KR20200000026U - Feed-Through - Google Patents

Abstract

The present invention is connected to the upper and lower connectors through the main body and the plural layers of insulators and pressure plates in a zigzag form, and coupled to maintain the gimbles, so that the conductors composed of ribbon tapes are connected to each other. It can withstand the pressure of LNG and gas through the structure of the feed-through which electrically forms the conductors which supply or receive the signal, and also resist the thermal shock of cryogenic liquid even when LNG liquid is touched, and also improve airtightness. The present invention relates to a feedthrough whose structure is improved to maintain electrical insulation with an external metal part.

Description

Feed-Through}

The present invention relates to a feed-through, in particular, the conductor consisting of a ribbon tape is zigzag form through the main body and the plurality of layers of insulators and pressure plates are coupled to connect to the upper and lower connectors, and coupled to maintain the gimming, The structure of the feed-through, which electrically forms the conductors which receive voltage or signals to the measuring instruments and sensors in the circuit, withstands LNG and gas pressures, and withstands the thermal shock of cryogenic liquids even when LNG liquids come into contact. At the same time, the present invention relates to a feedthrough whose structure is improved to maintain airtightness to maintain electrical insulation with an external metal part.

In general, feed-through is a vacuum part (hereinafter referred to as a 'vacuum inside') of a vacuum chamber, which is widely used in a large scientific device such as an accelerator, a nuclear fusion device, an aerospace experiment device, or a semiconductor manufacturing field. It is disposed between non-vacuum parts (hereinafter referred to as 'vacuum outside'), and is used to connect various signals and the like between the vacuum inside and the vacuum outside.

As a related art related to the existing feed-through, as disclosed in Korean Patent Publication No. 10-1585689 "Feed-through" (Registration Date: 2016.01.08), connecting the power supply and one end of the induction heating coil, the body and the A first electrode having an extension part extending from the body part, and connecting the other end of the power supply part and the induction heating coil, and mounted to the first electrode to penetrate the body part, wherein the body part has a geometrical shape with the center of the first electrode; And a second electrode which is eccentric and electrically coaxial and disposed parallel to the extension.

In general, in order to obtain a signal in a closed container or pipe such as an LNG pump, power and output signal lines supplied to the sensor are drawn in and drawn out, and feed through is also applied to the inlet and out parts. -162 ° C) temperature.

When the LNG pump is stopped, the feedthrough is heated to 40 ℃ hot in summer sunlight when the LNG pump is stopped. If the pump is running while the pump is running, the LNG liquid will reach the feed-through for about one minute and be subjected to a thermal shock of about -150 ° C.

These thermal shocks occur every time the pump is stopped and started. The continuous thermal shock creates a gap in the contracted expansion of the conductor or the contracted expansion of the insulator that insulates the conductor, preventing gas tightness and leaking gas to the outside. It has been.

Conventional feedthroughs have been bonded and composed of copper, an insulator, Teflon, epoxy, etc., to maintain airtightness, but shrinkage and expansion accumulate upon thermal shock, resulting in microleakage passages, resulting in leaky airtightness and leakage.

Other prior art related to feedthroughs used for existing cryogenic applications include cryogenic power feedthrough assemblies, as disclosed in Korean Patent Application Publication No. 10-2016-145157 "Cryogenic Power Feedthrough Assembly" (published: December 19, 2016). A contact header assembly installed as part of: a) a feedthrough body defining a cavity extending between a first open end and a second open end; b) i) a first contact plate, ii) a plurality of first insulating bushings in close contact with the first contact plate, and iii) a first contact intimately inserted through the first insulating bushings and conductive A first contact plate assembly having a plurality of first contact pins that are non-conductive to the plate and feedthrough body; And c) i) a second contact plate, ii) a plurality of second insulating bushings that are in close contact with the second contact plate, and iii) a second insertion of the conductive and second conductive bushings in close contact with the second insulating bushings. A second contact plate assembly having a plurality of second contact pins that are non-conductive with respect to the contact plate; wherein the first contact plate assembly is formed between the first contact plate and the first open end of the feedthrough body. By close contact with the first open end; And the second contact plate assembly is in close contact with the second open end by a second electron beam welding formed between the second contact plate and the second open end of the feedthrough body.

By the way, the feedthrough used in the existing LNG pump, etc., when the liquid is in contact with the feedthrough for about one minute when the pump is started, the cryogenic thermal shock is transmitted to the feedthrough, and there is a concern that the airtightness is deteriorated as the insulator shrinks and expands.

Korea Patent Publication No. 10-1585689 "Feed-through" (Registration Date: 2016.01.08) Korean Laid-Open Patent Publication No. 10-2016-145157 "Cryogenic Power Feedthrough Assembly" (published date: 2016.12.19)

The present invention was devised to solve this problem in consideration of the above-mentioned problems, and its purpose is to provide LNG and a feedthrough to electrically form a conductor that supplies or receives a signal to a measuring instrument and sensor in a closed room such as an LNG gas pipe. The present invention provides a feedthrough that can withstand gas pressure and has an improved structure to withstand the thermal shock of cryogenic liquid even when LNG liquid is touched, while maintaining electrical insulation with external metal parts.

The present invention for achieving the above object and the body is interposed between the inner flange and the outer flange, the bolt fastening hole is formed on the upper surface and the first through hole through which the conductor is formed; A gasket interposed between the main body and the inner and outer flanges for airtightness; A plurality of layers of insulators which are in close contact with the lower side of the main body and each of which has a second through hole through which the conductor penetrates; A pressing plate coupled to the main body to press the plurality of insulators upwardly and having a third through hole through which the conductor penetrates; And a connector cup coupled to an upper side of the main body and a lower side of the pressing plate and to which each connector is connected to a conductor.

The first, second, and third through holes are formed to be positioned on different vertical lines so that the conductor penetrates in a zigzag shape.

The conductor uses ribbon tape, and the insulator adopts Teflon tape.

Further comprising an airtight material interposed between the pressing plate and the insulator, wherein the airtight material is silicone rubber.

The present invention is connected to the upper and lower connectors through the main body and the plural layers of insulators and pressure plates in a zigzag form, and coupled to maintain the gimbles, so that the conductors composed of ribbon tapes are connected to each other. It can withstand the pressure of LNG and gas through the structure of the feed-through which electrically forms the conductors which supply or receive the signal, and also resist the thermal shock of cryogenic liquid even when LNG liquid is touched, and also improve airtightness. It has the advantage of maintaining electrical insulation with the outer metal part.

1 is a coupling state of the feedthrough applied to the inner, outer flange according to the present invention.
Figure 2a and 2b is an exploded view of the insulator of the present invention and a state of coupling of the insulator.
Figure 3 is a front view of the conductor of the present invention.
4 is a bottom view of the insulator of the present invention.
Figure 5 is a bottom view of the invention presser plate.
Figure 6 is a coupling state of the subject innovation feedthrough.

1 through 6, the feedthrough according to the present invention is interposed between the inner flange 10 and the outer flange 20, and a bolt fastening hole 105 is formed on an upper surface thereof, and the conductor 200 penetrates. A main body 100 having a first through hole 110 formed therein; A gasket 150 interposed between the main body 100 and the inner and outer flanges 10 and 20 to maintain airtightness; A plurality of layers of insulators 300 which are in close contact with the lower side of the main body 100 and have second through holes 310 through which the conductors 200 pass; A pressing plate 400 coupled to the main body 100 to press the plurality of layers of the insulators 300 upward, and having a third through hole 410 through which the conductors 200 pass; And a connector cup 550 coupled to an upper side of the main body 100 and a lower side of the pressing plate 400, wherein each connector 500 is connected to the conductor 200.

Referring to FIG. 1, the inner flange 10 and the outer flange 20 have a main body 100 interposed therebetween, and a gasket 150 is provided above and below the main body 100 to prevent fluid leakage. .

The inner flange 10 and the outer flange 20 have a structure that is fastened by the flange bolt 12 and the flange nut 14 so that the main body 100 and the gasket 150 are interposed therein.

The body 100 is preferably composed of an epoxy resin strong in physical properties for LNG.

2A and 2B, the insulator 300 is a plate structure interposed between the main body 100 and the pressing plate 400, and insulates the conductor 200 from the main body 100. It is composed of Teflon material which has excellent insulation performance and excellent low temperature characteristics to withstand thermal shock against cryogenic temperatures.

The insulator 300 is composed of first, second, third and fourth insulators 300a, 300b, 300c, and 300d, and each of the second through holes 310 has a structure formed on different vertical lines.

In addition, as shown in FIG. 4, the insulator 300 is formed of circular plates having different sizes of outer diameters, and is in close contact with a stepped structure inside the lower side of the main body 100.

Each of the second through holes 310 formed in the first and third through holes 110 and 410 and the plurality of insulators 300 is connected to the upper and lower connectors 500 through the conductor 200 in a zigzag form. It is located on different vertical lines.

Referring to FIG. 5, the pressing plate 400 is formed of a circular plate, and has a structure in which a plurality of connection holes 405 through which the connection bolt 720 penetrates to be coupled to the main body 100 are formed at the edge portion.

Referring to FIG. 3, the conductor 200 may employ a ribbon tape wire made of a flexible material so as to maintain hermeticity against compressive force and maintain insulation.

The upper connector 500 and the lower connector 500 are respectively supported by the connector cups 550 coupled to the upper and lower sides of the main body 100, and the upper connector cup 550 is fixed bolt 710 therethrough. The lower connector cup 550 is fastened to the bolt fastening groove 105 of the main body 100, and the lower connector cup 550 is fastened to the bolt coupling groove 402 formed at the lower side of the pressing plate 400 by a fixing bolt 710. ) Is coupled to be fixed to the upper side and the lower side of the pressing plate 400.

The upper connector 500 and the lower connector 500 have a structure in which upper and lower ends of the conductor 200 are connected.

Referring to FIG. 6, the insulator 300 is accommodated in a stepped groove provided in the lower side of the main body 100 and stacked in a plurality of layers, and is pressed and supported by the lower press plate 400 to support the main body 100. It is coupled to be in close contact with the lower side.

It is further provided with an airtight member 600 for inserting and curing between the insulators 300 and between the insulators 300 and the main body 100 to be in contact with each other, and then press and harden them to maintain airtightness.

The airtight member 600 may employ silicone rubber.

When explaining the assembly procedure of the present invention having such a configuration, the main body 100 is disposed between the inner flange 10 and the outer flange 20, the main body 100 and the inner and outer flanges (10, 20) The gasket 150 is disposed to maintain airtightness therebetween, and the first through hole of the main body 100 in the process of disposing the insulators 300 of the plurality of layers in the stepped groove formed in the lower side of the main body 100. After passing through the conductors 110 through the second through holes 310 of the plurality of layers of the insulators 300 in a zigzag form, the third through holes 410 of the pressing plate 400 are passed through. The upper and lower ends of the conductor 200 are connected to the connector 500, respectively.

Subsequently, the pressing plate 400 is fixed to the main body 100 to couple the plurality of insulators 300 to be accommodated between the main body 100 and the pressing plate 400.

In addition, the connector cup 550 is coupled to the upper and lower sides of the main body 100 so as to support the upper and lower connectors 500 connected to both ends of the conductor 200 with the connector cup 550, respectively.

At this time, the connector cup 550 may be coupled to be fixed to the upper and lower sides of the main body 100 by fastening through the fixing bolt 710 to the bolt fastening groove of the main body 100, respectively.

On the other hand, the insulator 300 and the insulator 300 and the contact surface between the insulator 300 and the stepped groove of the main body 100 is provided so that the airtight material 600 made of silicon rubber is interposed to prevent the leakage of fluid. have.

Therefore, the present invention is coupled to the upper and lower connectors 500 through the conductor 200 consisting of a ribbon tape through the main body 100 and the plurality of layers of the insulator 300 and the pressing plate 400 in a zigzag form, Combined to maintain the gas flow, the structure of the feed-through, which electrically forms the conductor 200 receiving voltage or signals to the meters and sensors in the closed chamber, can withstand LNG and gas pressure, Even when the liquid touches, it is able to withstand the thermal shock of the cryogenic liquid and at the same time improves the airtightness, thereby maintaining the electrical insulation with the external metal part.

As described above, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the embodiments described above, but should be defined by the claims below and equivalents thereof.

That is, the present invention as described above is not limited to the above-described specific preferred embodiment, anyone having ordinary knowledge in the technical field to which the present invention belongs without departing from the gist of the present invention claimed in the claims. Various modifications may be made, of course, and such changes are within the scope of the claims.

10: inner flange 12: flange bolt
14: flange nut 20: outer flange
100: main body 105: bolting groove
110: first through hole 200: conductor
300: insulator 310: second through hole
300a, 300b, 300c, 300d: first, second, third and fourth insulators
400: pressing plate 402: bolt coupling groove
405: connecting hole 410: third through hole
500: connector 550: connector cup
600: airtight material 710: fixing bolt
720: Connecting bolt

Claims (4)

A main body (100) interposed between the inner flange (10) and the outer flange (20) and having a first through hole (110) through which a bolt fastening hole (105) is formed and a conductor (200) therethrough;
A gasket 150 interposed between the main body 100 and the inner and outer flanges 10 and 20 to maintain airtightness;
A plurality of layers of insulators 300, which are in close contact with the lower side of the main body 100 and have second through holes 310 through which the conductors 200 penetrate;
A pressing plate 400 coupled to the main body 100 to press the plurality of layers of the insulators 300 upward, and having a third through hole 410 through which the conductors 200 pass; And
And a connector cup (550) coupled to an upper side of the main body (100) and a lower side of the pressing plate (400) and each connector (500) connected to a conductor (200).
The method according to claim 1,
The first, second, third through-holes (110, 310, 410) is characterized in that the conductor 200 is formed so as to be positioned on different vertical lines so as to pass through in a zigzag form.
The method according to claim 1,
The conductor 200 employs a ribbon tape, and the insulator 300 employs Teflon tape.
The method according to claim 1,
Further provided with an airtight member 600 which is interposed between the pressing plate 400 and the insulator 300,
The hermetic material 600 is a feed-through, characterized in that the silicone rubber.

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