EP0335780A1 - Coil, manufacturing method for said coil and imagery device having such a coil - Google Patents

Abstract

The main subject of the invention is a coil, a method of manufacturing the said coil and an imaging device comprising such a coil. …<??>The invention relates to a coil (2) comprising a support plate (3) of substantially constant thickness and patterns (12, 13) deposited on this support. The patterns (12, 13) are deposited in such a way that the absorption, within a desired pass band, of electromagnetic energy is constant throughout the surface of the coil. …<??>In a first illustrative embodiment, the patterns are transparent to the electromagnetic energy of a desired frequency band. …<??>In a second illustrative embodiment, complementary patterns are used so as to obtain a constant absorption throughout the surface of the coil (2). …<??>The invention applies to the manufacture of two-dimensional electrical coils, such as for example flat coils or spherical dome-shaped coils. Such coils find their applications in compensating the effect of magnetic fields on charged particle beams. In particular they find their application in imaging devices using electron beams. …<IMAGE>…

Description

The main object of the invention is a coil, a method for producing said coil and an imaging device comprising such a coil.

The invention particularly relates to the production of coils capable of compensating for the parasitic effects of a magnetic field on charged particles by generating a magnetic field at a desired location.

Many devices use charged particle beams, such as electrons. It is known to use electron beams in display devices such as, for example: image intensifier tubes, television cameras, cathode ray display tubes or electron microscopes.

However, charged particles, such as electrons for example, are deflected by electric and / or magnetic fields. Such fields if they are not controlled induce image distortions. Any visualization device is subjected, at least, to the earth's magnetic field.

It is known to try to overcome, from the influence on the image obtained, the earth's magnetic field by carrying out shielding which will channel said magnetic fields. However, this solution is not satisfactory insofar as there is no effective magnetic shielding which would be transparent. Thus, in front of the lens of a television camera or the screen of a viewing tube with cathode rays, it is not possible to have an effective shielding which would not decrease too significantly the intensity of transmitted light.

The device according to the present invention compensates for the influence of the earth's magnetic field on the image formed by generating a magnetic field which is substantially of the same intensity as the disturbing magnetic field and of opposite polarization.

To generate magnetic compensation fields, a coil is used comprising a support forming a plate of substantially constant thickness. On this support is deposited a conductor constituting the coil. The coil according to the present invention is intended to be placed on the path of electromagnetic radiation, to display and / or display. To do this, it is imperative that the disturbance of the electromagnetic waves brought by the coil is in any case less than the annoyance presented by the distortions caused by the magnetic field. The support is chosen so as to absorb as little as possible of electromagnetic radiation belonging to the bandwidth of the radiation to be viewed and / or viewed. In all cases, this absorption must be uniform over the entire surface of the coil intercepting said radiation. If, for example, the electromagnetic radiation belongs to the visible spectrum, use will advantageously be made of a glass or plexiglass support. For radiation belonging to X-rays, plastic materials will be used, for example. In a particularly advantageous alternative embodiment, a material sold under the brand KAPTON by the company DUPONT de NEMOURS is used.

The conductor tracks deposited on the support form patterns making it possible to generate, when traversed by an electric current, the desired magnetic field.

In a first embodiment of the device according to the present invention, the absorption due to the patterns of conductors is negligible, the conductor, in view of the thickness of the tracks used, which can be considered transparent. In the case of electromagnetic radiation belonging to the visible spectrum, transparent light conductors are used, such as, for example, those used in certain photovoltaic panels or in transparent calculators. In the case where the electromagnetic radiation belongs to X-rays, beryllium, or aluminum deposited in a thin layer, or plastic conductors is used, for example.

In a second embodiment of a coil according to the present invention, conductors are used whose absorption of electromagnetic radiation risks disturbing the image. In such a case, patterns are available, having a uniform absorption over substantially the entire surface of the coil. For this, for example, a uniform layer of conductors is deposited, to the resolution of the display device. For example, conductive tracks are formed by making cuts, for example by chemical ablation, in the uniform surface of the conductor. Such cuts will delimit conductive tracks. These cuts, however, are too fine to have a detectable influence on the image formed.

In a particularly advantageous variant of the device according to the present invention, several superimposed conductive patterns are used, separated by insulating layers. Thus, it is possible to produce complementary patterns whose total absorption by radiation, for example X-rays, is substantially constant over the entire surface of the coil. Thus, any spatial and temporal parasitic modulation of the signal which must be transmitted is avoided.

It is of course possible to associate the coil according to the present invention with other means to limit the effects of parasitic magnetic fields. For example, the faces of the imaging device which do not have to allow electromagnetic radiation to pass are covered with a shield which channels the magnetic field lines.

The present invention aims to solve the problem posed by magnetic fields on charged particles. The problem is solved by using a coil comprising a support and at least one electrical conductor, characterized in that the support is a plate of substantially constant thickness and that the conductor is deposited on the support so as to have an absorption of electromagnetic waves in a predetermined frequency band constant over almost the entire surface of the coil.

• - la figure 1 est une coupe d'un premier exemple de réalisation de bobine selon la présente invention ;
• - la figure 2 est une coupe d'un deuxième exemple de réalisation de bobine selon la présente invention ;
• - la figure 3 est une coupe d'un troisième exemple de réalisation de bobine selon la présente invention ;
• - la figure 4 est une coupe d'un quatrième exemple de réalisation de bobine selon la présente invention ;
• - la figure 5 est un schéma d'un exemple de réalisation de bobine selon la présente invention ;
• - la figure 6 est un schéma d'un premier exemple de réalisation d'un dispositif d'imagerie mettant en oeuvre la bobine selon la présente invention ;
• - la figure 7 est un second exemple de réalisation d'un dispositif d'imagerie mettant en oeuvre la bobine selon la présente invention.

The invention will be better understood by means of the description below and the appended figures given as nonlimiting examples among which:

• - Figure 1 is a section of a first embodiment of the coil according to the present invention;
• - Figure 2 is a section of a second embodiment of the coil according to the present invention;
• - Figure 3 is a section of a third embodiment of a coil according to the present invention;
• - Figure 4 is a section of a fourth embodiment of a coil according to the present invention;
• - Figure 5 is a diagram of an embodiment of a coil according to the present invention;
• - Figure 6 is a diagram of a first embodiment of an imaging device implementing the coil according to the present invention;
• - Figure 7 is a second embodiment of an imaging device using the coil according to the present invention.

In Figures 1 to 7 the same references have been used to designate the same elements.

The coil 2 of FIG. 1 comprises a support 3 constituted by a plate, the two main faces of which are substantially equidistant over the entire surface of the coil. The plate 3 having to absorb as little as possible of electromagnetic radiation in a predetermined bandwidth, is advantageously made of a dielectric material. The dielectric material is adapted to the chosen bandwidth. The plate 3 is not necessarily flat. It can for example conform to the input and / or output face of a display device to which it is adapted. Mention may be made, by way of nonlimiting example, of spherical, elliptical or hyperbolic caps.

On a first face of the support 3 is deposited a first pattern 12 of conductive tracks 1. The flow of current in the tracks 1 ensures the generation of the desired magnetic field.

In a first alternative embodiment, not illustrated, the delimitation between the tracks 1 of the pattern 12 is constituted by grooves of small width compared to the resolution of the imaging device. In such a case, it is sufficient to ensure the return of current to obtain a complete coil. This return of the current can be carried out on the same face as the pattern 12 or on the opposite face.

This type of solution can also be adopted in the case where a material is used whose absorption of electromagnetic radiation is negligible to produce the conductive tracks 1.

Otherwise, in order not to obtain spatial modulation of the image by the box 2 according to the present invention, at least one second pattern 13 is used, complementary to the first pattern 12. In the example of FIG. 1, the pattern 13 consisting of the conductive tracks 10 is deposited on the second face of the support 3 of the coil 2. The tracks 10 of the pattern 13 are complementary to the tracks 1 and of the pattern 12, that is to say that on the path of the radiations electromagnetic patterns 10 fill the spaces left free by tracks 1.

It is understood that neither the tracks 1 nor the tracks 10 are of necessarily constant width.

Tracks 1 and tracks 10 are interconnected, in at least one point through a junction 11 made in the support 3. The number of interconnections depends on the geometry of the patterns 12 and 13. Insofar as it is not possible to place the interconnections outside the area of image formation, it is important to take care that the interconnections 11 absorb the electromagnetic radiation as little as possible. In the example illustrated in Figure 1, the interconnection 11 is located in the center of a coil 2, for example circular.

We choose the shape of the patterns 12 and 13 and therefore tracks 1 and 10 so as to obtain the desired magnetic field. In all cases, it is imperative that the fields produced by the tracks 1 of the pattern 12 are added to the field generated by the tracks 10 of the pattern 13. For example the patterns 12 and 13 include concentric arcs and / or square spirals . Advantageously, the patterns 12 and 13 comprise spirals, for example logarithmic.

In the case where materials absorbing electromagnetic radiation are used, tracks 1 and 10 of thin thickness are used. However, a sufficient thickness is chosen to conduct, without damaging the coil 2, the current necessary for generating the desired magnetic field. The coil 2 of FIG. 1 is advantageously produced in known technologies in the production of double-sided printed circuits. In such technologies, it is known to have precision on the order of a tenth of a millimeter. Such details will often be sufficient for light amplifiers used in radiology comprising a coil 2 according to the present invention. If higher details are desired, it is important to take the greatest care in producing the printed circuit.

Advantageously, a deposition of the tracks 1 and 10 of the patterns 12 and 13 is carried out, the support 3 being flat, then if necessary it is given the desired shape. In this case it is advantageous to use flexible printed circuit supports such as, for example, the material sold under the KAPTON brand by the DUPONT de NEMOURS company.

In FIG. 2, an exemplary embodiment of coils 2 according to the present invention can be seen comprising at least two patterns 12 and 13 deposited on the same face of the support 3. In order not to short-circuit the tracks 1 and 10 of the patterns 12 and 13 an insulating layer 14 must be interposed between the patterns 12 and 13. The layer 14 is for example an insulating varnish. It is understood that one can use more than two layers on the face of the support 3 used. Likewise, the fact of using a plurality of layers on one of the faces does not prevent the use of the second face for depositing complementary patterns.

In the case of FIG. 2, the interconnection 11 between the patterns 12 and the patterns 13 is achieved by an absence of deposition of the insulating material 14 at the location where the interconnection is desired. Of course, at this location there must be a track 1 belonging to the pattern 12 and / or a track 10 belonging to the pattern 13. If at this location the track 1 and the track 10 are present, a local allowance is obtained. In an alternative embodiment, the track, for example 10 of the pattern 13, only touches the edges of the area not insulated by the material 14, the track 1 of the pattern 13. In this case, the formation of an extra thickness is avoided. ensuring electrical continuity.

Advantageously, the technologies of multilayer printed circuits are used.

In FIG. 3, one can see an embodiment of a coil 2 according to the present invention comprising two patterns 12 and 13 deposited on the same face of the support 3 electrically insulated by a varnish 14. In the example illustrated in the figure 3, the connection 11 placed at the level of the axis 15 of the coil 2 is produced by touching the track 10 and the track 1 without excess thickness on the path of the electromagnetic rays parallel to the axis 15. In FIG. 3, only two patterns 12 and 13 are represented and it is good understood that the use of more patterns deposited on one and / or the other face of the support 3 does not depart from the scope of the present invention. The coil illustrated in FIG. 3 is advantageously produced by screen printing technologies using conductive ink. In the case where it is desired to obtain a non-planar coil it may be advantageous to first of all give the support a shape and to deposit the patterns on a support having a final shape. In addition, screen printing with conductive ink allows the production of patterns 12 and 13 of high precision. You can also screen print flat and then bend the support.

In Figure 4, we can see an example of coil 2 according to the present invention having a spherical cap shape. In this case, it is possible to take into account the incidence of the rays 16 of electromagnetic energy having to pass through the coil 2 to determine the arrangement and the thicknesses of patterns 12 and 13, so that the energy absorption is uniform. over the entire surface of the coil, for operating incidence. However, for small thicknesses and patterns 12 and 13, the variations in absorption of electromagnetic radiation with the incidence will be small with the angle of incidence of the rays 16. Thus, this variation in absorption will have very little influence on the quality of the images obtained.

In FIG. 5, one can see an example of patterns 12 capable of being deposited on the coil 2 according to the present invention. In the example illustrated in Figure 5, the pattern 12 is a spiral connecting the center of the coil 2 to the edge. In the center, there is a connection 11 with a complementary pattern 13 deposited on, for example the other face of the coil 2.

In a first exemplary embodiment illustrated in FIG. 5, the spiral has substantially the same width from the center to the edge of the coil 2.

Advantageously, the width of the spiral varies over the surface of the coil 2. For example, the thickness of the spiral increases from the center to the edge of the box. Advantageously, the two limits of the spiral delimiting the pattern 12 are themselves spirals.

It is possible to use other forms of patterns, such as for example a square spiral, concentric circles belonging alternately to pattern 12 and to pattern 13. Similarly, it is possible to use more than two patterns to obtain constant absorption on the surface of the boblne 2.

In Figure 6, we can see a section of an image intensifier tube, applicable for example in medical or industrial radiology comprising a coil 2 according to the present invention. Image intensifier tubes in radiology are known as such and have been described, for example, in the "THOMSON-CSF technical review", Volume 8 number 4 of December 1976. Such a tube includes for example a screen input 5 capable of converting X-rays into photons 10, for example having passed through an object 110 to be radiographed. In contact with the input screen 5 is arranged a photocathode 1 capable of converting the X photons into electrons. The electrons can be accelerated and guided for example three electrodes 6 and the anode 9 towards the observation screen 300, the observation screen 300 ensures the conversion of the electrons 15 into visible light.

The image intensifier tube further comprises a voltage generator 130 making it possible to supply the various electrodes via cables 14 and polarization resistors 120.

To reduce the influence of the magnetic field, a magnetic shield 200 was first placed around the image intensifier tube. However, this shield is absent from the entry and exit face of the tube so as not to interfere how it works. The tube according to the present invention further comprises a coil 2 according to the invention capable of generating a magnetic field which, to cancel the effect of the Earth's magnetic field should have the same amplitude and an opposite polarization. To determine the value of the earth's magnetic field, a detector 18 is used. The detector 18 is for example a HALL effect probe. In the variant embodiment of the device in FIG. 6, the detector 18 is placed in the axis of the image intensifier tube behind the observation screen 300. Advantageously, sufficient space is left between the screen 300 and the probe 18 to allow observation or recording of the screen 300. In this case, the probe is placed behind the observer or the recording device. This arrangement has the advantage of measuring the axial field generating distortion without hampering the operation of the image intensifier tube.

In an alternative embodiment, one or more pairs of detectors 18 are used which are placed symmetrically around the coil 2. Such detectors 18 are connected to a control device 170 which cancels the magnetic field measured by the detectors. These magnetic fields measured by the detectors 18 correspond to the sum of the disturbing magnetic field and the magnetic field generated by the coil 2. Compensation is thus carried out. Advantageously, the detectors 18 are used in pairs. Thus, it is possible to carry out mounting in opposition making it possible to eliminate by subtraction the variations of the output signal of the detectors 18 as a function of the temperature.

The detector 18 is connected to the coil 2 surrounding the image intensifier tube, for example by means of a control device 170 which converts the input signal generated by the detector 18 to a current supplied to the coil 2. The control device 170 is for example an amplifier, or a servo device.

In a first alternative embodiment of the device according to the present invention, a flat coil 2 is used as illustrated in FIG. 6.

In a second variant, we use a coil 2 conforming to the input screen 5. For example, the coil illustrated in FIG. 4 is used, adapted to the shape of the screen 5.

It is of course possible to use the coil 2 to carry out other types of correction such as for example the geometric distortions induced by the imperfection of the electronic optics. Thus, it is possible to produce image intensifier tubes of larger diameter which, in the absence of the coil 2, would have geometric distortions of images that are unacceptable or at least troublesome. Similarly, it is possible to produce the commonly used diameter tube with less distortion. Such tubes according to the present invention facilitate the comparisons of the images with one another and the geometric measurement on the images obtained.

In Figure 7, we can see a first embodiment of a television camera according to the present invention. In FIG. 7 is schematically represented a television camera of the vidicon type, it being understood that other types of cameras do not depart from the scope of the present invention.

The television camera 4 includes a lens 50 allowing the formation of images on a photosensitive device 100. The photosensitive device 100 is composed for example of a transparent signal plate connected to a photoconductive layer. The detector 100 is scanned by the electron beam emitted by a cathode 36. The electron beam passes first through a wehnelt 35 then through three concentration electrodes 34, 33 and 32. At the outlet of electrodes 32 is placed a deceleration grid 39. The camera further comprises an electron concentration collar 31 as well as a deflection coil. The image formed is present on an output 37 connected to the device 100. On the other hand, the device 100 is connected to the ground 19 by a resistor 38.

In the embodiment illustrated in FIG. 7, a coil 2 according to the invention has been placed behind the objective 50, as close as possible to the vacuum enclosure 135 of the camera tube 4.

It is understood that one advantageously chooses a coil 2 according to the present invention transparent to the light to which the camera 4 is sensitive, such as for example visible light, infrared and / or ultraviolet.

The return of the current is for example ensured by the grounding 19 of one of the terminals of the coil 2.

As we have seen, the distortion of the image is all the greater the lower the speed of the electrons. It is possible to use one or more conventional type correction coils in addition to the coil 2 placed for example at the cathode 36. The electron beam passes through the additional coils. In the exemplary embodiment comprising several correction coils 12 and / or 2, advantageously, each coil is supplied by its own control circuit or amplifier 17. All the control devices or amplifiers 17 are connected to the output of a device magnetic field detection 18. The magnetic field detection device 18 is for example a HALL effect probe. The magnetic field detector is advantageously placed in the axis of the electron beam when no deviation is applied to it.

In the embodiment illustrated in FIG. 7, the magnetic field detector 18 is placed behind the cathode 36. This arrangement is particularly advantageous since it does not hinder the propagation of the photons forming the image nor that of the scanning electrons. .

However, as in the case of the image intensifier it is possible to use one or more pairs of detectors 18 placed at the level of the coil 2 so as, for example, to obtain a zero resulting field corresponding to the cancellation of the stray field by the field generated by the coil 2.

On the other hand, the use of a plurality of detectors 18 placed behind, symmetrically with respect to the axis so as to obtain temperature compensation is not beyond the scope of the present invention.

The use of the coils according to the present invention for example in monitors or high definition televisions is not outside the scope of the present invention.

The present invention applies to the manufacture of two-dimensional electric coils, such as for example flat coils or coils in the form of a spherical cap. Such coils find their applications in particular in compensation for the influence of magnetic fields on beams of charged particles. They find their application in particular in imaging devices using electron beams.

Claims (19)

1. Coil (2) comprising a support (3) and at least one electrical conductor, characterized in that the support (3) is a plate of substantially constant thickness and that the conductor (1,10,12,13) is deposited on the support so as to have an absorption of electromagnetic waves in a predetermined frequency band constant over almost the entire surface of the coil (2). 2. Coil (2) according to claim 1, characterized in that the support is transparent to electromagnetic waves in the predetermined frequency band. 3. Coil (2) according to claim 1 or 2, characterized in that the electromagnetic waves are X-rays. 4. Coil (2) according to claim 1 or 2, characterized in that the electromagnetic waves include visible light. 5. Coil according to claim 1,2,3 or 4, characterized in that the conductor has additional patterns deposited on both sides of the support (3). 6. Coil according to claim 1,2,3,4 or 5, characterized in that it comprises a plurality of layers of conductors (12, 13) separated by an insulator, except at the connections between layers. 7. Coil according to claim 1,2,3,4,5 or 6, characterized in that the patterns have a spiral shape. 8. Coil according to any one of the preceding claims, characterized in that the electrical conductor comprises copper. 9. Coil according to any one of the preceding claims, characterized in that the electrical conductor comprises aluminum. 10. Coil according to any one of the preceding claims, characterized in that the electrical conductor comprises a conductive plastic. 11. Coil according to claim 1,2,3,5,6,7,8,9 or 10, characterized in that the support is made of the material sold by the company DUPONT de NEMOURS under the brand KAPTON. 12. Coil according to claim 1,2,3,5,6,7,8,9 or 10, characterized in that the support (3) comprises epoxy resin. 13. Coil according to claim 1,2,3,5,6,7,8,9 or 10, characterized in that the conductor (1, 10) is a conductive ink. 14. Coil according to claim 1,2,3,4,5 or 6, characterized in that the electrical conductor is transparent to visible light. 15. An imaging device using electron beams, characterized in that it comprises a coil according to any one of the preceding claims, connected to a generator capable of supplying a current allowing the coil to compensate for the effects on electrons of stray magnetic fields. 16. Device according to claim 15, characterized in that said device is a radiological image intensifier. 17. Device according to claim 15 or 16, characterized in that it comprises at least one probe capable of measuring the intensity of the magnetic field in the axis of the device. 18. Coil according to any one of claims 1 to 14, characterized in that the support has substantially the shape of a spherical cap. 19. Coil according to any one of claims 1 to 14, characterized in that the support (3) has the shape of a flat plate.

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