DE2422166C3 - X-ray tube with rotating anode - Google Patents

Description

From DE-PS 6 92 818 an X-ray tube is known, which in an evacuated tube piston cylindrical rotating anode, an axial slide and other mechanical parts for moving the Contains rotating anode in the direction of its axis of rotation, in which an electron beam emanating from a cathode impinges on the rotating anode in a focal point, the focal point corresponding to the movement of the Rotating anode moved on a helical line. The rotating anode is not damaged by a collision with it connected solid body (bolt, hammer or the like) set in motion.

From DE-PS 7 01 809 an X-ray tube of the type mentioned is known in which the axial movement the rotating anode along a guide rail under the influence of one or more current-carrying coils generated magnetic field takes place.

The invention specified in claim 1 is based on the object of providing an X-ray tube one that is optimally matched to the unit area loading (i.e. the thermal load capacity) of the rotating anode Axial movement of the rotating anode. Because in the invention, the axial displacement of the rotating anode to the Focal spot temperature is adapted, this shift is also during the alternating operation of the X-ray tube minimal. As a result, there is wear and tear on the axial slide and the other mechanical parts Movement of the rotating anode in the direction of its axis of rotation is minimal.

An exemplary embodiment of the invention is explained in more detail below with reference to the drawing

The X-ray tube shown in the drawing contains a cylindrical evacuated piston 1 with

ίο an end part! with a metal wall 2, which is through a Metal-glass connection 3 connected to the other part of the bulb and one for X-rays has a permeable window 4 through which the X-rays generated in the tube are emitted.

To perform a rotary movement in the piston is a plate-shaped anode 5 with a cylindrical Arranged outer surface A cathode plate 6 is opposite the cylindrical outer surface of the plate-shaped Arranged anode and is supplied with energy by a heating coil 7 to form an electron beam to produce, which impinges on the anode surface and forms a focal point 21, which is through the Window 4 is visible.

The anode 5 is fastened on an axle 8 which is connected to a rotor 9 driven by a stator 10 The stator is mounted on the outside of the piston 1 The rotor 9 is open to rotate an axial slide 11 mounted on transverse bearings 12.

The axial slide 11 is in turn on a

jo stationary axis 13 for axial movement over Thrust bearing 14 is mounted and is via a rack 15 which forms part of the inner surface of the slide and a toothed pulley 16 driven by a motor 20 moves. The stationary axis 13 is in

J5 melted the piston end so that the piston can be evacuated.

In operation, the anode 5 is driven by the rotor 9 and offers the impinging jet continuously creates a new surface, thereby heating the place where the electron beam hits and forms the focal point, does not rise as much. Because of the thermal delay, however, the rise Temperature of the track described by the focal point with each revolution and limited in this way the load on the anode.

In order to increase the load, the anode 5 is axially displaced by driving the axial slide U. As a result, the focal point 21 performs a spiral movement on the outer surface of the anode, as a result of which

so the track length increases and the rise in the anode temperature due to thermal delay decreased.

To further control the amount of anode temperature rise and thus the load capacity to increase, the end face 2 made of metal is provided with a narrow window 17 through which the Inner surface of the plate-shaped anode can be viewed with a light detector 18, which is a electrical signal 19 generated, the intensity of the

W) is proportional to the light emitted by the focal point 21. This signal is amplified in the amplifier 19 and used to control the motor 20. So if the When the anode temperature rises, the amount of light emitted from the focal point also increases, which means that the

► ^ the signal applied to the motor 20 increases and increases this triggers the anode movement in the axial direction in response to the increased load.

Sometimes anodes break and hit parts of them

the tube window and can step out of the screen. In the proposed setup is a Metal screen is provided around the anode and the x-ray window is right in the way an anode part that is ejected by centrifugal force.

1 sheet of drawings

Claims (6)

Patent claims: 1. X-ray tube, which in an evacuated tubular flask has a cylindrical rotating anode, a Axial slide and other mechanical parts for moving the rotating anode in the direction of their Contains axis of rotation, in which an electron beam emanating from a cathode hits the rotating anode in impinges on a focal point, the focal point corresponding to the movement of the rotating anode moved a helical line, characterized in that the displacement of the The rotating anode (5) can be controlled in the longitudinal direction of its axis of rotation as a function of the focal point temperature is. 2. X-ray tube according to claim 1, characterized in that the rotating anode (5) is plate-shaped and the cathode (6) faces the outer surface of the plate 3. X-ray tube according to claim 2, characterized in that the rotating anode (5) with a Rotor (9) is connected, which rotates around an axially displaceable axial slide (11) 4. X-ray tube according to claim 3, characterized in that the axial slide (11) axially in Is shifted depending on the focal point temperature. 5. X-ray tube according to claim, characterized in that that a light detector (18) from the focal point area in the plate-shaped anode responds emitted light and thereby by means of a motor (20) and other mechanical parts (15,16) moves the axial slide (11). 6. X-ray tube according to claim 4, characterized in that the axial slide (11) by a Toothed rack (15) and a toothed disk (16) is coupled to the axially driving motor (20), wherein the toothed disk (16) is firmly set up and the toothed rack (15) is on the axial slide (11).