RU8152U1 - ITER PLANET HEATER PIPELINE CONNECTION - Google Patents

Abstract

1. Connection of the ITER blanket coolant pipelines, containing two nozzles, a crimp coupling, made of shape memory alloy, characterized in that both nozzles are installed end-to-end on the end surfaces, one of the nozzles is rigidly fixed to the blanket manifold by means of a flange, the second nozzle is connected through a bellows with the coolant pipeline of the module, the crimp sleeve is put on the first pipe and hermetically, for example, by soldering or welding, by means of a flexible metal element is fixed to the end section of the second pipe, while on the surface of the first pipe in contact with the sleeve there is a coating that prevents the diffusion seizure of surfaces, and there is also a transverse annular groove, which is connected to the auxiliary vacuum system through a longitudinal hole in the wall of the first branch pipe. The connection according to claim 1, characterized in that on the end surface of the second pipe in the direction of the blanket manifold there is an annular protrusion equipped with collet lobes, and the inner diameter of the protrusion is equal to the diameter of the pipe, and the outer diameter corresponds to the diameter of the inner surface of the first pipe, on which from the flange side there is a protrusion interacting with the collet petals, while inside the bellows through both nozzles there is a guide tube, which is a continuation of the pipeline connected to the bellows, the outer diameter of the guide tube corresponds to the inner diameter of the second nozzle, while the end section of the guide tube and the collet petals in contact with it, made with tapered surfaces. 3. The connection according to claims 1 and 2, characterized

Description

The utility model relates to nuclear engineering, in particular to the connections of the collector coolant pipelines and the ITER blanket modules, and can also be used in hydraulic: - {- and pneumatic systems in an energy-saving machine building.

Blanket on: Dressed inside a vacuum chamber in which

the operating time, by changing the vacuum system of the reactor, an ultra-deep vacuum meter is maintained (pressure is not 10 Pa), therefore the Bce, w blanket, in particular the detachable connection :: coolant, has a very tight tightness requirement, for the case, when the number of connectors is 11sh,

The research institute is 1.5–10, the requirement for the level of sealability of the compounds is determined by the following pattern: when crimping the ITER blank with helium with a pressure of 4.0 MPz, pressure

helium through one connection into a vacuum chamber, in a box -1 axis under a pressure of 1 Pa, should not exceed 1CG .mPaUs, pr1 / temperature of the constructional compound should be 0 and

9PP P

 / l

It is known to connect the coolant pipeline of the ITER blanket recirculator with the module pipeline (ITER Blanket gley -tf, -

  - --- -.-- - I T i; L

- ONZG Run

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ting ll-15t.h November 1996, EFET, European Fusion Engineering; and Teohnology EWIV, Qarahing :, 11 to 15 November 1996, containing a pipe, hermetically sealed E

i oh

the collector wall, nvprsher, welding in the pipe outlet pipe from the collector wall, the collector pipe is connected to the second pipe by welding, which is equipped with an RYN-T supply pipe to the coolant outlet to the module, and the free end of the second pipe is closed by a plug and placed in the hole of the module, coaxial pipe at the pickup.

In order to make the joint connection of the first pipe known, a hole is made in the module, in which a pipe with a pipe for supplying or removing coolant to the module is placed, and from the side of the first wall, a multi-function mechanism is introduced into the pipe through the hole in the module, by which both pipes are welded , tightness control of the weld, after which the connection mechanism is removed from the pipe, and the end of the pipe is blocked by a stopper. In case of replacing the module, it is necessary to separate the part of the nozzle about the plug from the nozzle itself, remove it from the hole in the module, then introduce the metal peBKii mechanism through the hole in the module and disconnect the nozzle a. blanket collector from the nozzle of the module.

The disadvantages of this design are as follows. 1, The known connection design is one-piece.

2. Necessity1. The need to use slsnachnogo dzhanshnuyu-controlled equipment for the conduct. Cutting operations, weld: and control, which increases the cost of technology connection.

3. The openings in the per-side wall of the module moisturizes the design of the first wall, reduces its strength, which reduces the reliability of the reactor.

The closest in its technical essence and achievable result to the proposed is the connection of pipes

(USSR AS N1590814 Connection of pipes, ZhP Fi6L21 / 00, 1988)} containing a crimp made of an alloy with a shape memory effect, two pipes.

An oblique box covers the conchs of both pipes, and between the coupling and the pipes to be connected there is an intermediate element made in the form of separate sections of grains of material with hardness, which is responsible for the hardness of the pipe material and, moreover, the sections with deposited grains are isolated from one another by free marks: .

The disadvantages of the prototype are as follows:, 1. This connection is one-piece.

S. The known compound does not meet the requirements for the level of tightness required for connections E of installations with high vacuum, in particular, to the connections of the coolant of the ITER blanket modules, since it has one step

% .seals ..

The above drawbacks do not allow the use of a prototype as a connection of coolant pipelines in the ITER blanket collector. .

Technically, the rez-ltatrm daadu of a useful model is 1. The connection is detachable, and the same tai-ogogg.note dkotantskonnogo implements9NI | 1 installation and demon, any operations.

2. Providing a given level of tightness.

The specified technical result is achieved due to the fact that in the connection of the pipelines of the coolant of the ITER blanket containing two nozzles, a crimp sleeve made of an alloy with a shape memory effect, both nozzles are installed end-to-end on the end surfaces, one of the nozzles is rigidly fixed to the collector form: of the flange, the second nozzle is connected through the bellows to the coolant pipe of the module, the coiled m-fitting is put on the first nozzle and is sealed, for example, by soldering or welding by means of a flexible metal the element is fixed on the end section of the second nozzle, while on the surface of the first nozzle in contact with the coupling there is a coating that prevents diffusion from setting surfaces, and there is also a transverse annular groove that is connected to the auxiliary via a longitudinal hole in the wall of the first nozzle vacuum system.

In addition, an annular protrusion provided with a petal grip collet is made on the end surface of the second nozzle towards the blanket collector; moreover, the inner diameter, 1 meter of the protrusion is equal to the dialet of the nozzle, and the outer corresponds to the dialetre of the inner surface of the first nozzle, on which there is a protrusion from the flange side, interacting with the collet petals, while inside the bellows through both nozzles, I pass the straight pipe, which is the continuation of the pipeline connected to the bellows, The diameter of the guide tube is It corresponds to the inner diameter of the second pipe, while the end portion of the guide tube and the collet contacts in contact with it are made of conical surfaces.

In addition, an additional transverse annular groove is made on the surface of the first nozzle, made between the existing transverse groove and the flange of the nozzle, through an additional longitudinal hole in the wall of the nozzle, the transverse groove is connected to the sample gas supply system (helium) while monitoring the tightness of the second stage of sealing

connections.

The set of well-known and set aside signs allows you to create a design g) detachable connection of the coolant pipelines, providing control of the tightness of the connection, as well as the possibility of its remote maintenance.

The essence of the utility model is illustrated in Figure 1, w, where in FIG. 1 shows a longitudinal section of a detachable connection. According to the figure, in the detachable connection of the heat transfer pipe, two coaxial pipes are sewn: а, contouring along the end faces, h surfaces, the first pipe 1 through the flange 2 is rigidly connected to the collector 3 of the ITER blanket, and the second pipe 4 is connected to the bellows 5, the second end of which connected about the pipeline 6 of the coolant module. On the

the first pipe 1 is equipped with a burner coupling, grips E. 1 from the junction to the flange 2. The kilogram / kg 7 is made of an alloy having a reversible (double-sided) e (| shape memory effect, for example, a Ti-Ni-Nb alloy), and is removed by a flexible metal element 3, with which a crimp the coupling is hermetically sealed, for example, by welding is fixed on the end section of the second pipe 4. On the surface of the first pipe 1 in contact with the coupling 7 there is a coating, for example, of titanium nitride or carbon nitride, which prevents diffusion gripping of g-surfaces. In addition, on the contact surface of the first nozzle 1, a transverse annular groove 9 smolders, which is connected through a longitudinal hole 10 in the wall of the first nozzle 1 to a tube 10 that extends beyond the blanket and is connected to an auxiliary vacuum system that provides pressure before

the second stage of sealing is not more than 10 Pa and, accordingly

leakage through the second stage of not more than 10 mPach for sealing with a diameter of up to 100 mm during the operation of the connection, or P: helium leak detector during the first monitoring of the tightness of the sealing stages of the connection (not shown in Fig.). Inside the bellows 5, a guide tube 11 passes through both nozzles 4, 1, which is a continuation of the module coolant pipe 5, while the outer D1 meter of the guide tube 11 corresponds to the inner diameter of the second nozzle. 4. On the end surface of the second nozzle 4. toward the collector of the bl-questionnaire a kodtsovy protrusion 12 is made, provided with a petal or collet 13. The inner diameter of the protrusion. 12 is equal to the diameter of the second pipe 4, and the external diash 5Er corresponds to the diameter

the inner surface of the first nozzle 1. On the flange 2, on the first nozzle 1, on its inner surface, Yotup 14 is made, taking into account the collet 13. These are supported by the guide tube 11, while the contact surface of the collet 13 and the guide tube are tapered.

In addition, on the crimped surface of the first pipe 1 has its own additional transverse annular groove 14, made between rhesheyoya transverse groove 9 and the flange 2

a pipe 1 connected through an additional longitudinal opening 15 in the shade of the pipe 1 about a pipe 16, which is removed outside the blanket and connected to the test gas supply (helium), while checking the tightness of the second stage of the joint seal (not shown in FIG.).

Docking of a detachable connection is carried out as follows.

Coaxially with the first pipe 1 of the blanket collector, pipe 6 about the bellows 5 and the second pipe 4 together with the burner, the first sleeve 7 are moved towards the first pipe 1. The first pipe 1 enters the space between the annular rings}. the protrusion 12 from the petal is the collet 13 and the crimp sleeve 7. The guide tube 11 and the protrusion 12 of the second nozzle 4, provided with the petal. the collet 13 enters the inner cavity of the first nozzle a. 1, and the casing sleeve 7 covers the first pipe 1 in outer diameter. The joint movement of the pipe 4 and the guide tube 11 is carried out until there is a contact of the end surfaces of the pipes, 1, the petals of the collets 13

they enter into action with a protrusion 14 on the first pipe 1, fix the position of the pipes, while continuing to move the guide tube 11 relative to the pipe 4 until the conical surface of the guide tube 11 and the inner conical 11 surfaces of the petals of the collets 13 are closed. As a result of which the collet is locked, the iPhone 5 remains in a tense state. Using a heated basin, for example, nitrogen, delivered directly through the channel in the module (not shown in FIG.) Directly to the hot}, 7, it is heated to the return temperature of 60–70 C, the coupling 7 seeks to restore the shape} / vyap temperature return transition, compresses the first pipe 1, and forms on the surface of the pipe 1 two stages of sealing. Then, the tightness of the joint is monitored. The tightness control is based on a separate tightness control of the first and second sealing stages. To control the tightness of the first stage, helium is fed into the entire pipe connection, and to control the second stage, helium is supplied via the tube 15 to the annular groove 15. The pressures and test temperatures were indicated above. For seals with a joint diameter of up to 100 mm, the leakage through the sealing stage (first or ETOPVTO) must not exceed 10} / 11a s. In this case, as the calculations show, when connecting the annular channel 9 to the auxiliary vacuum system and providing a pressure in front of the second stage of no more than 10 Pa, leakage through the entire connection

should not exceed 10 m. The connection is undocked as follows}. To the crimp sleeve 7 through the aforementioned: 1§ channels in the module is supplied with a refrigerant gas (vapors generated during boiling of liquid nitrogen), which cools it to temperatures of direct transition -20 С - or Hime. Possessing a two-sided effect of scorching for} / 1y, the coupling 7 expands and releases the first nozzle 1. Then the module is moved away from the blanket collector, while the guide tube 11 is pulled out from under the collar 13 of the collets, which are: interacting with the protrusion 14 of the first nozzle 1, the bellows 5 is unclenched, after which the second pipe 4 together with the casing 7 is disconnected from the first pipe 1. Thus, the proposed model for connecting the pipelines of the coolant of the modules and the collector of the ITER bladeset allows you to create a split distance tionally served compound pipelines in difficult to access: -: ground level and having zadannm tightness.

Applicant I. Chief Engineer of the National Research Nuclear Institute A.A. Grigoriev

Claims (3)

1. The connection of the pipelines of the coolant of the ITER blanket, containing two nozzles, a crimp sleeve, made of an alloy with a shape memory effect, characterized in that both nozzles are installed end-to-end on the end surfaces, one of the nozzles is rigidly fixed to the blanket collector by means of a flange, the second nozzle is connected through a bellows with the coolant pipe of the module, the crimp sleeve is put on the first pipe and hermetically, for example, by soldering or welding, by means of a flexible metal element is fixed on the end section of the second pat bk, while on the surface of the first pipe in contact with the coupling, there is a coating that prevents diffusion setting of surfaces, and there is also a transverse annular groove, which is connected to the auxiliary vacuum system through a longitudinal hole in the wall of the first pipe.  2. The compound according to claim 1, characterized in that on the end surface of the second nozzle towards the blanket collector there is made an annular protrusion equipped with collet petals, the inner diameter of the protrusion being equal to the diameter of the nozzle, and the outer diameter corresponding to the diameter of the inner surface of the first nozzle, on which on the flange side there is a protrusion interacting with the collet petals, while inside the bellows a guide tube passes through both nozzles, which is a continuation of the pipeline connected to the bellows, an external ametr guide tube corresponds to the inner diameter of the second pipe, the end portion of the guide tube and contacting them pitch collets are formed with conical surfaces. 3. The connection according to claims 1 and 2, characterized in that on the surface of the first pipe there is an additional transverse annular groove made between the existing transverse groove and the pipe flange, through an additional longitudinal hole in the pipe wall, through an additional longitudinal hole in the pipe wall, a transverse groove connected to a test gas (helium) supply system for monitoring the tightness of the second stage of joint sealing.