SU660475A1 - Plasma unit chamber - Google Patents

Abstract

PLASMA INSTALLATION CAMERA, containing corrugated and smooth sections with supporting elements, characterized in that, in order to fix the position of the geometric axis of the cross section of the chamber, its supporting elements are installed on both sides of the equatorial plane of the chamber and are made in the form of mutually perpendicular slider guides, some of which are fixed radially to the axis of the installation, others are along the tangent to the longitudinal axis of the chamber, with at least one pair of guides located on opposite sides of the equatorial plane bones, elastically supported vertically, 9 while others are free in this direction (L05 O) o4 ^ ^ SP

Description

The invention relates to electrophysical equipment, in particular to the design of vacuum chambers of plasma systems.

As is well known, for degassing, vacuum chambers of plasma systems — 5 woks are subjected to high temperature heating.

In the known constructions of toroidal vacuum chambers of tokamak installations, the usually discharged chamber 10, located inside the cooled external chamber, is heated [1 and 2J. The discharge chamber is supported on the outside by means of supporting insulators installed along the contour of the cross section 15. The thermal expansion of the discharge chamber is ensured by structural gaps between the supporting insulators and the wall of the outer chamber. Thus, under the action of at-. 2θ of mosospheric pressure and electromagnetic forces arising during the working impulse, the inner chamber can move relative to the stationary outer chamber within the specified gap.

Known heated chamber of the plasma tokamak [3J, containing corrugated and smooth sections with supporting elements. The latter are made in the form of insulators fixed 30 along the contour of the corrugated sections, · and brackets installed in the lower part of the smooth sections. The insulators rest on the external chamber,. · And the brackets on the power farm of the installation. One row of brackets is rigidly fixed on the truss, the other is movable so as not to impede the expansion of the chamber during heating. As a result of this fastening, all points of a smooth section during heating move in the plane of the camera’s cross section relative to the rigidly fixed bracket.

The disadvantage of the design of cameras with this type of mount becomes apparent during the transition to large-scale installations, the cross-sectional diameter of which can be 1.5-2 m or more. As the size of the cross section ^{J of the} chamber increases, the absolute value of the thermal expansion of its elements increases, as a result of which uncontrolled displacements of its contour grow both during heating and under the action of external forces. Along with this, the distortions of the diagnostic pipes increase, which must be compensated with the help of flexible elements. 60

The purpose of the invention is fixing the position of the geometric axis of the cross section of the camera.

The goal is achieved in that the supporting elements of the camera are installed on both sides of its equatorial plane and are made in the form of mutually perpendicular slide rails, some of which are fixed radially to the installation axis, and others along the tangent to the longitudinal axis of the camera, with at least one pair of guides located on different sides of the equatorial plane, elastically supported vertically, while others are free in this direction.

The drawing schematically shows the camera and its mount inside the plasma system.

The high-vacuum heated chamber 1, together with the blocks of the magnetic system 2, is placed inside a common vacuum box 3. The chamber contains smooth sections 4 interconnected by corrugated sections (they are not shown conventionally in the drawing). In sections 4 symmetrically to the equatorial plane 5, support elements 6 are installed, made in the form of mutually perpendicular slide guides 7.

The upper and lower guides 7 are supported on the elastic elements 8 (Belleville springs), mounted on the covers of the vacuum box. The neck of the nozzles, which are equipped with smooth sections, are connected to the walls of the box using flexible elements 9 and 10 of the bellows type, compensating for linear movement during heating.

The guides 7 rigidly fix the camera from the action of external forces arising from the vacuum pumping of one of the chambers and during the working impulse. When heated, the slide guides do not impede the expansion of sections with support elements in the plane of their location, however, the position of the center of the cross section of the chamber in the horizontal plane is rigidly fixed. The expansion of the chamber in the vertical direction is compensated by elastic supports. In this case, the center of the cross section of the chamber is also practically not displaced due to the symmetry of the system. The asymmetry of the loads, due to the weight of the section, is compensated by various initial podkagi of elastic supports. Flexible elements 9 and 10 compensate only linear expansion, without experiencing transverse shear deformations.

DECLARES Order 3891/1

Draw 414

Subscription

Branch of PPP Patent, Uzhhorod, st. Proletnaya, 4

Claims (1)

CAMERA OF PLASMA INSTALLATION, containing corrugated and smooth sections with support elements, characterized in that, in order to fix the position of the geometric axis of the cross section of the camera, its support elements are installed on both sides of the equatorial plane of the camera and are made in the form of mutually perpendicular slide guides, one of which are fixed radially to the axis of the installation, and others along the tangent to the longitudinal axis of the camera, with at least one pair of guides located on opposite sides of the equatorial plane awns elastically supported at the vertical and the other free in this direction. CX) about