KR20100113702A - Temperature sensor assembly for lng cargo tank - Google Patents

Abstract

PURPOSE: A temperature sensor assembly for a LNG storage tank is provided to prevent the disconnection or short circuit of a strand by damping stress. CONSTITUTION: A temperature sensor assembly for a LNG storage tank comprises a temperature sensor part(214) and a lead wire part(215). The temperature sensor part comprises a temperature sensor assembly and a filler(202). The temperature sensor assembly measures the LNG temperature within the storage tank of a LNG carrier. A temperature sensor element strand is inserted within the temperature sensor element protective tube. The space within the protective tube is charged with the filler. The lead wire part transfers a signal measured by the temperature sensor part.

Description

Temperature Sensor Assembly for LNG Storage Tank {Temperature Sensor Assembly for LNG Cargo Tank}

The present invention relates to a temperature sensor assembly for sensing a LNG (Liquified Natural Gas, LNG) storage tank temperature, in particular, it consists of a temperature sensor for sensing the LNG temperature in the LNG storage tank and a lead wire portion protected by a sheath made of stainless steel. It relates to a temperature sensor assembly consisting of a separate assembly.

LNG liquefies gaseous natural gas at -162 ℃ and stores it in high-pressure storage vessels, that is, it is transported in tanks.

LNG is 1/600 of the gaseous methane gas volume, and when the LNG temperature in the storage tank rises to room temperature (20 ° C.), the volume in the tank expands to 200 atm, causing the tank to crack.

Therefore, LNG must be kept at an ultra low temperature of -162 ° C, and for this, it is very important to detect a temperature change in the tank.

In addition, it is important to detect the leakage of LNG in the tank to prevent accidents due to leakage of the flammable LNG. The temperature sensor should monitor the leakage of LNG by sensing the temperature change as well as the temperature inside the insulation.

Figure 4 schematically shows a temperature sensor assembly for a conventional LNG storage tank.

As shown in FIG. 4, the conventional temperature sensor assembly 412 includes a temperature sensor part 410 and a lead wire part 411 in one body, and the temperature sensor part 410 has a temperature sensor element 401 having a protective tube. The inside of the protective tube 403 is filled with the filler 402, the lead wire portion 411 is formed of the lead wire 406 and the connecting portion 405, the lead wire 406 is the maximum An outer jacket 409 and an insulator 408 surrounding the lead wire element 407 therein are formed.

The temperature sensor assembly 412 is installed along the grooves between the insulation of the lower portion of the membrane metal panel forming the primary barrier of the LNG storage tank.

Therefore, when a failure occurs during or after the installation of the temperature sensor assembly 412, a structural structure in which all the membrane metal panels in all the paths where the temperature sensor assembly 412 is installed must be removed and the temperature sensor assembly 412 replaced. There was a problem.

In addition, since the junction between the element wire of the temperature sensor element 401 and the lead wire element 407 is in a straight line shape, there is a problem in that cracks are generated at the junction part due to the shrinkage / expansion caused by temperature change, thereby causing disconnection.

In addition, by filling the inner space of the protective tube 403 with a filler 402 of the same particle size, the empty space is generated between the filler 402, the temperature sensor element 401 by vibration This flow affects the junction between the relatively fragile temperature sensor element 401 element wire and the lead wire element wire 407, causing a disconnection or short circuit.

In addition, the lead wire 406 of the lead wire part 411 uses a Teflon-based organic material, and the jacket 409 or the insulator of the lead wire 406 due to the welding fly ash generated in the welding process for joining the respective membrane metal panels. There was a problem in that the lead wires 407 were disconnected or shorted because the 408 was burned.

The present invention has been made to solve the above problems, to eliminate the structural problem of removing all the membrane metal panel in case of failure, to prevent the disconnection or short-circuit of the junction between the small wire, further lead wire burned to lead It is an object of the present invention to provide a temperature sensor assembly that prevents elementary wires from breaking or shorting.

In order to solve the above problems, the present invention is a temperature sensor assembly for measuring the LNG temperature in the storage tank of the LNG carrier, the temperature sensor element element is inserted into the temperature sensor element protection tube and the space in the protection tube is filled with a filler Temperature sensor; Comprising a lead wire portion for transmitting the signal measured by the temperature sensor unit, provides a temperature sensor assembly for LNG storage tank, characterized in that the connector is formed at each end of the temperature sensor unit and the lead wire portion is fastened or separated.

In addition, the present invention is the temperature sensor element element included in the temperature sensor unit is processed in the form of Ω; The empty space inside the temperature sensor element protection tube surrounding the temperature sensor element element wire is provided with a temperature sensor assembly for the LNG storage tank, characterized in that it is filled with a filler of a ceramic material having a different particle size.

In another aspect, the present invention provides a temperature sensor assembly for LNG storage tank, characterized in that the lead wire portion is protected with a sheath made of stainless steel and the inside thereof is filled with a ceramic filler.

The temperature sensor assembly manufactured by the present invention has a structure in which the temperature sensor part and the lead wire part are separated, and the temperature sensor part and the lead wire part can be connected and separated through the connector.

If the temperature sensor assembly needs to be replaced due to malfunction during installation or after installation of the product, the membrane metal panel of the temperature sensor unit can be removed and replaced. Therefore, all membrane metal panels in the path where the temperature sensor assembly is installed must be removed. Compared with the prior art, the temperature sensor assembly replacement cost is significantly reduced.

The temperature sensor element element shape is implemented in Ω form to attenuate the stress caused by shrinkage or expansion due to temperature change, thereby preventing the crack of the junction with the lead wire element.

In addition, it is possible to reduce the flow of the temperature sensor element by using a filler having a different particle size around the temperature sensor element to prevent the disconnection of the wire.

In addition, a stainless steel sheath is applied to the lead wire to fundamentally prevent cable damage caused by the welding fly-bye generated during welding of the membrane metal panel, thereby ensuring a semi-permanent life.

Hereinafter, the configuration and operation of the temperature sensor according to the present invention will be described with reference to the accompanying drawings.

Prior to the description, in various embodiments, components having the same configuration will be representatively described in one embodiment using the same reference numerals, and only other configurations will be described in other embodiments.

Figure 1 schematically shows the installation of the temperature sensor assembly for the LNG storage tank according to the present invention.

In general, the LNG storage tank is formed of a primary barrier and a secondary barrier when viewed from the inside, and this drawing shows a partial cutaway of the primary barrier of the LNG storage tank.

The primary barrier is installed over the front of the LNG storage tank, and the temperature sensor assembly is also installed over the front of the LNG storage tank to detect a change in LNG temperature inside the storage tank.

In detail, the primary barrier 104 of the LNG storage tank is composed of a membrane metal panel 101 at the innermost part and a heat insulating material 102 at the outside thereof, and each of the heat insulating materials 102 is formed as a kind of block shape. There is a gap between the 102, and the gap is filled with the molding material 103.

At this time, the temperature sensor assembly 200 is installed along the groove between the heat insulating material 102 and the heat insulating material 102 outside the membrane metal panel 101 forming the primary barrier 104 of the LNG storage tank, the heat insulating material 102 ) And the insulation between the heat insulating material 102 is filled using the molding material 103, the surface is protected using a non-combustible tape.

2 is a view showing a temperature sensor assembly 200 of the present invention.

The temperature sensor assembly 200 is largely divided into a temperature sensor part 214 and a lead wire part 215.

The temperature sensor unit 214 is inserted into the temperature sensor element element 201 in the protective tube 203 and the space is filled with the filler 202, the protective tube 203 is connected to the temperature sensor bushes 204 and The protection tube 203 side is mounted inside the mounting bracket 220 to be protected, and is fixed using the fitting 205, and a first connector 206 is formed at one end of the temperature sensor bushing 204. .

The lead wire 210 of the lead wire portion 215 is protected in the lead wire sheath 213, and a second connector 207 is formed at one end thereof, and the element wire 211 and the filler 212 are formed inside the lead wire sheath 213. ) Is charged.

In the empty space inside the protection tube 203 of the temperature sensor unit 213, two ceramic particles having different sizes may be filled at an appropriate ratio.

Preferably, the filler 202 of ceramic material having 80 mesh and 120 mesh particle sizes is filled at a weight ratio of 6 to 4. Magnesium oxide powder may be used as the material of the filler, and the best filling ratio was obtained when the size of the filler was 80 mesh and 120 mesh, respectively.

In addition, one end of the protective tube 203 is sealed by welding to prevent the penetration of moisture.

A first connector 206 is attached to the opposite end of the temperature sensor bushes 204 to connect with the lead wire portion 215.

After the temperature sensor element element wire 201 and the pins of the first connector 206 are first bonded by brazing, the first connector 206 body and the temperature sensor bushes 204 are bonded by silver brazing.

The junction between the temperature sensor element element wire 201 and the pin of the first connector 206 is sealed using an epoxy of an organic material usable at ultra low temperature.

The second connector 207 of the lead wire part 215 for transmitting the signal value measured by the temperature sensor part 214 to the calculator is fastened to the first connector 206 of the temperature sensor part 214.

The first connector 206 of the temperature sensor unit 214 and the second connector 207 of the lead wire unit 215 may be fastened and separated from each other.

Therefore, if the temperature sensor assembly needs to be replaced due to malfunction during installation or after installation, only the membrane metal panel covering the temperature sensor part may be removed and replaced.

After the second connector 207 is bonded to the lead wire sheath 213 of the lead wire part 215 in the same manner as in the above bonding sequence, the lead wire 210 of the organic material is bonded to the inside of the adapter 208 by silver brazing. It is filled with epoxy of organic material. In addition, the charging unit uses a spring 209 to prevent breakage of the epoxy.

The first connector 206 and the second connector 207 used in the temperature sensor part 214 and the lead wire part 215 are fastened and loosened in a one-touch manner, and a key is formed for correct fastening. There may be.

3 is a detailed view of a temperature sensor element according to the present invention.

The temperature sensor element element 201 is connected to the resistance wire 302 wound inside the hollow protective tube 203, and is processed in Ω to attenuate the stress due to shrinkage or expansion due to temperature change and thus the sheath lead wire. The crack of the junction part with the element wire 211 is prevented.

At this time, the radius of curvature of the Ω form is preferably 1 mm.

This is because there is no big problem in the manufacturing process of the temperature sensor, and it does not affect the temperature sensor element due to the process of making the radius of curvature. In general, it is recommended to bend the curvature radius more than three times the thickness of the bar. Since the thickness of the sensor element element 303 is 0.3 mm, a radius of curvature of 1 mm, which is about three times as large, is preferable.

The temperature sensor element element wire 201 is processed in the form of Ω and bonded to the sheath lead wire element 211 and silver brazing, and then, a protective tube 203 for protecting the temperature sensor element element wire 201 and a sheath 213 made of stainless steel. ) Is joined by welding.

As such, those skilled in the art will appreciate that the present invention can be implemented in other specific forms without changing the technical spirit or essential features thereof.

Therefore, it should be understood that the above-described embodiments are exemplary in all respects, and are not intended to limit the present invention to the above embodiments, and the scope of the present invention is defined by the following claims rather than the detailed description. All changes or modifications shown and drawn from the meaning and scope of claims and equivalent concepts are to be construed as being included in the scope of the present invention.

1 is an installation of the temperature sensor assembly for the LNG storage tank according to the present invention.

2 is a perspective view of a temperature sensor assembly for an LNG storage tank according to the present invention;

Figure 3 is a detailed view of the temperature sensor element according to the present invention.

4 is a schematic view of a temperature sensor assembly for a conventional LNG storage tank.

Claims (3)

A temperature sensor assembly for measuring the LNG temperature in the storage tank of the LNG carrier, the temperature sensor element element is inserted into the temperature sensor element protection tube and the space in the protection tube is filled with a filler; It is made of a lead wire portion for transmitting a signal measured by the temperature sensor unit, A connector is formed at each end of the temperature sensor unit and the lead wire unit, the temperature sensor assembly for the LNG storage tank, characterized in that the fastening or separation. The method of claim 1, The temperature sensor element element included in the temperature sensor unit is processed in the form of Ω; The empty space inside the temperature sensor element protection tube surrounding the temperature sensor element element is filled with a filler of a ceramic material having a different particle size, the temperature sensor assembly for LNG storage tank. The method according to claim 1 or 2, The lead wire portion is protected by a stainless steel sheath and the inside of the temperature sensor assembly for LNG storage tanks, characterized in that the filling is made of a ceramic material can be used at high and ultra low temperatures.

Images