NL8502204A - RADIO TUBE WITH ROTATING ANODE. - Google Patents

Description

* ft Λ 85313

Short designation: Radiogenic tube with rotating WCe.

The invention relates to a radiogenic tube with a rotating antenna and more particularly relates to the mounting of the disk which formed the anode on the shaft of the rotor which rotates the drive.

The invention preferably applies to a radiogenic tube 5 with magnetic suspension, in which one wishes to electrically isolate the rotor from the high voltage applied to the anode.

A known radiogenic tube is composed of a cathode-forming electron emitter which is placed opposite an anode-forming target and is connected to a high voltage source. This disc-shaped anode is placed on the shaft of a rotor of the motor for rotary driving. Taking into account the large applied powers and the small surface area of the target zone of the electrons on the anode target, the rotation of this anode actually allows to increase the performance by proceeding in such a way that the electron bombardment on the relatively cold material. A recent development of this type of radiogenic tube has been the development of magnetic suspension rotors. The rotor no longer rests on ball bearings during its operation. With the appearance of this type of suspension, it is very advantageous to electrically isolate the disc forming the anode of the rotor. This makes it possible to avoid high voltage charging of the magnetic bearings, as well as the various power supplies and the electronic control and regulation systems that ensure the magnetic suspension. A simple-looking solution consists of manufacturing the shaft of the rotor from a strong electrically insulating material. With such a construction, only the disk is brought to a positive high voltage and the electric current is dissipated from the anode by a suitable device known per se, while the rotor remains at a potential close to the potential of mass.

Manufacturing such an impeller with insulating shaft, however, faces serious difficulties (caused by the significant temperature differences that occur) which have hitherto not been completely satisfactorily solved.

In fact, during operation, the disk forming the anode and the shaft of the rotor can reach temperatures on the order of 1500 ° C. This considerably limits the choice of materials usable for the shaft, since this material is simultaneously an iso- 'j8 8 2 2 Ö 4' 'ί * -2- learning and a refractory material. Furthermore, the anode disc must also be made of a refractory material that has a high atomic number. Due to the limited choice of materials for both the anode disc and the shaft, it is practically impossible to adjust the linear expansion coefficients between the materials of the disc and the shaft. It is noted that during the normal operation of the radiogen tube, the expansion difference between the shaft and the disk is too great to ensure good mechanical processing at any temperature.

The invention allows solving this problem.

The general idea of the invention consists in the choice of the constituent materials of the shaft and of the anode disc (currently the best possible insulating and refractory material for the shaft is chosen, such as, for example, a ceramic or aluminum oxide). take into account the expansion coefficients, and the mounting in the assembly of an element, which has a certain expansion coefficient and the dimensions of which are determined to take into account the different linear expansion coefficients of the composite materials.

More particularly, the invention therefore relates to a radiogenic tube provided with a rotating anode which is connected to a rotor shaft by a fastening system, characterized in that at least some of the composite parts are manufactured from materials having different linear expansion coefficients, at least one element of this fastening system has such a useful length that the axial expansions of this fastening system substantially compensate for the axial expansions of those parts of the anode and of the shaft which are subject to the action of this fastening system.

Usually, the aforementioned mounting system operates with axial clamping and the compensation element can, according to the invention, have the most diverse configurations. In this fastening system it is possible, for example, to provide a sort of partition wall (or several).

However, according to a presently preferred embodiment 35, this element of predetermined useful length is the screw of a screw-nut assembly disposed between this anode and an inner shoulder of the shaft, with the location of the inner shoulder the usable length of the screw 8502204 -3-r '. * <relative to this anode.

determines.

In addition, it should be noted that the invention is not limited to a magnetic suspension radiogenic tube (although this is the preferred field of application) but can be applied to any other radiogenic tube where the anode is to be electrically isolated from its drive system.

The invention will be better understood and other advantages thereof will become more apparent from the description below of various embodiments of radiogenic tubes according to the principle of the invention given by way of example with reference to the accompanying drawing, in which: fig. 1 is a partly schematic view of a radiogenic tube with magnetic suspension according to the invention; fig. 2 is a partial cross-sectional view of such a radiogenic tube, showing an attachment system according to the invention between the anode disc and the insulating shaft; fig. 3 is a similar view to fig. 1 and shows a variant of the fastening system; fig. 4 is a similar view to fig. 2 and shows another variant 20 of the mounting system; fig. 5 is a similar view as fig. 4 and again shows another variant of the mounting system.

In the drawing, a radiogenic tube 11 is shown with a rotating anode 12 and with magnetic suspension. The anode 12 is in the form of a disk, it is bombarded on its side 14 by an electron beam emitted by a cathode (not shown). The anode is attached to the end of a shaft 15 of a rotor 16 with magnetic bearings. The anode 12, the shaft 15 and the rotor 16 are mounted within an envelope 18, for example of glass. An anode 12, known per se, is provided with the device 7 for discharging charges. A positive high voltage is applied to the anode by means of this device.

The rotor is rotatably driven by a stator 19 located on the outside of the housing 18. The magnetic suspension is ensured by two pairs of poles 20 and two pairs of poles 21 which are arranged on the outside of the casing 18 in the vicinity of the two axial ends of the stator, respectively. In Fig. 1, a pair of poles 20 and a pair of poles 21 are visible and shown in the plane of the figure; the two 3502204 c% -4 other pairs of poles have shifted 90 °, respectively, and are not shown for simplicity. The rotor is hollow and protective bearings 24, which are mounted on a fixed shaft connected to the housing 18, are mounted inside the rotor so that it can rest on it when it is not in balance under the influence of the pair of poles 20 and 21 is being held.

According to a aspect of the invention, the shaft 15 of the rotor is of a refractory and insulating material, such as, for example, aluminum oxide or ceramic, and this shaft therefore has a linear expansion coefficient which differs substantially from that of the disc containing the anode 12, of graphite.

As Figs. 2 and 3 show, the anode 12 is pierced through an axial bore 26 and the shaft 13 is provided with a bore 28 which opens at the free end of the shaft and includes a diameter difference giving a straight shoulder 27. A screw 29 - nut 29a assembly is mounted against the face 14 of the anode and the shoulder 27. This screw-nut assembly thereby forms an axial clamping fastening system as noted above. The axial bore 26 of the anode corresponds to the end diameter of the shaft 15 and this anode rests against a straight shoulder 30 of this shaft.

According to the invention, the nature of the material forming the screw 29 and the location of the shoulder 27 (which determines its usable length) are chosen such that the axial expansion of this fastening system substantially compensates for the axial expansion of those parts of the anode and shaft subject to the action of this mounting system.

In the exemplary embodiment shown, the screw 29 actually plays the role of the said compensation element of the fastening system itself. The determination of the usable length L of the screw (ie the distance between the shoulder 27 and the plane 14 of the disc) is done in the following manner: - Lj is the length to be considered for the axial expansion from the anode; in the example of Figs. 1 and 2, simply the thickness of the anode in the vicinity of the shaft.

35 - L2 is the length to be considered for the axial expansion of the end portion of the shaft 15; in the example of fig. 1 and 2 it concerns the distance between the shoulders 27 and 30.

8502204 -5- φ φ - aj, ag and are the respective linear expansion coefficients of the materials that make up anode 12, shaft 15 and screw 29.

If at any time during the operation of the radiogenic tube it is allowed that these three elements have undergone the same temperature rise Δt with respect to the ambient temperature, so that the expansions are equal between the parts they hold (the shaft and the screw-nut assembly ) and the retained part (anode), then holds: a ^ At + = a ^ LAt and there L = + Lg al ~ a2 10 one gets: L = - a3 "a2

In other words, by selecting L in this manner, the cold clamping pressure applied along the longitudinal axis to the disk will maintain within the entire operating temperature range and the disk will properly attach to the insulating shaft remain confirmed.

15 In it; example of fig. 1, in which a = 5.5. ** m / ° C (graphite) and a2 = 7.10 “6 m / ° C (aluminum oxide), for the screw 29 a material with an intermediate temperature coefficient ( TZM, a ^ = 6.10 µm / ° C). The ratio L / L ^ is then 1.5. The usable length of the screw 29 is therefore greater than the thickness of the washer 12 (typically 30 mm for a washer with a thickness of 20 mm.).

The example of Fig. 2 corresponds to a combination of materials in which the expansion coefficient of the screw is greater than that of the other two materials. This is especially the case when the shaft 15 is ceramic (ag = 3.10 m / ° C, a ^ and a ^ do not change from the previous example). The same calculation results in the expression: al - a2 L = Lx. ---- a2 "a3

With the figures given above, the ratio L / Lj = 0.83.

The usable length of the screw is therefore smaller than the thickness of 3P the anode.

In the two previous cases, the radial expansion difference is compensated by the clearances calculated between the dia 5 '3 2 k: V-4 -6-' 1 meter from the bore 28 and that from the end of the shaft 15.

The configurations of Figures 5 and 6 simultaneously ensure radial and longitudinal compensation. For this purpose, the axial opening of the anode 12a and the end portion of the shaft 15a are provided with the cooperating, frusto-conical bearing surfaces 35 and 36, respectively. The other construction elements are identical and bear the same reference numerals as Figs. 1 and 2. It is shown that the length to be considered for the axial expansion of the disc is this time the distance between the top of the cone 38 in which the frusto-conical bearing surfaces 35 and 36 are inscribed and the plane 14 of the disc forms the anode on which the nut 29a rests. Likewise, the length to be considered for the axial expansion of the shaft is the distance between the top of this same cone and the shoulder 27.

When the expansion coefficient of the screw is less than or greater than that of the anode and of the shaft, the configuration of Fig. 4 is obtained, in which the top of the cone 38 is on the outside of the anode and with L = L ^. a1 a2 a2 - a3

In the opposite case, the configuration of FIG.

5, in which the top of the cone 38 lies on the inner side of the anode and / 20 with: al ”a2 L - L, ---- 1 a3 ~ a2

In all the cases described above, the determination of the usable length of the clamping screw 29 is given by the relationship: β-Ι “8λ L - L, ---- 1 a3 - a2 Of course, the invention is not limited to the few embodiments of the clamping system just described.

It includes all technical equivalents of the means employed when it is within the scope of the following claims.

8502 2 04

Claims (6)

Radiogenic tube provided with a rotating anode (12) connected to an axis (15) of the rotor (16) by a mounting system (29, 29a), characterized in that at least some of the assembled parts are made of materials having different linear coefficients of expansion, at least one element (29) of the fastening system having a usable length determined such that the axial expansions of the fastening system substantially compensate for the axial expansions of those parts of the anode and shaft which subject to the operation of this restraint system. Radiogenic tube according to claim 1, characterized in that said element of predetermined useful length is the screw (29) of a screw-nut assembly disposed between the anode (12) and an inner shoulder (27) of the shaft, the location of the inner shoulder relative to the anode determining this useful length. Radiogenic tube according to claim 2, characterized in that said usable length substantially satisfies the relationship: a1 “a2 L = L. -, wherein L is the usable length; 1 a3 - a2 is a length to be considered for the axial expansion of the anode, and 20 ap a2 »and a ^ are the respective linear expansion coefficients of the materials forming the anode (12), the shaft (15) and form the screw (29). Radiogenic tube according to claim 3, characterized in that the rotating anode is pierced through a cylindrical axial bore which corresponds to the end diameter of the shaft and which rests against a straight shoulder (30) thereof, taking into account the length is the thickness of the anode (12) in the vicinity of the shaft (15). Radiogenic tube according to claim 3, characterized in that the anode is provided with an axial opening and that this axial opening and the end part of the shaft are provided with co-operating, frusto-conical bearing surfaces (35, 36), wherein the length to be considered is the distance between the top of the cone (38) in which the frusto-conical bearing surfaces are inscribed and the surface (14) of the anode against which the clamping means rest. 6. Radiogenic tube according to any one of the preceding claims, having the ksa mark, which is the ceramic shaft. Radiogenic tube according to one of Claims 1 to 6, characterized in that the axis is made of aluminum oxide.