KR101004705B1 - Device of sensing temperature - Google Patents

Abstract

PURPOSE: A temperature sensing device is provided to prevent damage to a cable by forming a tube or a coil cover for covering the cable. CONSTITUTION: A temperature sensing device comprises a temperature sensing unit(10), a damping unit(20), and a cable(30). The temperature sensing unit senses the temperature of an object. The damping unit is coupled to the temperature sensing unit and absorbs the vibration of the object. The cable is connected to the temperature sensing unit and transfers a signal to a measuring unit. The damping unit comprises first and second connector units(21,22), an elastic unit(24), and a stopper(25). The second connector unit is coupled to the first connector unit and covers the temperature sensing unit. The elastic unit is arranged between the first and second connector units. The stopper is coupled to the temperature sensing unit and supports the elastic unit.

Description

DETECTION OF SENSING TEMPERATURE

The present invention relates to a temperature sensing device, and more particularly, to absorb vibrations transmitted from a temperature measuring object such as a gas turbine or a steam turbine with high temperature or high vibration, and to leak a high temperature fluid penetrating from the temperature measuring object. The present invention relates to a temperature sensing device which prevents the product from improving durability and increasing accuracy and reliability.

A thermocouple, commonly called a thermocouple, measures the temperature difference between two contacts using the thermoelectric power generated between the two metals.

For example, when joining platinum-rhodium, chromel-alumel, copper-constantan, etc., when the temperature of both ends of the contact is different, a current flows between these two metals. The temperature difference can be measured.

Such a temperature sensing device is relatively simple in structure and can measure a wide range of temperatures from a very low temperature to a high temperature of about 3000 ° C., and is widely used in various industrial temperature measurements throughout the industrial field.

Among the temperature sensing device, there is a sheath thermocouple composed of a thermocouple element wire, a metal protective tube, and an insulating material, which are widely used because they have good mechanical durability and can be bent arbitrarily.

The above technical configuration is a background art for helping understanding of the present invention, and does not mean a conventional technology well known in the art.

Conventional temperature sensing device has a problem that is damaged by the vibration of the temperature measurement object is shortened life.

In addition, the conventional temperature sensing device has a problem that gas or oil leaks through the connection to the temperature measurement object.

Therefore, there is a need for improvement.

The present invention has been made to improve the above problems, absorbs vibrations transmitted through the temperature measurement object, prevents the leakage of high-temperature fluid flowing through the temperature measurement object, improve the durability of the product The object is to provide a temperature sensing device that increases accuracy and reliability.

The present invention to achieve the above object is a temperature sensing unit for sensing the temperature of the temperature measurement object; A buffer unit coupled to the temperature sensing unit to absorb vibration of the temperature measuring object; And a cable connected to the temperature sensing unit and transmitting a signal to the measuring unit.

The temperature sensing unit is a thermocouple element bonded to two different metals; A protective tube surrounding the thermocouple element; And a sleeve surrounding and protecting the connection portion between the thermocouple element wire and the cable.

The temperature sensing unit is characterized in that it further comprises a tip installed on the protective tube and caught on the temperature measuring object.

The surface of the protective tube located between the tip and the end of the temperature sensing unit is characterized in that the smooth processing.

The protective tube is characterized in that it is processed smoothly by ultrasonic processing.

The protective tube is characterized in that the dual structure including the inner tube surrounding the thermocouple element, and the outer tube surrounding the inner tube.

The buffer unit is coupled to the temperature measurement object, the first connector portion surrounding the temperature sensing unit; A second connector unit coupled to the first connector unit and surrounding the temperature sensing unit; An elastic part disposed between the first connector part and the second connector part; And a stopper coupled to the temperature sensing unit and supporting the elastic unit.

A first case in which one end of the first connector is opened to form a first insertion space into which the elastic portion and the stopper are inserted; A first step bent at the other end of the first case to hold the stopper; And a first assembly extending from the first step and screwed to the temperature measuring object.

A second case in which the second connector portion has a second insertion space in which one end thereof is opened; And a second assembly extending from the second case and screwed to one end of the first case.

The elastic portion is a coil spring supported by the stopper; And a support ring disposed between the second assembly and the coil spring to support the coil spring.

Located between the second coupling member and the support ring, in close contact with the temperature sensing unit is characterized in that it is provided with a first sealing portion to prevent the outflow of the fluid.

One end of the second case is characterized in that the third connector is screwed.

Located in the second insertion space, in close contact with the temperature sensing unit is characterized in that it is provided with a second sealing portion to prevent the outflow of the fluid.

The temperature sensing unit is connected to the sleeve, characterized in that it further comprises a tube surrounding the cable.

The temperature sensing unit may further include a coil cover connected to the sleeve and surrounding the cable in the form of a coil.

The temperature sensing device according to the present invention has an effect of inducing the temperature sensing unit to be inserted into the temperature measuring object to an appropriate depth by being provided with a tip.

In the temperature sensing device according to the present invention, since the protection tube of the temperature sensing unit is designed in a double structure, the strength of the temperature sensing device is increased.

The temperature sensing device according to the present invention is formed so that the sleeve is wrapped around the connection portion of the thermocouple element wire and the cable, and the tube or coil cover is formed to surround the cable, thereby reducing the breakage of the cable due to frequent bending.

The temperature sensing device according to the present invention has an effect of absorbing the vibration of the temperature measuring object by having the elastic part embedded therein.

The temperature sensing device according to the present invention includes the first sealing part or the second sealing part, thereby preventing the leakage of high temperature fluid penetrating from the temperature measuring object to the outside.

1 is an exploded perspective view schematically showing a temperature sensing device according to an embodiment of the present invention.
Figure 2 is a schematic cross-sectional view showing a temperature sensing device according to an embodiment of the present invention.
3 is a view schematically showing a state in which the protective tube is a dual structure in the temperature sensing device according to an embodiment of the present invention.
4 is a diagram schematically illustrating a state in which a cable is protected by a tube in a temperature sensing device according to an embodiment of the present invention.
5 is a view schematically showing a state in which a cable is protected by a coil cover in a temperature sensing device according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described an embodiment of a temperature sensing device according to the present invention. In this process, the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description. In addition, terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to a user's or operator's intention or custom. Therefore, definitions of these terms should be made based on the contents throughout the specification.

1 to 3, the temperature sensing device 1 according to an embodiment of the present invention includes a temperature sensing unit 10, a buffer unit 20, and a cable 30.

The temperature sensing unit 10 is bonded to two different metals, and senses the temperature of the temperature measuring object 40. In this case, the temperature sensing unit 10 is inserted into the temperature measuring object 40 such as a gas turbine or a steam turbine, and the mounting unit 41 is provided to measure the temperature. The mounting part 41 may be integrally formed on the temperature measuring object 40 or may be installed to be detachably attached to the temperature measuring object 40.

The buffer unit 20 is combined with the temperature sensing unit 10 and absorbs the vibration of the temperature measuring object 40 when the vibration is transmitted to the temperature sensing unit 10.

The cable 30 is connected to the temperature sensing unit 10 and transmits a signal sensed by the temperature sensing unit 10 to the measuring device 50. Therefore, the measuring device 50 measures the temperature of the temperature measuring object 40 through the current by the thermoelectric power generated from the temperature sensing unit 10.

The temperature sensing unit 10 according to an embodiment of the present invention is provided with a thermocouple element wire 11, a protective tube 12, and a sleeve 13.

The thermocouple element 11 is joined to two different metals formed in a long and thin shape so as to sense the temperature of the temperature measuring object 40.

The protective tube 12 surrounds the thermocouple element wire 11 and protects the thermocouple element wire 11 inserted into the temperature measuring object 40 which is a high temperature. The protective tube 12 is filled with an insulating material, and the end portion from which the thermocouple element wire 11 is drawn out is sealed with an epoxy resin or the like.

The sleeve 13 wraps and protects the connection portion of the thermocouple element wire 11 and the cable 30.

The temperature sensing unit 10 according to an embodiment of the present invention is further provided with a tip 14. The tip 14 is coupled to the protective tube 12, the hooked to the limiting jaw 42 formed in the mounting portion 41 of the temperature measuring object 40, the thermocouple element wire 11 is a suitable depth to the temperature measuring object 40 To be inserted.

The surface of the protective tube 12 located in the machining area a corresponding between the tip 14 and the end of the temperature sensing unit 10 is smoothly machined. That is, the surface of the protective tube 12 which is located in the processing area a by using an ultrasonic processing machine that mixes the grindstone particles and the processing liquid between the tool and the workpiece vibrated by the ultrasonic wave and polishes the surface by the collision of the particles. This is processed smoothly.

As such, when the surface of the protective tube 12 corresponding to the processing region a becomes smooth, the response speed to the temperature measurement is improved.

The protective tube 12 may be formed in a single structure (see FIGS. 1 and 2) or may be formed in a double structure (see FIG. 3).

The protective tube 12 having a dual structure is divided into an inner tube 121 and an exterior 122. The inner tube 121 is filled with an insulating material to surround the thermocouple element wire 11, and the outer tube 122 surrounds the inner tube 121. The protective tube 12 having a dual structure is increased in thickness to improve the overall rigidity of the temperature sensing unit 10.

In addition, the protective tube 12 having a dual structure is disposed so that the inner tube 121 and the outer tube 122 are spaced apart, thereby enabling self-absorbing vibration.

The buffer unit 20 according to an embodiment of the present invention is provided with a first connector portion 21, a second connector portion 22, an elastic portion 24, and a stopper 25.

The first connector portion 21 is coupled to the mounting portion 41 of the temperature measurement object 40 and surrounds the temperature sensing portion 10.

The second connector portion 22 is coupled to the first connector portion 21 and surrounds the temperature sensing unit 10.

The elastic part 24 is disposed between the first connector part 21 and the second connector part 22, and the stopper 25 supports the elastic part 24.

Therefore, the elastic part 24 provided in the buffer part 20 coupled to the temperature measuring object 40 absorbs the vibration transmitted from the temperature measuring object 40.

The shock absorbing part 20 coupled with the temperature measuring object 40 by the shock absorbing action of the elastic part 24 absorbs the vibration.

The first connector part 21 according to an embodiment of the present invention includes a first case 211, a first step 212, and a first assembly 213.

One end of the first case 211 is opened to form a first insertion space 214 for inserting the elastic portion 24 and the stopper 25.

The first step 212 is bent at the other end of the first case 211 to reduce the inner diameter of the first insertion space 214. The stopper 25 fixed to the protective tube 12 is caught by the first step 212, and the movement of the first case 211 is limited.

The first assembly 213 extends to protrude laterally from the first step 212 and is screwed with the fastening part 43 provided in the mounting part 41 of the temperature measuring object 40.

The second connector portion 22 according to the embodiment of the present invention is provided with a second case 221 and a second assembly 223.

One end of the second case 221 is opened to form a second insertion space 224. The second assembly 223 extends so as to protrude laterally from the other end of the second case 221 and is screwed with one end of the first case 211.

An elastic portion 24 according to an embodiment of the present invention is provided with a coil spring 241 and a support ring 242.

The coil spring 241 is positioned in the first insertion space 214 formed in the first case 211, and the other end thereof is supported by the stopper 25.

The support ring 242 is disposed between the second assembly 223 and one end of the coil spring 241. The support ring 242 supports one end of the coil spring 241 while being supported at the end of the second assembly 223.

A first sealing part 26 is provided between the second assembly 223 and the support ring 242 to prevent the outflow of the fluid. The first sealing part 26 is in close contact with the protective tube 12 of the temperature sensing unit 10. At this time, the support ring 242 supports the first sealing portion 26.

The third connector 23 is screwed to one end of the second case 221. The third connector 23 is formed to surround the temperature sensing unit 10 to stably couple the protective tube 12 to the buffer unit 20.

A second sealing part 27 is provided between the third connector part 23 and the second case 221 to prevent the outflow of the fluid. The second sealing part 27 is positioned in the second insertion space 214 and is in close contact with the temperature sensing part 10.

The first sealing portion 26 and the second sealing portion 27 are made of non-metal materials such as natural rubber, synthetic rubber, plastic, graphite, and the like, metal materials such as mild steel, copper, and lead, and combinations of these metal materials and non-metal materials. Can be used.

In one embodiment of the present invention, the first sealing portion 26 and the second sealing portion 27 includes fluorine rubber having chemical resistance and heat resistance.

In order to prevent the cable 30 from being bent or damaged by vibration or the like, a tube 15 or a coil cover 16 connected to the sleeve 13 is provided.

Referring to FIG. 4, the tube 15 includes a silicon material and is connected to the sleeve 13. This tube 15 wraps the cable 30.

Referring to FIG. 5, the coil cover 16 is connected to the sleeve 13 and surrounds the cable 30 in the form of a coil.

Referring to the operation of the temperature sensing device according to an embodiment of the present invention having the structure as described above are as follows.

First, when the assembly process of the temperature sensing device 1 according to an embodiment of the present invention is described schematically, the stopper 25 is welded to the outer circumferential surface of the protective tube 12 surrounding the thermocouple element wire 11 or various other coupling schemes. To be fixed, and the protective tube 12 penetrates through the first connector portion 21.

When the stopper 25 fixed to the protective tube 12 is caught by the first step 212 of the first connector part 21, the elastic part 24 is inside the first case 211 of the first connector part 21. It is positioned in the first insertion space 214 is formed in.

In the above state, the second coupling member 223 of the second connector portion 22 is screwed to the first case 211, and the third connector portion 23 is further coupled to the second connector portion 22. Let's do it.

At this time, the first sealing portion 26 is positioned between the elastic portion 24 and the second connector portion 22, and the second sealing portion (between the second connector portion 22 and the third connector portion 23). 27).

When the assembly of the temperature sensing device 1 is completed as described above, the end of the temperature sensing unit 10 is inserted into the temperature measuring object 40, and the first assembly 213 of the temperature sensing unit 10 is attached to the mounting unit 41. Screwed to the fastening portion 43 formed in the).

At this time, since the tip 14 fixed to the outer circumferential surface of the protective tube 12 is caught by the limiting jaw 42 of the mounting portion 41 provided on the temperature measuring object 40, the temperature sensing unit 10 has an appropriate depth. The end is inserted into the temperature measuring object 40.

In the above state, a current generated through the thermocouple element wires 11 embedded in the protective tube 12 arrives at the measuring device 50 through the cable 30 to measure the temperature of the temperature measuring object 40.

At this time, the processing area (a) of the protective tube 12 inserted into the temperature measuring object 40 smoothly processes the surface of the protective tube 12 through ultrasonic processing, thereby increasing the response speed to the temperature measurement.

On the other hand, since the temperature sensing device 1 is coupled to the temperature measuring object 40, the vibration generated in the temperature measuring object 40 is transmitted to the temperature sensing device 1.

An elastic portion 24 is incorporated in the shock absorbing portion 20 to absorb such vibration, thereby suppressing the vibration of the temperature sensing portion 10.

In addition, if the protective tube 12 is designed in a dual structure having an inner tube 121 and the outer tube 122, the strength of the protective tube 12 is increased to suppress the damage of the protective tube 12 due to vibration.

While the temperature sensing device 1 senses the temperature of the temperature measuring object 40, the high temperature fluid flows into the buffer part 20 through the outer circumferential surface of the protective tube 12.

However, the buffer unit 20 is provided with the first sealing unit 26 and the second sealing unit 27, so that even if a high temperature fluid flows into the buffer unit 20 to prevent the outflow to the outside.

The connecting portion of the cable 30 and the thermocouple element wire 11 is formed so as to surround the sleeve 13, to prevent a short circuit or breakage of the connecting portion.

At this time, the tube 15 made of silicon material or the coil cover 16 which is connected to the sleeve 13 and surrounds the cable 30 prevents damage due to frequent bending of the cable 30.

Although the present invention has been described with reference to the embodiments shown in the drawings, this is merely exemplary, and those skilled in the art to which the art belongs can make various modifications and other equivalent embodiments therefrom. I will understand.

Therefore, the true technical protection scope of the present invention will be defined by the claims below.

10: temperature sensing unit 11: thermocouple element wire
12: sheriff 13: the sleeve
14 Tip 15: Tube
16 coil cover 20 buffer part
21: first connector portion 22: second connector portion
23: third connector portion 24: elastic portion
25: stopper 26: first sealing part
27: second sealing portion 30: cable
40: temperature measurement object 50: measuring instrument

Claims (15)

A temperature sensing unit sensing a temperature of a temperature measuring object;
A buffer unit coupled to the temperature sensing unit to absorb vibration of the temperature measuring object; And
It is connected to the temperature sensing unit includes a cable for transmitting a signal to the measuring instrument,
The buffer part
A first connector unit coupled to the temperature measuring object and surrounding the temperature sensing unit;
A second connector unit coupled to the first connector unit and surrounding the temperature sensing unit;
An elastic part disposed between the first connector part and the second connector part; And
A stopper coupled to the temperature sensing unit and supporting the elastic unit,
The first connector portion
A first case having one end opened to form a first insertion space into which the elastic portion and the stopper are inserted;
A first step bent at the other end of the first case to hold the stopper; And
A first assembly extending from the first step and screwed to the temperature measuring object;
The second connector portion
A second case having a second insertion space formed at one end thereof; And
A second assembly extending from the second case and screwed to one end of the first case;
The elastic portion
A coil spring supported by the stopper; And
A support ring disposed between the second assembly and the coil spring to support the coil spring,
Located between the second coupling member and the support ring, the first sealing portion is provided in close contact with the temperature sensing unit to prevent the outflow of the fluid,
A third connector portion is screwed to one end of the second case,
Located in the second insertion space, the temperature sensing device, characterized in that provided with a second sealing portion in close contact with the temperature sensing unit to prevent the outflow of the fluid. The method of claim 1, wherein the temperature sensing unit
Thermocouple elements in which two different metals are joined;
A protective tube surrounding the thermocouple element; And
And a sleeve surrounding and protecting the thermocouple element wire and the connection portion of the cable. The method of claim 2,
The temperature sensing device, characterized in that it further comprises a tip installed on the protective tube and the temperature measuring object. The method of claim 3, wherein
And a surface of the protective tube positioned between the tip and the end of the temperature sensing unit is smoothly processed. The method of claim 4, wherein
The protective tube is a temperature sensing device, characterized in that which is processed smoothly by ultrasonic processing. The method according to any one of claims 2 to 5,
The protective tube is a temperature sensing device, characterized in that the dual structure including the inner tube surrounding the thermocouple element, and the outer tube surrounding the inner tube. delete delete delete delete delete delete delete The method of claim 2,
The tube is connected to the sleeve, the temperature sensing device characterized in that it further comprises a tube surrounding the cable. The method of claim 2,
And a coil cover connected to the sleeve and surrounding the cable in the form of a coil.

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