Cathode-ray tube screening arrangement

Abstract

 A cathode ray tube (CRT) has a deflection yoke (22) and an internal conductive layer (20). A conductive guard screen (24) is positioned between the deflection yoke (22) and the internal conductive layer (20) for reducing capacitative coupling between them. This reduces AC electric fields emitted from the viewing surface of the CRT. The guard screen comprises a flexible circuit wrapped around the outside of the CRT, the circuit having interdigitated sets of conductive tracks or fingers.

Description

Background to the Invention

[0001] This invention relates to cathode ray tubes (CRTs). The invention is particularly, although not exclusively, concerned with CRTs for use in monitors and display terminals for data processing apparatus.

[0002] The problem of electric field emissions from CRTs is of increasing concern, and regulations are being introduced in some countries, specifying the maximum permissible amounts of such emissions.

[0003] Electric field emissions from a CRT comprise both DC and AC components.

[0004] The DC electric field generated on the surface of a CRT screen is relatively easy to reduce to acceptable levels by the incorporation of a conductive coating, available from all tube manufactures. However, 'normal' conductive coatings are high resistance and cannot cope with high levels of AC field. Very low Ohmic coatings or screens are available but at high cost.

[0005] The majority of AC electric field is produced by capacitive coupling between the scan coils (deflection yoke) and the aluminised internal final anode layer of the CRT. (This layer is connected to the Extra High Tension supply, around 10kV to 17kV for normal monochrome tubes). This capacitance is quite significant, being in the order of 100pF for a 14" CRT with a 20mm neck. Scan voltages of several hundred at line rate (30kHz to around 80kHz or more) and tens of volts at frame rate (between 50 and 100Hz) with fast edges during flyback, are capacitively coupled and modulate the aluminised layer inside the tube. This layer, though very thin covers the tube front. As the EHT source impedance is fairly high, substantial AC voltages can be induced at line and frame rate in this layer.

[0006] An object of the present invention is to provide way of reducing this AC component which does not have these problems.

Summary of the Invention

[0007] According to the invention there is provided a CRT having a deflection yoke and an internal conductive layer, characterised by a conductive guard screen between the deflection yoke and the internal conductive layer for reducing capacitative coupling between them, thereby reducing AC electric fields emitted from the viewing surface of the CRT.

Brief Description of the Drawings

[0008] 

Figure 1 is a sectional elevational view of a CRT embodying the invention.

Figure 2 is a cross-sectional view showing the guard screen in more detail.

Figure 3 shows a typical conductive pattern on the guard screen.

Description of an Embodiment of the Invention

[0009] One CRT in accordance with the invention will now be described by way of example with reference to the accompanying drawings.

[0010] Referring to Figure 1, the CRT comprises an evacuated glass envelope 10 having a cylindrical neck position 12, a flared portion 14 and a face 16. An electron gun 18 is positioned in the neck 12 of the tube, and the face 16 is coated with a phosphor, in the conventional manner.

[0011] The envelope 10 has an internal aluminised layer 20 on its inner surface, extending from the end of the neck 12, up the flared portion 14, and over the screen 16.

[0012] The CRT has scan coils 22 positioned around the neck 12, for deflecting the electron beam from the electron gun 18.

[0013] A conductive guard screen 24 is positioned around the CRT, between the scan coils 22 and the envelope 10. This screen is connected, in use, to ground potential. The guard screen 24 thus prevents or reduces the voltages induced between the coils 22 and the internal layer 20, and hence reduces AC emissions from the face 16 of the CRT. It has been found that a reduction in the order of 90-95% of the AC emissions can be achieved by use of the guard screen.

[0014] Referring to Figure 2, the guard screen 24 is formed from a flexible printed circuit, wrapped around the envelope 10. The flexible printed circuit comprises a flexible insulating substrate 26, having first and second conductive patterns 28, 30 on opposite sides of the substrate. The substrate 26 may comprise a polyimide film such as for example KAPTON, having a thickness of 50 microns. Alternatively, the substrate may comprise a KAPTON base with insulating coating layers, with a total thickness of 150 microns.

[0015] Each of the conductive patterns comprises a set of parallel fingers, the fingers of the two patterns being interdigitated so that, the fingers of one set are positioned over the gaps between the fingers of the other set. Thus, between them, the two sets of fingers provide complete screening, without any gaps.

[0016] The reason why the screen is formed in this way, rather than as a continuous conductive layer, is to prevent or reduce eddy currents in the screen, induced from the scan coils, which would generate excessive heat and cause potential failure of the scan circuits and associated components.

[0017] Referring now to Figure 3, this shows a typical conductive pattern on one side of the substrate. The pattern on the otherside is similar, but has its conductors offset to produce the interdigitated arrangement.

[0018] As can be seen in Figure 3, each pattern includes a set of parallel fingers 32, which, when the flexible printed circuit is wrapped around the CRT, form a cylindrical portion of the guard screen around the neck of the envelope. Each pattern also includes two sets of concentric, arc-shaped fingers 34 which, when the guard screen is in position, form a conical portion, around the flare of the envelope.

[0019] Other patterns are possible. For example, the arc-shaped fingers may be replaced by radial fingers.

[0020] The width of each finger preferably does not exceed approximately twice the line frequency AC signal penetration depth, otherwise the scan energy will be dissipated in heat generated from eddy current loss. The finger width in millimetres may be calculated from :-


Where

W = Maximum finger width.

k = Constant for material, for copper k = 72 @ 70°C, 75 @ 100°C.

f = Maximum operating frequency.

[0021] Typically, the maximum finger width lies in the range 0.5mm to 0.8mm.

[0022] The fingers do not have to be copper (ie standard PCB conductive coating), but could be formed in a conductive ink from a screen printing technique. Using this method a very thin, flexible guard screen could be manufactured in quantity and at competitive cost. The screen must be thin in order to fit between the scan coils and CRT neck, and flexible to form a cone around the CRT flare.

[0023] A further advantage of fitting a screen between the tube and scan coils is the improved immunity to the scan circuitry to tube 'flash over'. This occurs when the EHT in the tube final anode flashes across to other tube electrodes (a well known phenomenon). Capacitive coupling to the scan coils can cause failure of the electronic drive circuitry but with a screen fitted as described above, this problem would be vastly reduced.

Claims

1. A cathode ray tube (CRT) having a deflection yoke (22) and an internal conductive layer (20), characterised by a conductive guard screen (24) between the deflection yoke and the internal conductive layer for reducing capacitative coupling between the deflection yoke and internal conductive layer, thereby reducing AC electric fields emitted from the viewing surface (16) of the CRT.

2. A CRT according to Claim 1 wherein the guard screen comprises a flexible circuit wrapped around the outside of the CRT.

3. A CRT according to Claim 2 wherein said flexible circuit comprises an insulating substrate (26) with a conductive pattern (28, 30) printed on it in conductive ink.

4. A CRT according to Claim 2 wherein said flexible circuit comprises an insulating substrate (26) with a conductive pattern (28, 30) formed by etching a conductive layer on the substrate.

5. A CRT according to any preceding claim wherein the guard screen comprises interdigitated sets of conductive tracks or fingers (28, 30).

6. A CRT according to any preceding claim wherein the guard screen comprises a first generally cylindrical portion (32) covering the neck of the CRT and a second generally conical portion (34) covering the flared portion of the CRT.

Drawing