KR101996876B1 - Potable rail neutral temperature detection apparatus - Google Patents

Abstract

The present invention can improve the reliability of the representative temperature inside the rail calculated from the surface temperature of the rail by more accurately measuring the surface temperature of the rail, The present invention relates to a portable rail internal temperature detecting device capable of detecting an internal temperature of a portable rail.
A rail temperature measuring unit coupled to the housing and having a temperature sensor coupled to one end thereof; a contact guide unit for moving the rail temperature measuring unit in the longitudinal direction; An algorithm for calculating an internal representative temperature of the rail based on the surface temperature of the rail measured by the temperature sensor unit; and a communication unit for transmitting internal representative temperature information of the rail to an external management server or a terminal, Wherein the rail temperature measuring unit includes a first rail temperature measuring unit for measuring a surface temperature of the first region of the rail and a second rail temperature measuring unit for measuring a surface temperature of the second region of the rail. A rail inner temperature detection device is provided.

Description

[0001] The present invention relates to a portable rail internal temperature detection apparatus,

The present invention relates to a portable rail internal temperature detecting device, more specifically, to more accurately measure the surface temperature of a rail, thereby improving the reliability of the representative temperature inside the rail calculated from the surface temperature of the rail, The present invention relates to a portable rail internal temperature detecting device capable of detecting a representative temperature of each rail by detecting a rail temperature.

Recently, the speed of the train is increasing, and the rail installed to move the high-speed train is composed of a long rail. Generally, the long rail has a length of over 200m and it is necessary to weld the existing railway railway for the high speed of the train and stability of the running.

The pole rail is free from noise and vibration as compared with the existing railway rail, which is suitable for high speed train operation, but there is a risk of derailment of train due to buckling due to thermal stress.

Therefore, there is a problem that a large accident may occur during the train operation. To prevent this, a system for detecting representative temperature reflecting the thermal characteristics of the rail is being developed.

However, the conventional rail temperature detecting device is installed in a certain place and has a fixed form measuring the outside temperature of the rail. Such fixed type rail temperature detecting devices are troublesome to install and disassemble. Therefore, there is a problem in that it is difficult to move the detecting device to measure the rail temperature in the other area after being installed on the rail.

In addition, since only the temperature of the surface of a fixed position of the rail is measured and used for the maintenance of the rail, there is a problem that the overall thermal property of the rail is reflected and the representativeity is low.

Korean Registered Patent No. 10-0782319 (Title of the Invention: Monitoring Apparatus for Rail Measurement for Safety Diagnosis of Railway Structures, Date of Notification: December 06, 2007)

A problem to be solved by the present invention is to improve the reliability of the representative temperature inside the rails calculated from the surface temperature of the rails by more accurately measuring the surface temperature of the rails, The present invention provides a portable rail internal temperature detecting device capable of detecting a representative temperature for each section.

A rail temperature measuring unit coupled to the housing and having a temperature sensor coupled to one end thereof; a temperature sensor for measuring the temperature of the rail in the longitudinal direction; An algorithm for calculating an internal representative temperature of the rail based on the surface temperature of the rail measured by the temperature sensor unit, and a pre-stored arithmetic processing unit for transmitting the internal representative temperature information of the rail to an external management server or a terminal Wherein the rail temperature measuring unit includes a first rail temperature measuring unit for measuring a surface temperature of the first region of the rail and a second rail temperature measuring unit for measuring a surface temperature of the second region of the rail And an internal temperature detection unit for detecting an internal temperature of the rail.

In the portable rail internal temperature detecting device according to the present invention, the contact inducing portion may include a spring portion disposed along at least a part of an outer circumferential surface of the rail temperature measuring portion, and a handle coupled to the other end of the rail temperature measuring portion, A pin hole is formed at the other end of the rail temperature measuring portion for coupling with the handle portion and a protrusion portion into which the handle portion is inserted or to be mounted may be formed in an area of the outer surface of the housing where the handle portion is located .

In the portable rail internal temperature detecting device according to the present invention, the grip portion includes a first fixing portion disposed in front of the pin hole with respect to a longitudinal direction of the rail temperature measuring portion, And a fixing pin disposed between the first fixing portion and the second fixing portion and passing through the pin hole to be coupled with the pin hole, .

In the portable rail internal temperature detecting device according to the present invention, when the grip portion is mounted outside the protrusion, the spring portion is compressed so that the rail temperature measuring portion is inserted into the housing, and a part of the grip portion is inserted into the protrusion The one end of the rail temperature measuring part protrudes to the outside of the housing while the compression of the spring part is released, so that the contact area between the temperature sensor part and the rail can be increased.

In the portable rail internal temperature detecting apparatus according to the present invention, the calculation processing unit may calculate the representative temperature inside the rail based on the surface temperature measured by the first rail temperature measuring unit and the second rail temperature measuring unit have.

The portable rail internal temperature detecting device according to the present invention has the following effects.

First, the surface temperature is measured in two regions of the rail and the representative temperature of the inside of the rail is calculated more accurately by using the experiment based on the surface temperature, so that it is possible to maintain a stable rail rail.

Secondly, since the temperature sensor is more closely contacted to the rail through the contact guide portion, the contact resistance is minimized, and reliability of the representative temperature inside the rail, which is calculated based on the surface temperature of the rail, is increased.

Third, it is possible to measure the surface temperature of the rail by being detached and attached to the rail requiring internal representative temperature detection, thereby being able to detect the representative temperature of each rail section.

Fourth, since information about the internal representative temperature can be transmitted using the communication unit capable of wireless communication, it is possible to perform remote confirmation of the inside temperature of the rail as well as on-site identification of the representative internal temperature of the rail.

1 is a schematic view of a portable rail internal temperature detecting device according to the present invention.
FIG. 2 is a perspective view showing a detailed configuration of a housing, a rail temperature measuring unit, and a contact guide unit in the portable rail internal temperature detecting device of FIG. 1;
3 is a cross-sectional view of the portable rail internal temperature detecting device of FIG. 1 taken along line AA '.
Fig. 4 is a view showing an example in which the portable rail internal temperature detecting device of Fig. 1 is mounted on a rail. Fig.
FIG. 5 is a diagram illustrating a configuration for calculating a representative temperature of a rail through the portable rail internal temperature detecting device of FIG. 1. Referring to FIG.
6 is a view showing the movement of the rail temperature measuring unit according to the position of the contact guide unit in the portable rail internal temperature detecting device of FIG.
FIG. 7 is a diagram showing an experiment conducted to obtain an algorithm for calculating the surface temperature of the rail to the internal representative temperature of the rail in the portable rail internal temperature detecting device of FIG. 1;

Hereinafter, preferred embodiments of the present invention in which the above-mentioned problems to be solved can be specifically realized will be described with reference to the accompanying drawings. In describing the embodiments, the same names and the same symbols are used for the same configurations, and additional description therefor will be omitted below.

A portable rail internal temperature detecting device according to the present invention will be described with reference to FIGS. 1 to 7. FIG.

1 to 7, a portable rail internal temperature detecting apparatus according to the present invention includes a housing 100, a rail temperature measuring unit 200, a temperature sensor unit 300, a contact induction unit 400, A communication unit 900, a signal amplification unit 600, and a power supply unit 800.

The housing 100 is formed in a shape corresponding to the rail R on which the portable rail internal temperature detecting device according to the present invention is mounted. The housing 100 has a protrusion and a measuring portion through hole 120 , The projecting portion and the measurement portion through hole 120 will be described in detail later.

The housing 100 is made of a material having heat resistance in case the rail R rises at a high temperature, and may be made of a resin material such as PLA or ABS.

In addition, the housing 100 may be made of a material having low thermal conductivity, because the temperature of the housing 100 itself increases due to the heat of the rail R, So as to prevent noise from occurring in the process of measuring the temperature of the rail (R).

The rail temperature measuring unit 200 is connected to the housing 100 through the measuring unit through hole 120 and has a temperature sensor unit 300 coupled to one end thereof. A first rail temperature measuring unit 210 and a second rail temperature measuring unit 220.

The first rail temperature measuring unit 210 measures the surface temperature of the first region of the rail R by coupling the first temperature sensor unit 310 at one end.

The second rail temperature measuring unit 220 measures the surface temperature of the second region of the rail R by coupling the second temperature sensor unit 320 to one end.

As shown in FIG. 7, the thermal expansion amounts of the sixteen points measured by the displacement amount analysis according to the temperature change of the rail (R) are calculated by using a simulation program such as ANSYS, The first region R1 of the rail R suitable for calculating the internal representative temperature change of the rail R is displayed on the rail R by confirming intensively deformation of the rail R, And the surface of the second region R2 are selected.

Of course, the first region and the second region may be selected based on the results of actual experiments as well as the simulation program described above.

The rail temperature measuring unit 200 is made of a material having heat resistance and low thermal conductivity like the housing 100 so that the rail temperature measuring unit 200 is raised by the heat of the rail R, The sensor unit 300 prevents the occurrence of noise that may occur during the process of measuring the surface temperature of the rail (R).

The detailed structure of the rail temperature measuring unit 200 will be described with reference to the first rail temperature measuring unit 210 as follows. The second rail temperature measuring unit 220 measures the temperature of the first rail R) temperature measuring unit, the description of the second rail temperature measuring unit 220 will be omitted.

2 to 3, the first rail temperature measurement unit 210 includes a measurement head unit 211 and a measurement penetration unit 212.

One end of the measurement head 211 is connected to the first temperature sensor 310 and the other end is connected to the measurement penetration part 212. One end of the measurement head 211 is connected to the housing 100, Is formed so as to have the same structure and shape as the surface of the substrate.

That is, one end of the measuring head 211 is configured to correspond to the rail R, so that the first temperature sensor unit 310 coupled to one end of the measuring head 211 is connected to the rail R ) Can be measured more precisely.

One end of the measurement penetration part 212 is connected to the other end of the measurement head part 211. A first pin hole 120a is formed at the other end of the measurement penetration part 212, (211) is formed to be larger than the diameter of the measurement penetration portion (212).

The measuring part through hole 120 through which the first rail temperature measuring part 210 is passed includes a first through hole 121 and a second through hole 122. The first through hole 121, The diameter of the second through hole 122 is larger than the diameter of the second through hole 122.

The diameter of the first through hole 121 is larger than the diameter of the measuring head 211 and the diameter of the second through hole 122 is smaller than the diameter of the measuring head 211 And is formed to be larger than the diameter of the measurement penetration portion 212.

That is, a connecting portion of the measurement head 211 and the measurement penetration portion 212 is formed stepwise, and the diameter of the measurement head portion 211 is formed to be larger than the diameter of the second through hole 122 The first rail temperature measuring unit 210 may be removed from the housing 100 when the first rail temperature measuring unit 210 moves from the measuring head 211 to the measuring penetration unit 212. [ .

The temperature sensor unit 300 includes a first temperature sensor unit 310 and a second temperature sensor unit 320 and the temperature sensor unit 300 is a contact type temperature sensor such as a thermocouple So that the temperature of the surface of the rail R can be measured with higher accuracy when the temperature sensor unit 300 is attached to the surface of the rail R by the rail temperature measuring unit 200 .

The contact induction unit 400 moves the rail temperature measurement unit 200 in the longitudinal direction and the contact induction unit 400 includes a first contact induction unit 410 and a second contact induction unit 420.

Here, the protrusion is formed in the outer side surface of the housing so that the pull-tab is inserted or received in a region where the pull-tab is located, and the protrusion includes a first protrusion 111, into which the first contact- And a second protrusion 112 into which the second contact inducing part 420 is inserted or fixed.

The first contact induction unit 410 moves the first rail temperature measurement unit 210 in the longitudinal direction and the second contact induction unit 420 moves the second rail temperature measurement unit 220 in the longitudinal direction And the detailed configuration of the contact guide part 400 will be described with reference to the first contact guide part 410 as follows.

Of course, since the first contact guide portion 410 and the second contact guide portion 420 have the same configuration and shape, detailed description of the second contact guide portion 420 will be omitted.

The first contact guide part 410 includes a first spring part 413 and a first handle part 411.

The first spring portion 413 is located inside the first through hole 121 and is disposed along the outer circumferential surface of the measurement penetration portion 212. The other end of the measurement head portion 211 and the first through- (121), and is compressed and decompressed as it moves to the first rail temperature measurement unit (210).

The first grip portion 411 is located outside the housing 100 and is engaged with the other end of the measurement penetration portion 212 to move the rail temperature measurement portion 200 in the longitudinal direction.

Specifically, the first handle 411 includes a first fixing portion 411a, a second fixing portion 411b, and a first fixing pin 411c.

The first fixing part 411a is disposed in front of the first pin hole 120a in the longitudinal direction of the first rail temperature measuring part 210, 120a, and the measurement penetration portion 212 is disposed through the first fixing portion 411a.

The second fixing portion 411b is disposed behind the first pinhole 120a with respect to the longitudinal direction of the second rail temperature measuring portion 220 and is coupled to the first fixing portion 411a , And the measurement penetration portion 212 is disposed through the second fixing portion 411b.

The first fixing pin 411c is disposed between the first fixing part 411a and the second fixing part 411b and penetrates through the first pin hole 120a to penetrate the measurement through part 212 .

That is, the measurement penetration portion 212 is arranged to penetrate the first fixing portion 411a and the second fixing portion 411b at the same time, and the first fixing portion 411a and the second fixing portion 411b And a first fixing pin 411c is coupled between the first fixing portion 411a and the second fixing portion 411b and coupled with the measurement penetration portion 212, The first fixing part 411a and the second fixing part 411b are coupled to the measurement penetration part 212 and the first fixing part 411a and the second fixing part 411b are connected to the measurement through part 212 And can be rotated at a desired angle.

The first fixing portion 411a and the second fixing portion 411b have a polygonal cross section, and the reason why the first fixing portion 411a and the second fixing portion 411b are formed will be described later.

The first fixing part 411a includes a body part 411ab and a head part 411aa.

One end of the body part 411ab is inserted into the first projection 111 formed on the housing 100 and the other end is connected to the head part 411aa.

The head part 411aa is connected to the body part 411ab and has a larger cross-sectional area than the body part 411ab.

The cross section of the body part 411ab and the head part 411aa is formed in a polygonal shape and the inner end surface of the protrusion in which the body part 411ab is inserted is formed smaller than the cross section of the body part 411ab And is formed in the same shape as the cross section of the body portion 411ab, and the outer cross section of the protrusion is formed to be larger than the cross section of the body portion 411ab.

The cross section of the head portion 411aa is formed to be larger than the cross section of the inner side of the projecting portion.

That is, the body part 411ab may be inserted into the protruding part or may be mounted at the outer end of the protruding part, and the head part 411aa is not inserted into the protruding part, The first rail temperature measuring unit 210 is prevented from being detached from the housing 100 when the measuring unit 210 moves from the measurement penetration unit 212 to the measurement head unit 211.

Referring to FIG. 6, movement of the rail temperature measuring unit 200 according to the position of the contact guide 400 of the portable rail internal temperature detecting device according to the present invention will be described.

6 (a), when the handle portion, more specifically, the body portion 411ab is inserted into the protrusion portion, the measurement head portion 211 is moved in accordance with the movement of the measurement head portion 211, The pressure applied to the spring portion by the first through hole 121 and the first through hole 121 is released.

The spring portion is released and the measurement head portion 211 and the first temperature sensor portion 310 are protruded to the outside of the housing 100 so that the temperature sensor portion 300 and the rail R ) Is increased.

That is, since the temperature sensor unit 300 is closely contacted with the rail R through the contact induction unit 400 to minimize the contact resistance, the surface temperature of the rail R can be more accurately measured The reliability of the representative temperature inside the rail R calculated based on the measured surface temperature of the rail R is increased.

6 (b), when the handle portion, that is, the body portion 411ab is mounted on the outer side of the protruding portion, the force applied to the spring portion by the movement of the measurement head portion 211 A pressure is formed by the measurement head portion 211 and the first through-hole 121.

Thus, as the spring portion is compressed, the measurement head portion 211 and the first temperature sensor portion 310 are inserted into the housing 100.

When the first temperature sensor unit 310 does not measure the temperature of the rail R, the first temperature sensor unit 310 is disposed inside the housing 100, It is possible to prevent damage and breakage of the first temperature sensor unit 310 and to increase the service life of the first temperature sensor unit 310.

The first temperature sensor unit 310 and the second temperature sensor unit 320 measure the surface temperature of the first region and the second region of the rail R through the above-

The signal amplification unit 600 converts the surface temperature of the rail R measured by the first temperature sensor unit 310 and the second temperature sensor unit 320 from an analog signal to a digital signal, And transfers it to the arithmetic processing unit 700.

The arithmetic processing unit 700 stores an algorithm for calculating the internal representative temperature of the rail R on the basis of the surface temperature of the rail R. The arithmetic processing unit 700 includes the signal amplifying unit 600 The internal temperature of the rail R is calculated through the above-described algorithm.

The above algorithm was constructed through simulation and experiments through an analysis program such as ANSYS, etc., and a microprocessor was used to construct such an algorithm.

Since the microprocessor can be used for controlling various sensors and modules as well as using algorithms and has characteristics of using a small size and low power consumption, the portable rail internal temperature detecting device according to the present invention is portable Lt; / RTI >

The arithmetic processing unit 700 according to the present invention may use Arduino UNO or Razvepai.

In addition, the portable rail internal temperature detecting device according to the present invention may include a database unit (not shown). The database unit builds a database of information on the rail R based on seasonal and time-based weather data obtained through experiments, and the database processes the surface temperature of the rail (R) Is calculated when calculating the internal representative temperature of the rail (R), so that it is possible to calculate the internal representative temperature more accurately.

The communication unit 900 transmits the internal representative temperature information of the rail R to the external management server or the terminal M and the communication unit 900 is configured by wireless communication and uses the Bluetooth, The information on the rail R can also be transmitted to the terminal so that the remote manager can confirm the information on the rail R. [

The power supply unit 800 uses an internal power supply method and uses a rechargeable power supply to increase the mobility and reduce the maintenance cost of the internal representative temperature detecting apparatus for a portable rail according to the present invention.

A power switch S is formed in the housing 100 so that the housing 100 can be driven only when the temperature of the rail R is measured to save power stored in the power supply unit 800.

A mounting portion 500 is formed in the housing 100 so that the portable rail internal temperature detecting device according to the present invention can be easily attached to and detached from the rail R. [

As a result, the internal representative temperature detector of the portable rail (R) according to the present invention is detachably attached to the rail (R) requiring internal representative temperature detection, thereby being able to detect the representative temperature of the rail (R) In addition, since it can be used for maintenance of the rail (R) regardless of time and place, convenience of use is increased.

As described above, the present invention is not limited to the above-described specific preferred embodiments, and various changes and modifications may be made by those skilled in the art without departing from the scope of the present invention as claimed in the claims. And such variations are within the scope of the present invention.

100: Housing
111: first protrusion
112: second protrusion
120: Measurement part through hole
121: first through hole
122: second through hole
200: Rail temperature measuring unit
210: first rail temperature measuring unit
211: Measurement head section
212:
210a: first pin hole
220: second rail temperature measuring unit
220b: second pin hole
300: Temperature sensor unit
310: first temperature sensor unit
320: second temperature sensor unit
400:
410: first contact induction portion
411: first handle portion
411a:
411aa: head portion
411ab: body part
411b:
411c: first fixing pin
413: first spring portion
420: second contact induction portion
423: second spring portion
500:
600:
700:
800: Power supply
900:
S: Power switch
R: Rail

Claims (5)

housing;
A rail temperature measuring unit coupled to the housing through the measurement portion through hole formed in the housing and having a temperature sensor attached to one end thereof;
A contact guide portion for moving the rail temperature measuring portion in the longitudinal direction;
An algorithm for calculating an internal representative temperature of the rail based on the surface temperature of the rail measured by the temperature sensor;
And a communication unit for transmitting internal representative temperature information of the rail to an external management server or a terminal,
Wherein the rail temperature measuring unit comprises:
A first rail temperature measuring unit for measuring a surface temperature of the first region of the rail;
And a second rail temperature measuring unit for measuring a surface temperature of the second region of the rail,
Wherein the first region and the second region correspond to a region where the most deformation is intensively concentrated on the basis of a thermal expansion amount calculated through a displacement amount analysis according to a temperature change among the regions of the rails. Detection device. The method according to claim 1,
The contact-
A spring portion disposed along at least a portion of an outer circumferential surface of the rail temperature measuring portion; And
And a grip part coupled to the other end of the rail temperature measurement part to move the rail temperature measurement part,
A pin hole for coupling with the handle portion is formed at the other end of the rail temperature measuring portion,
Wherein a protrusion is formed in an outer surface of the housing to locate the handle portion, wherein the handle is inserted or received. 3. The method of claim 2,
The handle portion
A first fixing part disposed in front of the pin hole with respect to a longitudinal direction of the rail temperature measuring part;
A second fixing part disposed at a rear side of the pin hole with respect to a longitudinal direction of the rail temperature measuring part and coupled with the first fixing part; And
And a fixing pin disposed between the first fixing portion and the second fixing portion and penetrating the pin hole and coupled with the pin hole. The method of claim 3,
When the handle portion is mounted on the outside of the protrusion, the spring portion is compressed so that the rail temperature measuring portion is inserted to the inside of the housing,
Wherein when a part of the handle is inserted into the protrusion, the spring portion is released from compression, and one end of the rail temperature measuring portion protrudes to the outside of the housing, thereby increasing a contact area between the temperature sensor and the rail. And a temperature sensor for detecting a temperature of the inside of the rail. The method according to claim 1,
Wherein the calculation processing unit calculates a representative temperature inside the rail based on a surface temperature measured by the first rail temperature measuring unit and the second rail temperature measuring unit.

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