KR101908921B1 - Temperature indicator device for power transformer - Google Patents

Abstract

In the present invention, the temperature change inside the transformer is measured in real time, and the alarm is performed when the limit temperature of the transformer is reached. Finally, the transformer is automatically shut off from the entire system, And more particularly, to a temperature sensing device for a railway transformer using a sensor to prevent the temperature of the railway transformer.
An apparatus for detecting the temperature of a transformer, comprising: a main body (100) for visually displaying a temperature inside a transformer using a graduation plate (115) having a temperature indication scale on the front; The bimetal coil 211 is gradually rotated to operate the temperature indicator 212 in accordance with the temperature change so that the temperature indicator 212 can be operated in real time A first sensor member (200) indicative of the temperature; A coupling tube body 300 penetrating the rear of the main body 100 to transmit heat inside the transformer; A flange tube 400 coupled to the coupling tube 300 to connect the coupling tube 300 to the transformer and to transmit heat inside the transformer; A second sensor member 501 inserted into an end portion of the coupling tube 300 to transmit the internal heat of the transformer, measuring a critical temperature at a starting point of explosion risk of the transformer, and sending out a primary alarm signal; And a third sensor member (502) inserted adjacent to the second sensor member (501) to transmit the internal heat of the transformer, and measuring a limit temperature at which the explosion of the transformer is imminent and sending out a second alarm signal.

Description

TECHNICAL FIELD [0001] The present invention relates to a temperature sensor for a railway transformer using a sensor,

In the present invention, the temperature change inside the transformer is measured in real time, and the alarm is performed when the limit temperature of the transformer is reached. Finally, the transformer is automatically shut off from the entire system, And more particularly, to a temperature sensing device for a railway transformer using a sensor to prevent the temperature of the railway transformer.

Generally, a transformer for railway power is one of the most used equipment among the electric equipment for railway industry. It is used to supply electric power to the railway through an economical transmission and distribution system that increases or decreases AC voltage in a transmission system or a power distribution system Widely used.

This transformer is one of the essential elements for the operation of the transformer. It measures the change of the internal temperature of the transformer accurately and installs a thermometer to operate and control the surrounding cooling device based on the sensed value. Immediate shut-off minimizes damage and damage to equipment and systems.

In connection with such a technique, a conventional vertical bobbin is mounted on one end of a coil bimetal which rotates in accordance with a change in temperature, and transmits a rotation force of the coil bimetal to a guide part, as disclosed in Korean Patent Application Publication No. 2003-0007262 And a guide unit integrally coupled to an upper end of the vertical bar and integrally rotated on a concentric circle and integrally formed with the horizontal guide unit and the guide unit bent vertically downward with respect to the horizontal guide unit, A scale indicator provided on a concentric circle on the concentric circle with a direct indicator, the scale indicator being formed in a vertical columnar shape, the indicator being installed on the inner side of the direct indicator and having a temperature display scale on its outer periphery, and a fixing part provided below to support the direct indicator and the scale indicator A base plate on which drain holes are formed and a transparent cover And, the vertical bar is configured to include a vertical rod for supporting the stator so as to rotate the free-naeseol.

However, various temperature sensing devices for transformers have been developed in the background of prior art documents, but they are exposed to technical problems to be improved.

In the conventional case, since the transformer has a structure in which the temperature measurement period is concentrated at the limit temperature, the temperature measurement period of the transformer is very limited because the alarm function is performed only at the limit of the transformer, and the transformer is continuously exposed to the limit temperature condition There is another problem that the lifetime of the transformer is remarkably reduced and the maintenance cost is increased.

(Document 1) Korean Patent Publication No. 2003-0007262 (published on Jan. 23, 2003).

The present invention solves the problems of the prior art by providing a signal to shut down the transformer when the directive reaches the maximum limit temperature of the transformer and to measure the interval between the threshold temperature and the limit temperature, The sensor is designed to reduce the maintenance cost by increasing the service life of the transformer because it does not continuously operate the transformer to the limit temperature condition because it has a wide range of temperature measurement, The object of the present invention is to provide a temperature sensing device for a railway transformer.

According to an aspect of the present invention,

As a temperature sensing device for a transformer,

A main body for visually displaying a temperature inside the transformer using a graduation plate having a temperature display graduation on the front surface;

A first sensor member for displaying a temperature in real time by operating the temperature indicator according to a temperature change while gradually rotating the bimetallic coil when heat is transferred to the inside of the transformer;

A coupling tube inserted through a rear side of the main body to transmit heat inside the transformer;

A flange tube coupled to the outside of the coupling tube to provide a coupling tube to the transformer and to transfer heat inside the transformer;

A second sensor member inserted into an end portion of the coupling tube to transmit the internal heat of the transformer and measuring a critical temperature at a starting point of the explosion of the transformer and sending out a primary alarm signal;

And a third sensor member inserted adjacent to the second sensor member for transmitting the internal heat of the transformer and measuring a limit temperature at which the explosion of the transformer is imminent and sending out a second alarm signal. A temperature sensing device for a transformer is provided.

According to the present invention, when the temperature guideline reaches the maximum limit temperature of the transformer and contacts the flow guide to establish a contact, a signal for shutting down the transformer is sent out. In particular, a critical point between the critical temperature Is measured by using the second sensor and the third sensor, and the alarm signal is sent before the blocking signal. Thus, since the temperature measurement range is wide, the transformer is not continuously operated up to the limit temperature condition, It is effective.

FIG. 1 is a perspective view of a temperature sensing apparatus for a railway transformer using a sensor according to a first embodiment of the present invention; FIG.
5 is an operational view of a temperature sensing device for a railway transformer using a sensor according to a first embodiment of the present invention.
6 is a block diagram of a temperature sensing device for a railway transformer using a sensor according to a second embodiment of the present invention.

The temperature sensing apparatus for a railway transformer using the sensor according to the present invention will be described in detail with reference to the accompanying drawings.

In the following description of the exemplary embodiments of the present invention, a detailed description of components that are widely known and used in the art to which the present invention belongs is omitted, and unnecessary explanations thereof are omitted. It is to communicate the point more clearly.

1 to 6 are views illustrating a temperature sensing apparatus for a railway transformer using a sensor according to each embodiment of the present invention.

The temperature sensing device 1 includes a main body 100 for visually displaying the temperature inside the transformer, a first sensor member 200 for displaying the temperature of the transformer in real time, A flange tube 400 for transferring the heat inside the transformer while the coupling tube 300 is installed in the transformer and a critical temperature at a starting point where the transformer is at risk of explosion is measured A second sensor member 501 for transmitting a first alarm signal and a third sensor member 502 for measuring a limit temperature at which the explosion of the transformer is imminent and sending out a second alarm signal.

Hereinafter, as a basic configuration of the present invention, the configuration of each part of the temperature sensing apparatus for a railway transformer using the sensor according to the first embodiment will be described in detail with reference to FIG. 1 to FIG. FIG. 1 is a side cross-sectional view of the temperature sensing apparatus according to the first embodiment, FIG. 2 is a structural view of each part of the coupling tube of the temperature sensing apparatus according to the first embodiment, and FIG. 3 is a cross- FIG. 4 is a block diagram of each part of the first sensor member and the second sensor member of the temperature sensing device according to the first embodiment. FIG.

First, the main body 100 includes:

For visually displaying the temperature inside the transformer using a graduation plate 115 having a temperature display graduation on the front surface thereof.

The main body 100 according to the basic embodiment of the present invention comprises: A case 120, a cover 121, and a pointer contactor 110. [

For example, the main body 100 may include: A case 120 having a space therein and having a glass plate 123 coupled to the front surface of the space and a graduation plate 115 having a graduation for temperature indication coupled to an inner space of the glass plate 123, .

The case 120 is fixedly coupled to the outer wall of the transformer so that the inside temperature of the transformer can be visually recognized from the outside, and the separate connector is electrically connected to detect the temperature change of the transformer at a long distance.

At this time, the case 120 is provided with a terminal 125 to be electrically connected to the pointer contact unit 110 downwardly. The glass plate 123 prevents external moisture from flowing into the internal space of the case 120 And the sealing plate 115 has a structure in which numerals for temperature display and various characters for information transmission are printed on the front surface of the scale plate 115. [

In addition, the main body 100 includes: And a lid 121 hinged to the front of the case 120 using a lid hinge 122 and being rotatably opened and closed about the lid hinge 122.

The lid 121 is for preventing a stone or other foreign matter from being damaged by hitting the glass plate 123 at a high speed when the transformer is a moving type such as a train.

The lid 121 may be further provided with a fixing member 124 for fixing the lid 121 in a closed state. The fixing member 124 is fixed in a state where the lid 121 is closed by a bolt fastening method, On the inner surface of the lid 121, a packing for sealing function is provided.

In addition, the main body 100 includes: Is provided in front of the scale plate 115 to set the limit temperature of the transformer and when the temperature guide 212 of the first sensor member 200 rotates to reach the limit temperature, And a guide contactor 110 which is electrically connected while the flow guide 113 is in contact with the temperature guide 212 to send a shutoff signal of the transformer.

The instruction contactor 110 is designed to allow the user to directly set the limit temperature inside the transformer to operate the flow guide 113 and transmit a shutoff signal at the limit temperature of the transformer. Is 100 DEG C or higher, but the limit temperature can be set to 100 DEG C or higher or lower according to the user's selection.

Here, the pointer contactor 110 includes: A first contact 112 fixedly coupled to one side of the front surface of the temperature guide 212 and rotating in the same direction as the temperature guide 212,

When the temperature guide 212 rotates in accordance with the increase of the limit temperature of the transformer, the first contacts 112 are brought into contact with each other at the same rotation and are electrically connected to each other, A second contact 114 for sending out the first contact 114,

And a flow guide 113 fixedly coupled to the front surface of the second contact 114 and rotating in the same direction as the second contact 114 but arbitrarily set to a limit temperature of the transformer.

On the other hand, the first contact 112 protrudes from the front surface of the temperature indicator 212 in the shape of 'a', and the opposite side of the protruded first contact 112 is connected to the electric wires to be electrically connected.

The second contact 114 is protruded from the rear surface of the flow guide 113 and positioned within the rotation radius of the first contact 112 so that the second contact 114 is electrically connected when the first contact 112 is in contact.

The flow guide 113 has a tip in the form of a thin rod-like plate, and the flow guide 113 is rotated about the shaft-engaged portion in a state where the flow guide 113 is positioned axially at a position adjacent to the front surface of the temperature indicator 212 It is a structure that can visually display the limit temperature of the transformer by operation.

Accordingly, when the limit contact temperature of the transformer is reached, the first contact 112 and the second contact 114 make an electrical connection to transmit a cutoff signal to the transformer, The entire system of the transformer can be automatically shut off at the limit temperature where the internal fire and the explosion by it occur.

In addition, the first sensor member 200 may include:

The bimetal coil 211 is gradually rotated to operate the temperature indicator 212 in accordance with the temperature change so that the temperature indicator 212 can be operated in real time To indicate the temperature.

The first sensor member 200 according to the basic embodiment of the present invention includes: A temperature guide 212, and a bimetal coil 211.

For example, the first sensor member 200 may include: And a temperature guider 212 which rotates in an axial direction at the front surface of the scale plate 115 and a bimetal coil 211 is connected to the center of the shaft to transmit a rotational force according to a temperature change inside the transformer.

The bimetal coil 211 is connected to a shaft provided in front of the bimetal coil 211 so that the bimetal coil 211 is rotated in place according to the temperature change inside the transformer. And the same rotation is performed in response to the operation of FIG.

In addition, the first sensor member 200 may include: A bimetal coil 211 which is positioned in an internal temperature measuring part of the transformer and rotates by a thermal expansion coefficient as the heat is transmitted and rotates the temperature guide 212 connected to the end part to display an increase in the internal temperature of the transformer in real time, .

The bimetal coil 211 is accommodated in the protective tube 210 and has two types of thin metal having different degrees of expansion and contraction according to a change in temperature. The bimetal coil 211 has a coil shape. And the temperature guide 212 is fixedly connected to the shaft portion provided.

Here, the first sensor member 200 may include: A protective pipe 210 for protecting the bimetal coil 211 and an axis fixing member 220 for fixing the temperature indicator 212 while freely rotating the tip shaft portion of the bimetal coil 211. [

The protection tube 210 is inserted into the first heat conduction tube 320 of the coupling tube 300. The protection tube 210 is made of a tube so as to cover and protect the bimetal coil 211, 210 are exposed while projecting a shaft portion connecting the temperature indicator 212 to the tip of the cap.

The shaft fixture 220 is fixedly inserted into the distal end of the fixing pipe 310 of the coupling tube 300 with a circular plate having a hole penetrating through only the shaft portion of the bimetal coil 211 at the center, And functions to fix the temperature guide 212 so that the temperature guide 212 does not move vertically and horizontally while the shaft portion freely rotates.

Accordingly, the first sensor member 200 is provided with a structure for performing the temperature measurement using the bimetal coil 211, thereby enabling accurate temperature measurement while displaying the internal temperature of the transformer in real time.

The coupling tube 300 includes:

And is connected to the inside of the rear of the main body 100 to transmit heat inside the transformer.

The coupling tube 300 according to the basic embodiment of the present invention includes: A fixing pipe 310, a first heat conduction pipe 320, and a coupling 330.

For example, the coupling tube 300 may include: And a fixing pipe 310 penetrating the rear of the main body 100 and connecting the temperature indicator 212 of the first sensor member 200 to the main body 100.

The fixing pipe 310 is made of a hollow tube having a screw thread formed on the outer side in order to penetrate the case back of the case 100. The packing is inserted into the joint portion between the fixing pipe 310 and the main body 100 It is sealed.

Further, the coupling tube 300 includes: And a first heat conduction pipe 320 coupled to the rear of the fixing pipe 310 and having a rear portion of the first sensor member 200 inserted therein to transmit the internal heat of the transformer.

The first heat conduction tube 320 is coupled to the inside of the rear side of the fixing tube 310. The first heat conduction tube 320 is open at one side and the opposite side is formed at a closed tube shape, And has a space in which a second sensor member 501 and a third sensor member 502 to be described later are accommodated together with the sensor member 200. [

At this time, the first heat conduction pipe 320 is made of a metal material with easy heat conduction and is welded to the rear inside of the fixing pipe 310.

Here, the first heat conduction pipe 320 includes: A sensor cap (not shown) for directly transferring the heat of the transformer in a state where the second sensor member 501 and the third sensor member 502 are accommodated and inserted into the inner end portion of the first heat conductive pipe 320 321).

The sensor cap 321 is formed in a cylindrical shape in which a plurality of receiving grooves 321b for separating and accommodating the second sensor member 501 and the third sensor member 502 are formed, The first sensor member 200 and the third sensor member 502 having a size corresponding to the inner surface of the tube 320 and corresponding to the first sensor member 200 and the third sensor member 502 respectively inserted into the receiving groove 321b, It inserts it at the end and protects it.

In this case, the sensor cap 321 is made of a material that can not easily transmit heat. Preferably, the sensor cap 321 is made of ceramic or the like, and the sensor cap 321 is used for the second sensor member 501, The second sensor member 501 and the third sensor member 502 are prevented from rising in temperature through the remaining internal heat by adopting a material that is not heat transferred to each other while separating and accommodating the member 502 Reduce temperature measurement errors.

Here, the sensor cap 321 includes: A plurality of heat transfer holes 321a communicating with the receiving grooves 321b on side walls and a plurality of heat transfer holes 321a inserted into the heat transfer holes 321a and having one surface in surface contact with the inner surface of the first heat conduction pipe 320, And a plurality of heat transfer plates 322 that are in surface contact with the second sensor member 501 and the third sensor member 502, respectively.

The heat transfer holes 321a penetrate through the side walls of the sensor cap 321 toward the receiving grooves 321b so that the receiving grooves 321b and the inner spaces of the first heat transfer tubes 320 are connected to each other.

The heat transfer plate 322 is inserted into the heat transfer holes 321a so as to be in surface contact with the first heat conduction pipe 320 and the second sensor member 501 and the third sensor member 502, The heat of the first heat conduction pipe 320 through which the heat is first transferred using the heat transfer plate 322 can be immediately transmitted to the second sensor member 501 and the third sensor member 502 without delay.

Therefore, according to the present invention, it is possible to transmit the internal heat of the transformer more effectively to the second sensor member 501 and the third sensor member 502 by further adding the configuration of the sensor cap 321, Due to the short thermal conduction time, it can respond to rapid temperature changes immediately.

In addition, the coupling tube 300 may include: And a coupling 330 which is coupled to the outside of the fixing pipe 310 and is movable back and forth, and a flange tube 400 is coupled to the coupling tube 300.

The coupling 330 penetrates the outer periphery of the fixing pipe 310 and moves back and forth so that the length of the first sensor member 200 inserted into the transformer can be arbitrarily adjusted by the action that the flange pipe 400 is fixedly coupled. The coupling 330 is formed in the shape of a tube and integrally formed with a thread and nut on the outer periphery thereof. The flange tube 400 is screwed and fixed to the thread of the outer periphery of the coupling 330 Structure.

Further, the flange body 400 includes:

And is coupled to the outside of the coupling tube 300 to allow the coupling tube 300 to be installed in the transformer and to transfer heat inside the transformer.

The flange tube 400 according to the basic embodiment of the present invention includes: A flange 410, and a second heat conduction pipe 420.

For example, the flange body 400 may include: And a flange 410 coupled to an outer periphery of the coupling 330 of the coupling tube 300 by a spiral coupling and having one surface thereof coupled to the transformer in a tightly fixed state.

The flange 410 is formed in the shape of a disk with a hole for screwing the coupling 330 formed at the center of the inside thereof with a thread and is fastened to the outer wall of the transformer around the circular plate of the flange 410 Hole.

Further, the flange body 400 includes: The first heat conduction pipe 320 is inserted into the inside of the transformer while being fixed to one surface of the flange 410 so that the first heat conduction pipe 320 is positioned inside the transformer, And a second heat conduction pipe 420 for transferring the heat.

The second heat conduction pipe 420 is opened at one side and the opposite side is formed in a closed tube shape and has a space in which the first heat conduction pipe 320 is accommodated. Is inserted into the flange 410 and is fixed by welding.

Therefore, according to the present invention, the first sensor member 200, the second sensor member 501, and the third sensor member 502 are fixed to the inside of the transformer while the structure of the flange tube 400 is added, To be installed on the outer wall of the transformer.

The second sensor member 501 includes:

Is inserted into the end portion of the coupling tube 300 to transmit the internal heat of the transformer, and measures the critical temperature of the start point where the explosion of the transformer is likely to occur.

The second sensor member 501 is inserted into one of the plurality of receiving grooves 321b provided in the sensor cap 321 and is inserted into the end portion of the first thermally conductive pipe 320 using the sensor cap 321, And the surface of the second sensor member 501 is directly contacted with the heat transfer plate 322 provided in the sensor cap 321 so that the internal heat of the transformer can be directly transmitted and the temperature inside the transformer When it is high enough to send, it senses it and sends alarm signal continuously in a certain temperature range.

At this time, the second sensor member 501 operates within the temperature range of 70 ° C. to 90 ± 5 ° C. of the transformer, and when the second sensor member 501 measures the internal temperature of the transformer, .

And, the third sensor member 502 includes:

The second sensor member 501 is inserted adjacent to the second sensor member 501 to transmit the internal heat of the transformer, and the second alarm signal is transmitted by measuring the limit temperature at which the explosion of the transformer is imminent.

The third sensor member 502 is accommodated adjacent to the second sensor member 501 in one of the plurality of receiving grooves 321b provided in the sensor cap 321, And the surface of the third sensor member 502 is directly in contact with the heat transfer plate 322 provided in the sensor cap 321 so that the internal heat of the transformer can be directly transmitted And when the temperature inside the transformer rises enough to send an alarm signal, it senses it and sends a continuous alarm signal in a certain temperature range.

At this time, the third sensor member 502 operates at an internal temperature of the transformer of 90 ° C. to 100 ± 5 ° C., and the internal temperature of the transformer is measured by the third sensor member 502, .

Meanwhile, the second sensor member 501 and the third sensor member 502 according to the basic embodiment of the present invention include: First and second electrodes 510, a snap spring terminal 530, and a bimetal switch 540.

For example, the second sensor member 501 and the third sensor member 502 include: And further includes first and second electrodes 510 shorted to each other.

The first and second electrodes 510 and 510 are separately connected to the outside of the second sensor member 501 and the third sensor member 502 to be electrically connected to each other.

In addition, the second sensor member 501 and the third sensor member 502 include: The first electrode 510 and the second electrode 520 are connected to the second electrode 520 by a seesaw operation using an elastic force and a terminal 531 provided on one side contacts the first electrode 510, And a snap spring terminal 530 for making electrical connection with each other.

The snap spring terminal 530 is constructed such that a center portion of the snap spring terminal 530 is fastened to the second electrode 520 in a state where a plate snap spring is fastened to a lower portion of the plate, The terminal 531 is fixedly connected to the adjacent position of the second electrode 520 and is electrically connected to the second electrode 520.

In addition, the second sensor member 501 and the third sensor member 502 include: When the temperature inside the transformer rises, the terminal 531 is pressed by the first electrode 510 by pressing one side of the snap spring terminal 530 by the bending action using the thermal expansion coefficient of the bimetal, (Not shown).

The bimetal switch 540 is made of a bimetal provided with two types of thin metals having different degrees of thermal expansion and heat shrinking. The one end of the bimetal switch 540 is fixed to the first electrode 510, And is coupled to one side of the snap spring terminal 530.

At this time, when heat is transmitted to the bimetal switch 540 and the bending operation is performed by the thermal expansion coefficient, the bimetal switch 540 presses one side of the snap spring terminal 530 to push the terminal 531 toward the first electrode 510 And the terminals 531 rising toward the first electrode 510 are mutually contacted with each other, the first electrode 510 and the second electrode 520 are energized with each other to transmit an electrical signal.

Therefore, according to the present invention, since the second sensor member 501 and the third sensor member 502 are provided with a structure for measuring heat using a bimetal, even when the temperature falls, the contact point of the alarm signal is slowly returned by the remaining heat, And the time for performing the cause of the increase in the temperature and the recognition of the user is ensured to prevent the explosion and the fire accident due to the breakage of the transformer.

FIG. 5 is a diagram illustrating an operation state of a temperature sensing apparatus for a railway transformer using the sensor according to the first embodiment of the present invention.

5, in the temperature sensing device 1 having the above-described structure, when the temperature inside the initial transformer rises, the bimetal coil 211 of the first sensor member 200 gradually rotates And the temperature indicator 212 is rotated to perform real-time temperature display.

At this time, when the temperature inside the transformer rises to 70 ° C. to 90 ± 5 ° C., the second sensor member 501 senses this and the first alarm signal is electrically transmitted, thereby performing the alarm function by the lamp or sound When the temperature inside the transformer rises to 90 ° C. to 100 ± 5 ° C., the third sensor member 502 senses the second sensor signal and electrically transmits the second alarm signal to perform an alarm function by lamp or sound do.

The first contact 112 of the temperature indicator 212 and the second contact 114 of the flow guide 113 are brought into contact with each other so that the electric connection Thereby causing the shutdown signal to be transmitted to the entire system of the transformer.

As another constitution of the present invention, the constitution of each part of the temperature sensing device for a railway transformer according to the second embodiment will be described in detail with reference to Fig. 6 is a side cross-sectional view of the temperature sensing device according to the second embodiment.

The outer circumferential surface of the first heat conduction pipe 320 and the outer circumferential surface of the second heat conduction pipe 420 are disposed between the first heat conduction pipe 320 and the second heat conduction pipe 420 of the temperature sensing device 1 having the above- (600) which are in surface contact with the inner circumferential surfaces of the tubes (600) to directly transmit heat.

The other pipe (600) has a size and thickness corresponding to the space between the first heat pipe (320) and the second heat pipe (420) in a state of being made of a copper tube of the same material, 600 are in surface contact with the first heat conduction pipe 320 and the second heat conduction pipe 420 to directly transmit the heat of the transformer.

At this time, a plurality of heat holes 610 are formed through the inside of the other tube 600 so that heat can be taken in and out, and the heat holes 610 allow the heat to be more efficiently conducted to the through holes.

As described above. While the present invention has been particularly shown and described with reference to certain preferred embodiments thereof, it is to be understood that the terminology used herein is for the purpose of describing the present invention only and is not intended to limit the scope of the claims. But is not intended to,

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be easy for anyone to know.

One; A temperature sensing device 100; main body
110; Instruction contact point 120; case
200; A first sensor member 210; Protectionist
220; An axial fixture 300; Coupling tube
310; A fixing tube 320; The first heat conduction pipe
330; Coupling 321; Sensor cap
400; Flange body 410; flange
420; A heat conduit 501; The second sensor member
502; The third sensor member

Claims (4)

As a temperature sensing device for a transformer,
A main body 100 for visually displaying a temperature inside the transformer using a graduation plate 115 having a temperature display graduation on the front surface;
The bimetal coil 211 is gradually rotated to operate the temperature indicator 212 in accordance with the temperature change so that the temperature indicator 212 can be operated in real time A first sensor member (200) indicative of the temperature;
A coupling tube body 300 penetrating the rear of the main body 100 to transmit heat inside the transformer;
A flange tube 400 coupled to the coupling tube 300 to connect the coupling tube 300 to the transformer and to transmit heat inside the transformer;
A second sensor member 501 inserted into an end portion of the coupling tube 300 to transmit the internal heat of the transformer, measuring a critical temperature at a starting point of explosion risk of the transformer, and sending out a primary alarm signal;
And a third sensor member (502) which is inserted adjacent to the second sensor member (501) to transmit the internal heat of the transformer, and measures a limit temperature at which the explosion of the transformer is imminent and sends out a second alarm signal,
The coupling tube (300)
A fixing pipe 310 penetrating the rear of the main body 100 and connecting the temperature indicator 212 of the first sensor member 200 to the main body 100;
And a first heat conduction pipe (320) coupled to the rear of the fixing pipe (310) and having a rear portion of the first sensor member (200) inserted therein to transmit the internal heat of the transformer,
The first heat conduction pipe 320 allows the second sensor member 501 and the third sensor member 502 to be fixedly inserted into the inner end portion of the first heat conduction pipe 320 while being accommodated therein, And a sensor cap 321 for directly transferring the heat of the transformer to the second sensor member 501 and the third sensor member 502 using a heat transfer plate 322 provided to be in surface contact with the flange body 400 ,
The main body 100 is provided in front of the graduation plate 115 to set the limit temperature of the transformer and when the temperature guide 212 of the first sensor member 200 rotates to reach the limit temperature, Further comprising a guide contactor (110) which is electrically connected while the flow guide (113) provided adjacent to the temperature guide (212) is in contact with the temperature guide (212)
The sensor cap 321 is made of a material which can not easily transmit heat and includes a plurality of receiving grooves 321b for allowing the second sensor member 501 and the third sensor member 502 to be separated from each other, A plurality of heat transfer holes 321a penetrating through the side walls and communicating with the receiving grooves 321b to allow the heat transfer plates 322 to be inserted are formed,
One surface of the heat transfer plate 322 inserted in the heat transfer hole 321a is in surface contact with the inner surface of the first heat conduction pipe 320 while the other surface is in contact with the second sensor member 501 and the third sensor member 502 Each being in surface contact,
When the internal temperature of the transformer rises to 70 ° C. to 90 ° C., the second sensor member 501 senses the first temperature and the first alarm signal is electrically transmitted to perform alarm function by lamp or sound,
When the internal temperature of the transformer rises to 90 ° C. to 100 ° C., the third sensor member 502 senses the second temperature sensor and electrically transmits the second alarm signal, thereby further performing an alarm function by lamp or sausage Temperature sensing device for railway transformer using sensor. delete delete delete

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