阅读说明：本技术 尖轨爬行监测系统及尖轨爬行监测方法 (Switch rail crawling monitoring system and switch rail crawling monitoring method ) 是由 刘志敏 孙延松 张家维 于 2020-04-21 设计创作，主要内容包括：本发明涉及一种尖轨爬行监测系统及尖轨爬行监测方法,将对齐线与第一尖轨的端部对准；对准后,定期对第一尖轨的端部分别与第一极限线、第二极限线的位置进行监测。当第一尖轨的端部偏离对齐线、并超出第一极限线或者第二极限线,需及时反馈,并对第一尖轨作出相应调整措施,以避免导致行车安全事故的发生。由于监测尺直接安装在第一基本轨上,因此,在检修过程中,作业人员无需携带笨重的测量仪器,使得检修过程变得更加轻松、便利。同时,将监测尺设置在第一基本轨上,当第一尖轨密贴在第一基本轨上时,第一尖轨的端部更加靠近监测尺,有利于准确读取第一尖轨端部在监测尺上的读数。此外,本尖轨爬行监测方法还具有维护工作量少、维修成本低。(The invention relates to a switch rail crawling monitoring system and a switch rail crawling monitoring method.A registration line is aligned with the end part of a first switch rail; after alignment, the position of the end of the first point rail is regularly monitored with respect to the first limit line and the second limit line, respectively. When the end part of the first switch rail deviates from the alignment line and exceeds the first limit line or the second limit line, timely feedback is needed, and corresponding adjustment measures are taken for the first switch rail so as to avoid traffic safety accidents. Because the monitoring ruler direct mount is on first stock rail, consequently, overhauls the in-process, the operation personnel need not to carry heavy measuring instrument for the maintenance process becomes lighter, convenient. Simultaneously, with the monitoring ruler setting on first stock rail, when first switch rail is closely pasted on first stock rail, the tip of first switch rail is close to the monitoring ruler more, is favorable to accurately reading the reading of first switch rail tip on the monitoring ruler. In addition, the switch rail crawling monitoring method has the advantages of less maintenance workload and low maintenance cost.)

1. A method for monitoring the creeping of a switch rail is characterized by comprising the following steps:

providing a monitoring ruler, and marking scale marks on the monitoring ruler as an alignment line, a first limit line and a second limit line respectively, wherein the first limit line and the second limit line are positioned on two opposite sides of the alignment line respectively, and the distance between the first limit line and the alignment line is a preset distance;

applying the monitoring ruler to a first stock rail and aligning the alignment line with an end of a first point rail;

after alignment, the position relationship between the end part of the first switch rail and the first limit line and the position relationship between the end part of the first switch rail and the second limit line are monitored, a first crawling amount is obtained, and the crawling condition of the first switch rail is judged.

2. The method of monitoring the crawling of the tongue rail as claimed in claim 1, wherein said step of applying said monitoring ruler to the first stock rail and aligning said alignment line with the end of the first tongue rail comprises:

fixing a base of the monitoring ruler on the first stock rail;

after the fixing, the ruler body of the monitoring ruler is arranged on the base in a sliding manner;

sliding the rule body so that the alignment line is aligned with an end of the first point rail;

after alignment, the ruler body is locked on the base through the locking piece.

3. The method for monitoring the crawling of the switch rail according to claim 2, wherein said steps further comprise:

adjusting the first point position when the end of the first point exceeds the first limit line or the second limit line;

after adjustment, unlocking the rule body and sliding the rule body so that the alignment line is aligned with the end of the first point rail;

after alignment, the ruler body is locked through the locking piece.

4. The method for monitoring the crawling of the tongue rail according to claim 1, wherein before the step of attaching said monitoring ruler to the first stock rail and aligning said alignment line with the end of the first tongue rail, it further comprises:

and carrying out rust removal operation on the first stock rail.

5. The method for monitoring the crawling of the tongue rail according to claim 1, wherein the step of attaching said monitoring ruler to the first stock rail and aligning said alignment line with the end of the first tongue rail further comprises:

and pulling the turnout to enable the first switch rail to approach the first stock rail and ensure that the lock hook on the first switch rail can be locked with the locking rod.

6. The method for monitoring the crawling of the switch blade according to claim 1, wherein the step of monitoring the position relationship between the end of the first switch blade and the first limit line and the position relationship between the end of the first switch blade and the second limit line respectively after the alignment to obtain a first crawling amount and judge the crawling condition of the first switch blade comprises the following steps:

extending or projecting one end of the first switch rail on the monitoring ruler by adopting an alignment tool to obtain a measuring position;

reading data of a measuring position on the monitoring ruler, acquiring the first crawling amount, and judging the crawling condition of the first switch rail according to the position relation among the reading position, the first limit line and the second limit line.

7. The method for monitoring the crawling of the switch blade according to claim 1, wherein said steps further comprise:

additionally providing a monitoring ruler, attaching the monitoring ruler on a second stock rail, and aligning an alignment line of the monitoring ruler with the end part of the second switch rail;

after alignment, monitoring the position relation between the end part of the second switch rail and the first limit line and the position relation between the end part of the second switch rail and the second limit line respectively, acquiring a second crawling amount, and judging the crawling condition of the second switch rail;

and combining and analyzing the first crawling amount and the second crawling amount to obtain the relative crawling amount of the switch rail.

8. The method for monitoring the crawling of the tongue rail according to claim 1,

if the end part of the first switch rail and the end part of the second switch rail are on the same side of the alignment line, the relative climbing amount of the switch rail is the difference between the first climbing amount and the second climbing amount, and the first switch rail and the second switch rail are judged to climb in the same direction;

and if the end part of the first switch rail and the end part of the second switch rail are both opposite to the aligning line, the relative crawling amount of the switch rail is the sum of the first crawling amount and the second crawling amount, and the first switch rail and the second switch rail are judged to crawl in opposite directions.

9. The method for monitoring the crawling of the switch blade according to any one of claims 1 to 8, wherein said predetermined distance is 18mm to 22 mm.

10. A monitoring system for the crawling of switch rails, characterized in that the monitoring method for the crawling of switch rails according to any one of claims 1 to 9 is adopted, and the monitoring system further comprises a first stock rail, a first switch rail and a monitoring ruler, wherein an alignment line, a first limit line and a second limit line are arranged on the monitoring ruler, the first limit line and the second limit line are positioned on two opposite sides of the alignment line, the monitoring ruler is attached to the first stock rail, and the alignment line is aligned with the end part of the first switch rail.

Technical Field

The invention relates to the technical field of switch rail crawling, in particular to a switch rail crawling monitoring system and a switch rail crawling monitoring method.

Background

The switch is a kind of line equipment for realizing locomotive running along different tracks, mainly including point switch, connecting portion, frog and guard rail. The switch is composed of stock rails, two switch points and a switch machine, wherein the two switch points are located between the two stock rails. When the switch machine is operated, one of the switch rails is driven to be closely attached to one stock rail, and the other switch rail is driven to be separated from the corresponding stock rail, so that the switching of different tracks of the locomotive is completed.

During switch operation, however, there is typically a point stick-slip condition, i.e., longitudinal displacement of the switch point relative to the stock rail. The main reasons for the tongue crawling are: firstly, bolts for fixing the switch rail are fewer, and the buckling pressure is insufficient; and secondly, when the turnout runs in a single direction and runs in a heavy vehicle in a single direction, the switch rail is seriously unbalanced in longitudinal force, and the switch rail on one side crawls. After the switch rail creeps, the limit device is pushed to be dead, the geometrical size below the switch rail cannot reach the standard, and the switch tie is scraped by the electric operating pull rod to be damaged, so that the safe operation of the switch is seriously influenced, and the orderly operation of lines is realized.

In order to find the crawling amount of the switch rail in time, an operator needs to carry a square ruler (the square ruler has the defects of being heavy and huge in the operation process and is not beneficial to carrying and using), a tape measure and other tools to measure the switch rail, or the switch rail is detected on the operation site according to camera monitoring equipment. However, these methods are difficult to carry and cannot accurately determine whether the crawling amount is within the specified range; or increase maintenance workload and equipment maintenance cost.

Disclosure of Invention

On the basis, a need exists for providing a switch rail crawling monitoring system and a switch rail crawling monitoring method, which can accurately judge whether the crawling amount of the switch rail is within a specified range; meanwhile, the operation is simple and the maintenance is convenient.

A method for monitoring the creeping of a switch rail comprises the following steps: providing a monitoring ruler, and marking scale marks on the monitoring ruler as an alignment line, a first limit line and a second limit line respectively, wherein the first limit line and the second limit line are positioned on two opposite sides of the alignment line respectively, and the distance between the first limit line and the alignment line is a preset distance; applying the monitoring ruler to a first stock rail and aligning the alignment line with an end of a first point rail; after alignment, the position relationship between the end part of the first switch rail and the first limit line and the position relationship between the end part of the first switch rail and the second limit line are monitored, a first crawling amount is obtained, and the crawling condition of the first switch rail is judged.

In the switch rail crawling monitoring method, the monitoring ruler is attached to the first stock rail, and the alignment line is aligned with the end part of the first switch rail; after alignment, the position of the end of the first point rail is regularly monitored with respect to the first limit line and the second limit line, respectively. When the end of the first point rail is offset from the alignment line and between the alignment line and the first limit line; or when the first switch rail is positioned between the alignment line and the second limit line, the first switch rail can be judged to creep, but the creep amount does not exceed the preset distance and is still in the allowable range; when the end part of the first switch rail deviates from the alignment line and exceeds the first limit line or the second limit line, namely, the end part is positioned on one side of the first limit line back to the alignment line, or the end part is positioned on one side of the second limit line back to the alignment line, the first switch rail is judged to have crawled, and the crawl amount exceeds an allowable range, at the moment, timely feedback is needed, and corresponding adjustment measures are taken for the first switch rail, so that the occurrence of traffic safety accidents is avoided. Because the monitoring ruler direct mount is on first stock rail, consequently, overhauls the in-process, the operation personnel need not to carry heavy measuring instrument for the maintenance process becomes lighter, convenient. Meanwhile, the monitoring ruler is arranged on the first stock rail, and when the first switch rail is closely attached to the first stock rail, the end part of the first switch rail is closer to the monitoring ruler, so that an operator can accurately read the reading of the end part of the first switch rail on the monitoring ruler, and the crawling condition of the first switch rail can be accurately judged. In addition, the switch rail crawling monitoring method has the advantages of less maintenance workload and low maintenance cost, and is beneficial to being widely popularized in turnout operation.

In one embodiment, the step of applying the monitoring tape to the first stock rail and aligning the alignment line with the end of the first point rail comprises: fixing a base of the monitoring ruler on the first stock rail; after the fixing, the ruler body of the monitoring ruler is arranged on the base in a sliding manner; sliding the rule body so that the alignment line is aligned with an end of the first point rail; after alignment, the ruler body is locked on the base through the locking piece.

In one embodiment, the steps further include: adjusting the first point position when the end of the first point exceeds the first limit line or the second limit line; after adjustment, unlocking the rule body and sliding the rule body so that the alignment line is aligned with the end of the first point rail; after alignment, the ruler body is locked through the locking piece.

In one embodiment, the step of attaching the monitoring ruler to the first stock rail and aligning the alignment line with the end of the first point rail further comprises: and carrying out rust removal operation on the first stock rail.

In one embodiment, after the step of attaching the monitoring ruler to the first stock rail and aligning the alignment line with the end of the first point rail, the method further comprises: and pulling the turnout to enable the first switch rail to approach the first stock rail and ensure that the lock hook on the first switch rail can be locked with the locking rod.

In one embodiment, after the aligning, the step of monitoring a position relationship between the end of the first switch rail and the first limit line and the second limit line, respectively, obtaining a first crawling amount, and determining a crawling status of the first switch rail includes: extending or projecting one end of the first switch rail on the monitoring ruler by adopting an alignment tool to obtain a measuring position; reading data of a measuring position on the monitoring ruler, acquiring the first crawling amount, and judging the crawling condition of the first switch rail according to the position relation among the reading position, the first limit line and the second limit line.

In one embodiment, the steps further comprise: additionally providing a monitoring ruler, attaching the monitoring ruler on a second stock rail, and aligning an alignment line of the monitoring ruler with the end part of the second switch rail; after alignment, monitoring the position relation between the end part of the second switch rail and the first limit line and the position relation between the end part of the second switch rail and the second limit line respectively, acquiring a second crawling amount, and judging the crawling condition of the second switch rail; and combining and analyzing the first crawling amount and the second crawling amount to obtain the relative crawling amount of the switch rail.

In one embodiment, if the end of the first switch rail and the end of the second switch rail are both on the same side of the alignment line, the relative climbing amount of the switch rail is the difference between the first climbing amount and the second climbing amount, and it is determined that the first switch rail and the second switch rail climb in the same direction; and if the end part of the first switch rail and the end part of the second switch rail are both opposite to the aligning line, the relative crawling amount of the switch rail is the sum of the first crawling amount and the second crawling amount, and the first switch rail and the second switch rail are judged to crawl in opposite directions.

In one embodiment, the predetermined distance is 18mm to 22 mm.

The switch rail crawling monitoring system further comprises a first base rail, a first switch rail and a monitoring ruler, wherein the monitoring ruler is provided with an alignment line, a first limit line and a second limit line, the first limit line and the second limit line are located on two opposite sides of the alignment line, the monitoring ruler is attached to the first base rail, and the alignment line is aligned with the end portion of the first switch rail.

The switch rail crawling monitoring system adopts the switch rail crawling monitoring method, the monitoring ruler is attached to the first stock rail, and the alignment line is aligned with the end part of the first switch rail; after alignment, the position of the end of the first point rail is regularly monitored with respect to the first limit line and the second limit line, respectively. When the end of the first point rail is offset from the alignment line and between the alignment line and the first limit line; or when the first switch rail is positioned between the alignment line and the second limit line, the first switch rail can be judged to creep, but the creep amount does not exceed the preset distance and is still in the allowable range; when the end part of the first switch rail deviates from the alignment line and exceeds the first limit line or the second limit line, namely, the end part is positioned on one side of the first limit line back to the alignment line, or the end part is positioned on one side of the second limit line back to the alignment line, the first switch rail is judged to have crawled, and the crawl amount exceeds an allowable range, at the moment, timely feedback is needed, and corresponding adjustment measures are taken for the first switch rail, so that the occurrence of traffic safety accidents is avoided. Because the monitoring ruler direct mount is on first stock rail, consequently, overhauls the in-process, the operation personnel need not to carry heavy measuring instrument for the maintenance process becomes lighter, convenient. Meanwhile, the monitoring ruler is arranged on the first stock rail, and when the first switch rail is closely attached to the first stock rail, the end part of the first switch rail is closer to the monitoring ruler, so that an operator can accurately read the reading of the end part of the first switch rail on the monitoring ruler, and the crawling condition of the first switch rail can be accurately judged. In addition, the switch rail crawling monitoring method has the advantages of less maintenance workload and low maintenance cost, and is beneficial to being widely popularized in turnout operation.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, illustrate embodiments of the invention and, together with the description, serve to explain the invention and not to limit the invention.

In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments 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 to obtain other drawings based on these drawings without creative efforts.

FIG. 1 is a first flowchart of a method for monitoring blade creep according to an embodiment;

FIG. 2 is a flow chart of a point rail crawling monitoring method according to an embodiment;

fig. 3 is a flow chart of a switch rail crawling monitoring method according to an embodiment;

FIG. 4 is a flow chart of a point rail crawling monitoring method according to an embodiment;

FIG. 5 is a flow chart of a method for monitoring blade creep according to an embodiment;

FIG. 6 is a flow chart of a method for monitoring blade creep according to an embodiment;

FIG. 7 is a schematic diagram of a blade creep monitoring system according to an embodiment;

FIG. 8 is a perspective view of a monitoring ruler configuration according to an embodiment;

fig. 9 is another perspective view of the monitoring ruler structure according to an embodiment.

100. A first stock rail, 200, a first point rail, 300, a monitoring ruler, 310, a base, 320, a ruler body, 321, an alignment line, 322, a first limit line, 323, a second limit line, 330, a locking member, 400, a second stock rail, 500, a second point rail.

Detailed Description

In order to make the aforementioned objects, features and advantages of the present invention comprehensible, embodiments accompanied with figures are described in detail below. In the following description, numerous specific details are set forth in order to provide a thorough understanding of the present invention. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein.

In the description of the present invention, it is to be understood that the terms "central," "longitudinal," "lateral," "length," "width," "thickness," "upper," "lower," "front," "rear," "left," "right," "vertical," "horizontal," "top," "bottom," "inner," "outer," "clockwise," "counterclockwise," "axial," "radial," "circumferential," and the like are used in the orientations and positional relationships indicated in the drawings for convenience in describing the invention and to simplify the description, and are not intended to indicate or imply that the referenced device or element must have a particular orientation, be constructed and operated in a particular orientation, and are not to be considered limiting of the invention.

Furthermore, the terms "first", "second" and "first" are used for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In the description of the present invention, "a plurality" means at least two, e.g., two, three, etc., unless specifically limited otherwise.

In the present invention, unless otherwise expressly stated or limited, the terms "mounted," "connected," "secured," and the like are to be construed broadly and can, for example, be fixedly connected, detachably connected, or integrally formed; can be mechanically or electrically connected; they may be directly connected or indirectly connected through intervening media, or they may be connected internally or in any other suitable relationship, unless expressly stated otherwise. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

In the present invention, unless otherwise expressly stated or limited, the first feature "on" or "under" the second feature may be directly contacting the first and second features or indirectly contacting the first and second features through an intermediate. Also, a first feature "on," "over," and "above" a second feature may be directly or diagonally above the second feature, or may simply indicate that the first feature is at a higher level than the second feature. A first feature being "under," "below," and "beneath" a second feature may be directly under or obliquely under the first feature, or may simply mean that the first feature is at a lesser elevation than the second feature.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "upper," "lower," "left," "right," and the like as used herein are for illustrative purposes only and do not denote a unique embodiment.

In one embodiment, referring to fig. 1 and 7, a method for monitoring the creeping of the tongue rail includes the following steps:

s10, providing the monitoring ruler 300, and marking the scale marks on the monitoring ruler 300 as an alignment line 321, a first limit line 322, and a second limit line 323, wherein the first limit line 322 and the second limit line 323 are respectively located at two opposite sides of the alignment line 321, and the distances from the alignment line 321 are preset distances;

s20, attaching the monitoring ruler 300 to the first stock rail 100 and aligning the alignment line 321 with the end of the first point rail 200;

s30, after alignment, the position relationship between the end of the first switch rail 200 and the first limit line 322 and the second limit line 323 is monitored, a first crawling amount is obtained, and the crawling status of the first switch rail 200 is determined.

In the above-described switch rail crawling monitoring method, the monitoring ruler 300 is attached to the first stock rail 100, and the alignment line 321 is aligned with the end of the first switch rail 200; after the alignment, the positions of the end portions of the first point rail 200 and the first limit line 322 and the second limit line 323 are periodically monitored. When the end of the first point rail 200 is offset from the alignment line 321 and is located between the alignment line 321 and the first limit line 322; alternatively, when the first switch rail 200 is located between the alignment line 321 and the second limit line 323, it may be determined that the first switch rail 200 has crawled, but the crawl amount does not exceed the preset distance and still stays within the allowable range; when the end of the first point rail 200 deviates from the alignment line 321 and exceeds the first limit line 322 or the second limit line 323, that is, is located on the side of the first limit line 322 facing away from the alignment line 321, or is located on the side of the second limit line 323 facing away from the alignment line 321, it is determined that the first point rail 200 has climbed and the amount of climbed exceeds the allowable range, and at this time, timely feedback is required and corresponding adjustment measures are taken for the first point rail 200 to avoid occurrence of traffic safety accidents. Because the monitoring ruler 300 is directly installed on the first stock rail 100, in the maintenance process, an operator does not need to carry a heavy measuring instrument, so that the maintenance process becomes easier and more convenient. Meanwhile, the monitoring ruler 300 is arranged on the first stock rail 100, and when the first switch rail 200 is closely attached to the first stock rail 100, the end of the first switch rail 200 is closer to the monitoring ruler 300, so that an operator can accurately read the reading of the end of the first switch rail 200 on the monitoring ruler 300, and the crawling condition of the first switch rail 200 can be accurately judged. In addition, the switch rail crawling monitoring method has the advantages of less maintenance workload and low maintenance cost, and is beneficial to being widely popularized in turnout operation.

It should be noted that aligning the alignment line 321 with the end of the first point rail 200 should be understood as: the end of the first point rail 200 is projected or extended onto the monitoring ruler 300 along the vertical direction of the vertical monitoring ruler 300, and the projected line or the extended line is overlapped with the alignment line 321.

It should be noted that, when the creep amount of the first point rail 200 exceeds the allowable range, a corresponding adjustment measure needs to be performed on the first point rail 200. The adjustment means is to return the first point rail 200 to the initial position and to adjust the fixing means of the first point rail 200 accordingly, thereby preventing the first point rail 200 from repeatedly creeping. Of course, as to how to specifically pull the first point rail 200 and adjust the fixing means of the first point rail 200, reference is made to the prior art and no specific description is given here.

Alternatively, the predetermined distance may be determined according to the requirements of the switch blade creep specifications, such as: the predetermined distance may be 18mm to 22 mm.

Specifically, the preset distance is 20 mm. Meanwhile, the monitoring ruler 300 is specifically installed on the rail web of the first stock rail 100, and is installed on a side of the first stock rail 100 facing the first point rail 200.

Further, referring to fig. 2, 7 and 8, the step of attaching the monitoring ruler 300 to the first stock rail 100 and aligning the alignment line 321 with the end of the first point rail 200S 20 includes: fixing the base 310 of the monitoring ruler 300 on the first stock rail 100S 21; after the fixation, slidably mounting the scale body 320 of the monitoring scale 300 on the base 310S 22; sliding the rule body 320 such that the alignment line 321 is aligned with the end of the first point rail 200S 23; after alignment, the rule body 320 is locked to the base 310 by the locking member 330S 24. Therefore, the monitoring ruler 300 of the present embodiment is an adjustable structure. During installation, the base 310 is secured to the first stock rail 100; the scale body 320 is then slidably mounted on the base 310. Thus, in the alignment process of the end portion of the first point rail 200 and the alignment line 321, the accurate alignment of the alignment line 321 and the end portion of the first point rail 200 can be ensured only by sliding the ruler body 320, and the installation convenience of the monitoring ruler 300 is greatly improved. Meanwhile, after the first point rail 200 is crawled and readjusted, the end of the first point rail 200 is more or less deviated from the alignment line 321, and therefore, the present embodiment only needs to fine tune the ruler body 320, and does not need to tear off the whole structure of the monitoring ruler 300 again and then reinstall and align the monitoring ruler.

It should be noted that, in the present embodiment, how the ruler body 320 is slidably mounted on the base 310 is not specifically limited, and only the ruler body 320 can slide on the base 310. Such as: the ruler body 320 is provided with a guide bar, and the base 310 is provided with a guide groove; or the ruler body 320 is provided with a guide groove, and the base 310 is provided with a guide strip.

Optionally, retaining member 330 is a bolt, screw, pin, rivet, or other retaining member. Meanwhile, the base 310 may be mounted on the first stock rail 100 by means of bonding, welding, bolting, pinning, clamping, etc.

In an embodiment, referring to fig. 3, fig. 7 and fig. 8, the steps further include: adjusting the position S40 of the first point 200 when the end of the first point 200 exceeds the first limit line 322 or the second limit line 323; after the adjustment, the rule body 320 is unlocked and the rule body 320 is slid so that the alignment line 321 is aligned with the end of the first point rail 200S 50; after alignment, the rule body 320 is locked by the locking member 330S 60. It can be seen that, when the first point rail 200 is adjusted, the alignment line 321 can be accurately aligned with the end of the first point rail 200 only by sliding the ruler body 320 on the base 310.

In one embodiment, referring to fig. 4 and 7, before the steps of attaching the monitoring ruler 300 to the first stock rail 100 and aligning the alignment line 321 with the end of the first switch rail 200, the method further includes: the first stock rail 100 is subjected to a rust removing operation. Thus, before installation, the first stock rail 100 is derusted, ensuring that the monitoring ruler 300 is stably installed on the first stock rail 100; at the same time, flatness on the first stock rail 100 is also ensured, so that the reading of the end of the first point rail 200 on the monitoring ruler 300 is more accurate.

Specifically, during installation, the web of the first stock rail 100 is sanded using sandpaper to remove rust from the first stock rail 100. After the rust removal, the monitoring ruler 300 is stuck on the first stock rail 100.

In one embodiment, referring to fig. 4 and 7, after the steps of attaching the monitoring ruler 300 to the first stock rail 100 and aligning the alignment line 321 with the end of the first switch rail 200S 20, the method further includes: the switch is pulled so that the first point 200 is drawn toward the first stock rail 100 and the shackle on the first point 200 is secured to the lock bar S25. In this way, it is ensured that the locking of the first point rail 200 is not affected after the monitoring ruler 300 has been mounted on the first stock rail 100.

In one embodiment, referring to fig. 5 and 7, after aligning, the steps of monitoring the position relationship between the end of the first point rail 200 and the first limit line 322 and the second limit line 323 respectively, obtaining the first crawling amount, and determining the crawling status S20 of the first point rail 200 include: extending or projecting one end of the first point rail 200 on the monitoring ruler 300 using the alignment tool to obtain a measurement site S26; the data of the measuring bit on the monitoring ruler 300 is read, the first crawling amount is obtained, and the crawling state of the first switch rail 200 is judged according to the position relationship among the reading bit, the first limit line 322 and the second limit line 323S 27. Thus, the creep amount of the first switch rail 200 is accurately read, and the creep condition of the first switch rail 200 is more accurately judged.

Alternatively, the alignment tool may be a square or a laser infrared rangefinder. When the alignment tool is a square, one side of the square is attached to the end of the first point rail 200 and the other side is attached to the monitoring ruler 300, so that by using the square, the end of the first point rail 200 is extended to the monitoring ruler 300, and a first crawling amount can be obtained by reading the reading of the right angle of the square on the monitoring ruler 300. When the alignment tool is a laser infrared distance meter, the end of the first switch rail 200 is projected on the monitoring ruler 300 through a laser line, and the first crawling amount can be accurately read.

In one embodiment, referring to fig. 6 and 7, the steps further include: additionally providing a monitoring ruler 300, attaching the monitoring ruler 300 to the second stock rail 400, and aligning the alignment line 321 of the monitoring ruler 300 with the end of the second point rail 500S 70; after the alignment, monitoring the position relationship between the end of the second switch rail 500 and the first limit line 322 and the second limit line 323 respectively, obtaining a second crawling amount, and determining the crawling state of the second switch rail 500S 80; and (4) analyzing the first crawling amount and the second crawling amount in a combined manner to obtain the relative crawling amount of the switch rail S90. As can be seen, the present embodiment provides two monitoring rulers 300 for monitoring the independent creeping states of the first point rail 200 and the second point rail 500, respectively. And meanwhile, acquiring the relative crawling amount of the switch rail according to the comprehensive analysis of the acquired first crawling amount and the acquired second crawling amount.

Note that the second stock rail 400 may be descaled before the monitoring gauge 300 is mounted on the second stock rail 400. Meanwhile, the monitoring ruler 300 installed on the second stock rail 400 may also adopt a combined structure of the base 310 and the ruler body 320.

Further, referring to fig. 7, if the end of the first switch rail 200 and the end of the second switch rail 500 are both on the same side of the alignment line 321, the relative climbing amount of the switch rail is the difference between the first climbing amount and the second climbing amount, and it is determined that the first switch rail 200 and the second switch rail 500 climb in the same direction; if the end of the first point rail 200 and the end of the second point rail 500 are both opposite sides of the alignment line 321, the relative amount of the point rail climbs is the sum of the first amount of the creep and the second amount of the creep, and it is determined that the first point rail 200 and the second point rail 500 crawl in opposite directions. Therefore, when analyzing the respective crawling conditions of the first switch rail 200 and the second switch rail 500, the relative crawling amount of the switch rail can be comprehensively analyzed through the first crawling amount and the second crawling amount, that is, when the first switch rail 200 and the second switch rail 500 crawl in different directions, the relative crawling amount of the switch rail is the sum of the first crawling amount and the second crawling amount, and if the relative crawling amount of the switch rail also exceeds a specified range, the first switch rail 200 and the second switch rail 500 also need to be correspondingly adjusted. Wherein the predetermined range is within 20 mm.

In one embodiment, referring to fig. 7, the crawling condition of the first rail 100 or the second rail 400 can be indirectly analyzed through the two monitoring rules 300. When the two monitoring rulers 300 respectively detect that the first switch rail 200 and the second switch rail 500 have no crawling or the crawling amount is within the technical allowable requirement range, observing the change of the front rail gap and the rear rail gap of the first stock rail 100 or the second stock rail 400 and recording the relevant state; then, the alignment lines 321 of the two monitoring rulers 300 are realigned with the end of the first point rail 200 or the end of the second point rail 500, and the front and rear rail gaps of the point rail and the stock rail are monitored. If the first and second switch rails 200 and 500 do not creep or the amount of creep is within the allowable technical range, and the front and rear rail gaps of the first stock rail 100 or the second stock rail 400 change again, it can be determined that the first stock rail 100 or the second stock rail 400 creeps.

It should be noted that the front and rear rail gaps of the first stock rail 100 or the second stock rail 400 mean that the stock rails are spliced together, and a rail gap exists between the front and rear rails.

In one embodiment, referring to fig. 1 and 7, a system for monitoring the crawling of tongue rails, which employs any one of the above methods for monitoring the crawling of tongue rails, further includes a first stock rail 100, a first tongue rail 200 and a monitoring ruler 300, wherein the monitoring ruler 300 is provided with an alignment line 321, and a first limit line 322 and a second limit line 323 which are located on two opposite sides of the alignment line 321, the monitoring ruler 300 is attached to the first stock rail 100, and the alignment line 321 is aligned with an end of the first tongue rail 200.

The above-mentioned switch rail crawling monitoring system adopts the above-mentioned switch rail crawling monitoring method, and attaches the monitoring ruler 300 to the first stock rail 100, and aligns the alignment line 321 with the end of the first switch rail 200; after the alignment, the positions of the end portions of the first point rail 200 and the first limit line 322 and the second limit line 323 are periodically monitored. When the end of the first point rail 200 is offset from the alignment line 321 and is located between the alignment line 321 and the first limit line 322; alternatively, when the first switch rail 200 is located between the alignment line 321 and the second limit line 323, it may be determined that the first switch rail 200 has crawled, but the crawl amount does not exceed the preset distance and still stays within the allowable range; when the end of the first point rail 200 deviates from the alignment line 321 and exceeds the first limit line 322 or the second limit line 323, that is, is located on the side of the first limit line 322 facing away from the alignment line 321, or is located on the side of the second limit line 323 facing away from the alignment line 321, it is determined that the first point rail 200 has climbed and the amount of climbed exceeds the allowable range, and at this time, timely feedback is required and corresponding adjustment measures are taken for the first point rail 200 to avoid occurrence of traffic safety accidents. Because the monitoring ruler 300 is directly installed on the first stock rail 100, in the maintenance process, an operator does not need to carry a heavy measuring instrument, so that the maintenance process becomes easier and more convenient. Meanwhile, the monitoring ruler 300 is arranged on the first stock rail 100, and when the first switch rail 200 is closely attached to the first stock rail 100, the end of the first switch rail 200 is closer to the monitoring ruler 300, so that an operator can accurately read the reading of the end of the first switch rail 200 on the monitoring ruler 300, and the crawling condition of the first switch rail 200 can be accurately judged. In addition, the switch rail crawling monitoring method has the advantages of less maintenance workload and low maintenance cost, and is beneficial to being widely popularized in turnout operation.

Further, referring to fig. 8 and 9, the monitoring ruler 300 includes a base 310, a locking member 330, and a ruler body 320 slidably mounted on the base 310, wherein the alignment line 321, the first limit line 322, and the second limit line 323 are all disposed on the ruler body 320, and the locking member 330 is used for locking the ruler body 320 on the base 310. In this way, the alignment of the alignment line 321 with the end of the point rail is greatly facilitated.

In one embodiment, referring to fig. 7, the creep tongue monitoring system further includes a second tongue rail 500 and a second stock rail 400 arranged side by side with the first stock rail 100, two monitoring rulers 300 are provided, the two monitoring rulers 300 are respectively provided on the first stock rail 100 and the second stock rail 400, and the first tongue rail 200 and the second tongue rail 500 are both located between the first stock rail 100 and the second stock rail 400.

The technical features of the embodiments described above may be arbitrarily combined, and for the sake of brevity, all possible combinations of the technical features in the embodiments described above are not described, but should be considered as being within the scope of the present specification as long as there is no contradiction between the combinations of the technical features.

The above-mentioned embodiments only express several embodiments of the present invention, and the description thereof is more specific and detailed, but not construed as limiting the scope of the invention. It should be noted that, for a person skilled in the art, several variations and modifications can be made without departing from the inventive concept, which falls within the scope of the present invention. Therefore, the protection scope of the present patent shall be subject to the appended claims.