Furthermore, the fiber optic cable 30 connects the third straight stator 23, the first intermediate straight stator 41, and the first straight stator 21 in series. This configuration provides an orderly threading method for the fiber optic cable 30 when multiple intermediate branch stators 11 exist in the transmission line 1. It optimizes the threading sequence of the fiber optic cable 30 at and between multiple intermediate branch stators 11, effectively improving the problem of messy threading in the fiber optic cable 30, thereby saving the length of the fiber optic cable 30 and reducing costs.

[0049] Please see Figure 2 In some embodiments, the bifurcated stator 10 further includes a first-end bifurcated stator 12, located at the first end of the transmission line 1. The transmission line 1 also includes a fourth linear stator 24 and a fifth linear stator 25. The fourth linear stator 24 is connected to the confluence end of the first-end bifurcated stator 12, and the fifth linear stator 25 is connected to the first shunt end of the first-end bifurcated stator 12. This allows the mover on the fourth linear stator 24 to perform shunt operation, while also allowing the mover entering the first shunt end of the first-end bifurcated stator 12 to continue moving along the transmission direction of the fifth linear stator 25 on the transmission line 1.

[0050] For example, the first-end bifurcated stator 12 can be used for sorting good and defective workpieces. In some embodiments, the workpiece carried by the mover can be detected by a visual recognition technology device. If the workpiece is detected as good, the fourth linear stator 24, the first-end bifurcated stator 12, and the fifth linear stator 25 are magnetically coupled with the mover to drive the mover to the first-end bifurcated stator 12. The coil between the first shunt end and the confluence end of the first-end bifurcated stator 12 is energized, so that the mover moves to the first shunt end and further to the fifth linear stator 25, thereby achieving workpiece sorting. Alternatively, if a defective workpiece is detected, the fourth linear stator 24, the first-end bifurcated stator 12, and the mover are magnetically coupled to drive the mover to the first-end bifurcated stator 12. The coil between the second shunt end and the confluence end of the first-end bifurcated stator 12 is energized, so that the mover moves to the second shunt end, thereby achieving workpiece sorting. It should be noted that this application does not specifically limit the aforementioned visual recognition technology device.

[0051] See Figure 2 Furthermore, the optical fiber 30 connects the fourth straight stator 24, the first-end branching stator 12, and the fifth straight stator 25 in series. This configuration provides an orderly threading method for the optical fiber 30 when the first-end branching stator 12 is present in the transmission line 1, optimizing the threading sequence of the optical fiber 30 at the first-end branching stator 12, effectively improving the problem of messy threading of the optical fiber 30, thereby saving the length of the optical fiber 30 used and achieving cost reduction.

[0052] Continue reading Figure 2In some embodiments, the transmission line 1 further includes a second intermediate straight stator 42, which is located between the first-end bifurcated stator 12 and the intermediate bifurcated stator 11, and is disposed between the fifth straight stator 25 and the first straight stator 21 adjacent to the fifth straight stator 25. The number of second intermediate straight stators 42 can be one, two, three, or other numbers, and this application does not impose a specific limitation on this.

[0053] See Figure 2 Furthermore, the fiber optic cable 30 connects the fifth straight stator 25, the second intermediate straight stator 42, and the first straight stator 21 in series. This configuration provides an orderly threading method for the fiber optic cable 30 when both the first-end branching stator 12 and the intermediate branching stator 11 exist in the transmission line 1. It optimizes the threading sequence of the fiber optic cable 30 between the first-end branching stator 12 and the intermediate branching stator 11, effectively improving the problem of messy threading in the fiber optic cable 30, thereby saving the length of the fiber optic cable 30 used and achieving cost reduction.

[0054] Please see Figure 2 In some embodiments, the bifurcated stator 10 further includes an end bifurcated stator 13, which is located at the end of the transmission line 1. The transmission line 1 also includes a sixth straight stator 26 and a seventh straight stator 27. The sixth straight stator 26 is connected to the confluence end of the end bifurcated stator 13, and the seventh straight stator 27 is connected to the first shunting end of the end bifurcated stator 13. In this way, the mover on the sixth straight stator 26 can perform shunting operations, and the mover entering the first shunting end of the end bifurcated stator 13 can continue to move along the transmission direction of the seventh straight stator 27 on the transmission line 1.

[0055] For example, the end-branched stator 13 can be used for sorting good and defective workpieces. In some embodiments, the workpiece carried by the mover can be detected by a visual recognition technology device. If the workpiece is detected as good, the sixth linear stator 26, the end-branched stator 13, and the seventh linear stator 27 are magnetically coupled to the mover to drive the mover to the end-branched stator 13, and the coil between the first shunt end and the confluence end of the end-branched stator 13 is energized, so that the mover moves to the first shunt end and further to the seventh linear stator 27, thereby achieving workpiece sorting. Alternatively, if a defective workpiece is detected, the sixth linear stator 26, the end-branched stator 13, and the mover are magnetically coupled to drive the mover to the end-branched stator 13, and the coil between the second shunt end and the confluence end of the end-branched stator 13 is energized, so that the mover moves to the second shunt end, thereby achieving workpiece sorting. It should be noted that the above-described visual recognition technology device is not specifically limited in this application.

[0056] See Figure 2Furthermore, the fiber optic cable 30 connects the sixth straight stator 26, the end-branching stator 13, and the seventh straight stator 27 in series. This configuration provides an orderly threading method for the fiber optic cable 30 when the end-branching stator 13 is present in the transmission line 1, optimizing the threading sequence of the fiber optic cable 30 at the end-branching stator 13, effectively improving the problem of messy threading of the fiber optic cable 30, thereby saving the length of the fiber optic cable 30 used and achieving cost reduction.

[0057] Continue reading Figure 2 In some embodiments, the transmission line 1 further includes a third intermediate straight stator 43, which is located between the intermediate bifurcated stator 11 and the end bifurcated stator 13, and is disposed between the sixth straight stator 26 and the third straight stator 23 adjacent to the sixth straight stator 26. The number of third intermediate straight stators 43 can be one, two, three, or other numbers, and this application does not impose a specific limitation on this.

[0058] See Figure 2 Furthermore, the fiber optic cable 30 connects the third straight stator 23, the end-branching stator 13, and the sixth straight stator 26 in series. This configuration provides an orderly wiring method for the fiber optic cable 30 when both the intermediate-branching stator 11 and the end-branching stator 13 are present in the transmission line 1. It optimizes the wiring sequence of the fiber optic cable 30 between the intermediate-branching stator 11 and the end-branching stator 13, effectively improving the problem of messy wiring in the fiber optic cable 30, thereby saving the length of the fiber optic cable 30 and reducing costs.

[0059] See also Figure 1 and Figure 2In some embodiments, transmission line 1 is a multi-layer transmission line, which is stacked vertically. The multi-layer transmission line has at least two layers, meaning it includes at least an upper transmission line 1a and a lower transmission line 1b. The upper transmission line 1a includes a first-end bifurcated stator 12 and a middle bifurcated stator 11, meaning it includes a fourth straight stator 24, a first-end bifurcated stator 12, a fifth straight stator 25, a second middle straight stator 42, a first straight stator 21, a middle bifurcated stator 11, a second straight stator 22, a third straight stator 23, and a first middle straight stator 41. The lower transmission line 1b includes a middle bifurcated stator 11 and an end bifurcated stator 13, meaning it includes a first middle straight stator 41, a first straight stator 21, a middle bifurcated stator 11, a second straight stator 22, and a third straight stator 23. With this configuration, both the upper transmission line 1a and the lower transmission line 1b can achieve the merging and splitting of the moving part, thereby improving the splitting efficiency of transmission line 1. At the same time, the upper transmission line 1a and the lower transmission line 1b are arranged vertically in the multi-layer transmission line, which can reduce the footprint of transmission line 1 and make transmission line 1 suitable for scenarios with limited area.

[0060] See Figure 2 Furthermore, the fiber optic cable 30 connects the fourth straight stator 24, the first-end branched stator 12, the fifth straight stator 25, the second intermediate straight stator 42, the first straight stator 21, the intermediate branched stator 11, the second straight stator 22, the third straight stator 23, and the first intermediate straight stator 41 located on the upper transmission line 1a in series, and then connects them in series with the first intermediate straight stator 41, the first straight stator 21, the intermediate branched stator 11, the second straight stator 22, and the third straight stator 23 located on the lower transmission line 1b. With this configuration, the stators of the multiple transmission lines are all connected in series through the same fiber optic cable 30, avoiding electromagnetic interference and signal attenuation when multiple fiber optic cables 30 run in parallel, ensuring the stability of data transmission, and contributing to improving the stability and reliability of the fiber optic communication system.

[0061] Please see Figure 2 In some embodiments, the first-end bifurcated stator 12 in the upper transmission line 1a and the last-end bifurcated stator 13 in the lower transmission line 1b are arranged vertically opposite each other. This arrangement allows the upper transmission line 1a and the lower transmission line 1b to split or merge at corresponding positions in the vertical direction, facilitating the determination of the placement of secondary processing equipment and other devices. Furthermore, only one secondary processing device needs to be placed at the same vertical position to complete the secondary processing operations on multiple transmission lines 1, further saving space and cost.

[0062] Please see Figure 1 and Figure 2In some embodiments, the intermediate branch stator 11 in the upper transmission line 1a and the intermediate branch stator 11 in the lower transmission line 1b are arranged vertically opposite each other. This arrangement allows the upper transmission line 1a and the lower transmission line 1b to split or merge at corresponding positions in the vertical direction, facilitating the determination of the placement locations of other equipment such as the defective product recycling device. Furthermore, only one defective product recycling device needs to be installed at the same vertical position to complete the defective product recycling operation for multiple transmission lines 1, further saving space and cost.

[0063] Please see Figure 1 and Figure 2 To ensure the normal operation of the stator in transmission line 1, in some embodiments, transmission line 1 further includes a power distribution module (not shown in the figure) and a power supply line 50. It is understood that the power distribution module can be connected to a 380V or 220V supply voltage; the power supply line 50 is electrically connected to the power distribution module. Multiple stators (including bifurcated stators 10 and linear stators) are sequentially electrically connected via the power supply line 50, so that the power distribution module supplies power to multiple stators. Furthermore, since the supply voltage of the power distribution module is limited and the power required by the stator is fixed, if the number of stators connected to the power supply line 50 is large, it can easily affect the voltage it provides. That is, the longer the power supply line 50 is, the greater its resistance, and the voltage input to the stator will decrease, reducing the reliability of the power supply. In this embodiment, multiple power distribution modules are provided, and each power distribution module supplies power to only multiple stators, ensuring that the power distribution module provides stable and safe power support to the stator, thereby ensuring the stable operation of the stator.

[0064] In the description of this application, it should be understood that if terms such as "upper," "lower," "left," "right," "front," and "rear" indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings, they are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, the terms used to describe positional relationships in the accompanying drawings are only for illustrative purposes and should not be construed as limiting this patent. For those skilled in the art, the specific meaning of the above terms can be understood according to the specific circumstances.

[0065] Furthermore, the terms "first" and "second" are used for descriptive purposes only and should not be construed as implying or suggesting relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include one or more of that feature. In the description of this application, "multiple" means at least two, such as two, three, etc., unless otherwise explicitly specified.

[0066] In the description of this application, unless otherwise expressly specified and limited, the terms "installation," "connection," "joining," "fixing," etc., should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral part; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; they can refer to the internal communication of two components or the interaction between two components, unless otherwise expressly limited. Those skilled in the art can understand the specific meaning of the above terms in this application according to the specific circumstances.

[0067] It should be noted that when an element is referred to as being "fixed to" or "set on" another element, it can be directly on the other element or there may be an intervening element. When an element is considered to be "connected to" another element, it can be directly connected to the other element or there may be an intervening element. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and similar expressions used herein are for illustrative purposes only and do not represent the only possible implementation.

[0068] The above description is merely a specific embodiment of this application, but the scope of protection of this application is not limited thereto. Any variations or substitutions that can be easily conceived by those skilled in the art within the scope of the technology disclosed in this application should be included within the scope of protection of this application. Therefore, the scope of protection of this application should be determined by the scope of the claims.

Claims

1. A transmission line, characterized by, include: The bifurcated stator includes a confluence end, a first branch end, and a second branch end. The mover can branch from the confluence end to the first branch end or the second branch end, or merge from the first branch end and the second branch end to the confluence end. The first linear stator is spliced ​​with the confluence end; The second linear stator is spliced ​​with the first shunt end; as well as An optical fiber is used to connect the first straight stator, the bifurcated stator, and the second straight stator in series.

2. The transmission line of claim 1, wherein, The bifurcated stator includes a middle bifurcated stator located in the middle of the transmission line, and the transmission line also includes a third straight stator, which is spliced ​​with the second shunt end; The optical fiber connects the first straight stator, the intermediate bifurcated stator, the second straight stator, and the third straight stator in series.

3. The transmission line of claim 2, wherein, The number of intermediate bifurcated stators is at least two; The transmission line further includes a first intermediate straight stator, which is disposed between the third straight stator and the first straight stator adjacent to the third straight stator. The optical fiber connects the third linear stator, the first intermediate linear stator, and the first linear stator in series.

4. The transmission line of claim 3, wherein, The bifurcated stator further includes a first bifurcated stator located at the beginning of the transmission line. The transmission line further includes a fourth straight stator and a fifth straight stator. The fourth straight stator is connected to the confluence end of the first bifurcated stator, and the fifth straight stator is connected to the first shunt end of the first bifurcated stator. The optical fiber connects the fourth linear stator, the first-end bifurcated stator, and the fifth linear stator in series.

5. The transmission line of claim 4, wherein, The transmission line further includes a second intermediate straight stator, which is disposed between the fifth straight stator and the first straight stator adjacent to the fifth straight stator; The optical fiber connects the fifth linear stator, the second intermediate linear stator, and the first linear stator in series.

6. The transmission line of claim 5, wherein, The transmission line is a multi-layer transmission line, which includes at least an upper transmission line and a lower transmission line. The optical fiber line connects the fourth straight stator, the first-end bifurcated stator, the fifth straight stator, the second intermediate straight stator, the first straight stator, the intermediate bifurcated stator, the second straight stator, the third straight stator, and the first intermediate straight stator located on the upper transmission line in series, and then connects the first intermediate straight stator, the first straight stator, the intermediate bifurcated stator, the second straight stator, and the third straight stator located on the lower transmission line in series.

7. The transmission line of claim 6, wherein, The lower transmission line also includes a terminal bifurcation stator located at the end of the lower transmission line, and the lower transmission line also includes a sixth straight stator and a seventh straight stator. The sixth straight stator is spliced ​​with the confluence end of the terminal bifurcation stator, and the seventh straight stator is spliced ​​with the first shunting end of the terminal bifurcation stator. The optical fiber connects the sixth straight stator, the end-branched stator, and the seventh straight stator in series.

8. The transmission line of claim 7, wherein, The lower transmission line also includes a third intermediate straight stator, which is disposed between the sixth straight stator and the third straight stator adjacent to the sixth straight stator. The optical fiber connects the third straight stator, the end-branched stator, and the sixth straight stator in series.

9. The transmission line of claim 7, wherein, The first-end bifurcated stator in the upper transmission line and the last-end bifurcated stator in the lower transmission line are arranged vertically opposite each other.

10. The transmission line of claim 6, wherein, The intermediate bifurcated stator in the upper transmission line is arranged vertically opposite to the intermediate bifurcated stator in the lower transmission line.