FR2500958A1 - ROTATING ANODE FOR RADIOGENIC TUBES - Google Patents

Abstract

The invention relates to an X-ray rotating anode whose body has radial recesses which cross under the path of the focus spot and those which cut through the path of the focus spot. These recesses are used to compensate for stresses which are caused during the production of X-ray radiation by the heating of the anode which occurs at the same time. However, in the case of such unstressed anodes, it is still desirable to increase the load capacity. According to the invention, this is possible in that the holes (15) are broken towards the focus spot path (9, 10) and the plate (8) is a ring which is at least 6 mm thick, corresponds approximately to the width of the focus spot path and has a heat-insulating hub (16, 12) towards its rotation axis (11). An X-ray tube which is equipped with a rotating anode according to the invention is particularly suitable for use in medical X-ray diagnosis.

Description

 The present invention relates to a rotating anode for X-ray tubes, the body of which has radial recesses which are bores passing under the target or targets. Such rotating anodes are known, for example from the patent application published in the Federal Republic of Germany under No. 2,833,751.

 It is known that, in rotating anodes for X-ray tubes, there is an intense heating during the production of X-rays. This heating occurs very quickly compared to the possibility of heat dissipation. This gives localized heating and therefore expansion under the effect of heat, which gives the material deformations which can cause the anode discs to burst.

According to the patent application published in the Republic
Federal of Germany under No. 2 833 751 mentioned above, one must obtain a relaxation of the tensions by holes which pass below the target or targets. But it is necessary to start from a rotating anode, which has a disc made entirely of metal going from the outer periphery to the axis. It would take rectilinear and very long holes to go from the periphery to the axis. It is therefore very complicated to obtain a relaxation of tensions by sparing holes. Shorter holes, for example those for which the drill comes out of the material while being inclined, present the risk of breakage of the drill or of requiring as an auxiliary measure to provide an additional hole at the outlet of the radial bore serving to release the tensions so that the drill bit has an "outlet". An additional disadvantage, especially for extremely high rotational speeds, lies in the fact that these additional "outlet holes" represent other notches with the consequence of the appearance of coefficients of concentration of stresses which increase the risk of rupture. In addition, the direct metallic bond between the target and the axis gives good heat conduction, which is not desirable, towards the bearings by means of the axis.

 The invention relates to a rotating anode for X-ray tubes of the type mentioned above which, while avoiding the aforementioned drawbacks and difficulties, makes it possible to obtain an improvement in thermal properties.

 According to the invention, the holes are open in the direction of the target and the disc is a ring having a thickness of at least 6 mm, roughly corresponding to the width of the target, and having a thermally insulating hub towards its axis. of rotation.

 Thanks to the use of a ring, which has a thickness of at least 6 mm and corresponds approximately to the width of the target or targets and which has a thermally insulating hub, account is taken of observations which have shown that, in the process of distributing heat from the target within the anode material, the amounts of heat propagating laterally are negligible compared to the heat flux which propagates in the Z direction (perpendicular to the surface of the anode). As the calculations have shown, during the charge, only the target first and, during longer charges, only in particular the parts of the target which are below are heated by the calorific energy appearing during the production of X-rays. The parts which are outside the target (outer edge and center) heat only slowly by conduction of heat.

 Precisely because of the fairly long path followed by the heat in the direction leading to the center of rotation, so along the radius of the anode, the ano disk / axis transition does not reach the same temperature as the target as well later. Now, if we make the target disk thicker and if, in addition, we shorten the radial extent into a ring which has only the width imposed by the target or by the targets, it then occurs lower thermomechanical tensions due to more regular heating.

 According to the invention, use is therefore made of the great advantage of producing the anode in the form of a ring, in which there is a lot of material below the target. In an anode produced in this way, it is possible in a simple manner to provide holes which terminate on the cylindrical interior surfaces facing the axis. These must have essentially diameters of 2 mm, because that gives, compared to the thickness of the material at the edge of the disc, on the one hand of the coefficients of concentration of the small stresses, and on the other hand does not weaken still not too much disc thickness. An end drilling, as for discs made entirely of metal going to the axis?, in which the drilling should not go to the center in order to avoid additional notches, is not necessary in the annular arrangement. In addition, the metal disc can be split from the surface, so as to obtain a simple and inexpensive manufacture. In addition, the annular arrangement allows, due to the fact that the separation disc is released towards the large space in the center, an increase in the number of slots provided. Instead of the six slots which are suitable for plates with a diameter of 100 mm, one can easily provide twelve.

 The holes are drilled in the radial direction essentially parallel to the upper surface of the anode. As a result, the base material, for example molybdenum, supplemented with 5% tungsten (MoW5), is weakened as little as possible.

 In the case of anodes for extremely high rotational speeds (greater than 300 Hz), it may be recommended to hoop the annular segments created by these slots using a hoop applied to the periphery of the ring. Such a hoop can be manufactured, for example from tungsten wire from 0.2 to 0.3 mm in section, applied in the form of a winding with one layer or with several layers. These wires can then absorb a large part of the centrifugal forces applied to the ring. The use of tungsten wires is proposed, because, as is known, the breaking strength increases for tungsten when the diameter of the wire decreases.

The hooping can be carried out at the edge of the ring by brazing on the various segments of the anode ring. Suitable solders are, for example, vanadium (V) and zirconium (Zr) or an alloy of the two, in which V represents 30X. Also suitable as solders of platinum (Pt) or rhodium (Rh).

 The fixing of the ring on the axis is advantageously carried out, as known by the German patent 1 099 095, by means of a means slowing down the propagation of heat, for example by the intermediary of a hub. graphite (C), molybdenum (Mo) or titanium (Ti). According to an advantageous embodiment, a graphite connecting piece is used, in which a metal hub, for example niobium (Nb), is inserted, by means of which the actual connection is then made to the metallo axis. that, which can be for example molybdenum. A secure connection with the axis is obtained, in particular by the combination mentioned last, because the metal partners can be connected in a reliable manner by welding or by soldering.

 It has also been found to be advantageous to provide the bores, admittedly essentially parallel to the surface, but in such a way that they make an angle on the side with respect to the radius instead of extending in the radial direction. This has the advantage that when the slot inclined at a certain angle to the radius passes through the hearth, there is no sudden shift of the hearth for the duration of the crossing thereof. It has proven particularly advantageous to maintain between the direction of drilling and the radius an angle of 5 to 250, in particular 150, depending on the width of the hearth, because then we are sure that the total width of the slot will never cover the width of the hearth, which would result in an undesirable brief axial shift of the hearth from the depth of the slot including the hole.

Other characteristics and advantages of the invention will emerge from the exemplary embodiments which will follow, illustrated in the drawing in which
FIG. 1 is a general view of an X-ray tube with a rotating anode, the anode of which is in accordance with the invention,
FIG. 2 is an enlarged view, partially in section, of the anode used in FIG. 1,
FIG. 3 is a partial plan view of the anode shown in the preceding figures,
FIG. 4 is a partial view of the anode of FIG. 3, in which a hoop made of tungsten wires has been shown, and
FIG. 5 is a plan view of an anode, in which the holes make an angle relative to the radius.

 In FIG. 1, an X-ray tube 1 with a rotating anode carries, in its vacuum bottle 2 and on its opposite end faces, a device 3 forming a cathode and a device 4 forming an anode. The cathode consists of a sleeve 5, which is threaded through one of the front sides and which carries in a cover 6 an incandescent cathode, which is not shown. The device 4 forming anode has, in a manner known per se, a rotor 7, which carries the actual anode 8 rotating. It has targets 9 and 10, which rotate around an axis 11, the anode of which is secured by means of an intermediate piece 12 made of niobium for example. The targets 9 and 10 are in contact with an annular piece 13 of molybdenum alloyed with 5% tungsten. The piece 13 also has holes 14 of 1.5 mm in diameter which open towards the targets 9 and 10, as represented by slots 15 0.5 mm wide. Between the axis 11 and the ring 13 is interposed a piece 16 carrying graphite, which further covers the underside of the metal piece 13 opposite the targets 9 and 10. In the direction of the axis 11, the connection between the ring 13 and the axis It further comprises a part 12 made of niobium (Nb) for example.

 On the periphery of the annular part 13 is mounted a winding 17 of tungsten wire, the wire having a thickness of 0.3 mm. Winding 17 is made up of ten turns. It is fixed by solders 18 to the parts of the ring which are separated from each other by slots 15. The solders -are made of zirconium (Zr) or vanadium (v).

 For the production of X-rays, a sufficient voltage is applied in a manner known per se between the cathode and the anode of a tube according to FIG. 1. At the same time the cathode, which is contained in the cover 6 and which consists of two parts, one of which is associated with the target 9 and the other of which is associated with the target 10, by applying a heating voltage between the conductors 19 and 20 and 19 and 21. On the conductor 19 located between the terminals 20 and 21, the cathode voltage is also applied in addition. This gives the appearance on one of the targets 9 and 10 or on these two electron targets, which then produce X-rays which can be used in the usual way.

 Figure 5 illustrates an embodiment which has slots 15 'formed, like the holes 14', in a direction which makes an angle 24, amounting to 15, relative to the radius 23 shown in phantom.

This variant otherwise corresponds to that of FIGS. 1 to 4. The advantage which can be obtained by the variant of FIG. 5 is, as already mentioned above, that when the slot crosses point 9 'incidence of the electron beam (focus), at least parts of the targets 9 and 10 are always in action.

Claims (8)

1) Rotating anode for X-ray tubes, the body of which has radial recesses, which are bores passing under the target or targets, characterized in that the bores (14) are open towards the target (9) and the disc (8) is a ring having a thickness of at least 6 mm, corresponding approximately to the width of the target (9), and having a hub (12) thermally insulating towards its axis of rotation. 2) Rotating anode-according to claim 1, characterized in that the holes make in the radial direction an angle with the perpendicular to the axis. 3) Rotating anode according to claim 2, characterized in that the angle is between 50 and 250 and is Xgalznotanté at 150. 4) Rotating anode according to claim 1, characterized in that the hub has at least one part made of graphite (C), molybdenum (Mo) or titanium (Ti). 5) Rotating anode according to claim 1, characterized in that the periphery of the ring is surrounded by an element which clamps it. 6) Rotating anode according to claim 5, characterized in that one or more layers of tungsten son are wound as a clamping element on the outer periphery of the ring. 7) Rotating anode according to claim 6, characterized in that the tungsten wires are fixed on the various segments, that is to say between the open holes, by solder points. 8) Rotating anode according to claim 7, characterized in that the solder is made of vanadium, zirconium, platinum or rhodium.