NO171527B - DEVICE FOR CATHOD RADIATORS FOR REDUCTION OF THE MAGNETIC FIELD STRENGTH IN THE ROOM'S ENVIRONMENT - Google Patents

Description

TECHNICAL AREA

The present invention relates to a picture tube device for reducing the magnetic field strength in the picture tube's surroundings, the picture tube comprising a deflection coil which produces a magnetic deflection field in the transverse direction of the electron beam and a magnetic leakage field in the picture tube's surroundings, as well as a shielding housing of magnetic material which surrounds the deflection coil.

STATE OF THE ART.

In picture tubes with magnetic deflection of the electron beam, magnetic leakage fields arise. These fields extend beyond the deflection zone and can reach a person who is near the pipe. The magnetic leakage fields are believed to cause damage due to the electric currents that are induced in the body's cells. The current strength is proportional to the time change in the magnetic field, and relatively large currents arise in the cells, e.g. due to the return pulse for the line sweep of the picture tube. In known solutions which involve reducing the magnetic field in front of the picture tube, this solution involves placing a short-circuit loop positioned horizontally above the electron tube, so that the leakage field is deflected obliquely upwards. This measure is simple, but has a limitation regarding the area of use, because the field does not decrease, but is only given

a different course. It is also suggested to shield the picture tube with a housing made of magnetic material. The housing cannot cover the projection surface or the picture screen of the electron tube and does not contribute to any reduction of the leakage field.

one in front of the tube.

DISCUSSION OF THE INVENTION..

The above-mentioned problem is solved according to the present invention, in that electrical loops are used which are connected to the deflection coils for the production of magnetic compensation fields, which are directed opposite the leakage field and reduce the field strength in front of the picture tube^ as indicated in the characteristic in patent claims.

BRIEF DESCRIPTION OF THE DRAWING FIGURES.

An embodiment of the invention will now be described in detail with reference to the drawings. Figure 1 is a perspective view showing the picture tube's deflection coil. Figure 2 schematically shows the electrical connections for the deflection coil.

Figure 3 is a cross-section through the picture tube.

Figure 4a is a perspective view of the deflection coil.

Figure 4b is a side view of the deflection coil.

Figure 4c is a rear view of the deflection coil.

Figure 5 is a plan of the picture tube with a first compensation ion loop. Figure 6 shows the compensation loop in perspective. Figure 7 shows the electrical connection of the compensation loop with the picture tube deflection coil. Figure 8a is a rear view of the picture tube with the first and second compensation loop. Figure 8b is a view of the picture tube seen from the side with the first and second compensation loops. Figure 9 illustrates an alternative embodiment for the first compensation loop. Figure 10 is a diagram showing the time variations of the magnetic field strength in the surroundings of the picture tube. Figure 11 is a further diagram of the magnetic field strength.

PREFERRED EMBODIMENTS.

Figure 1 shows schematically a magnetic deflection coil 1 in a picture tube 3, the picture surface 3a of the picture tube being shown in the figure. The coil has an upper half la and a lower half lb, which are connected in parallel, as shown in Figure 2. The coil has many windings, but for simplicity it is shown with only one winding. The coil is located at the rear part of the outside of the picture tube, and has a funnel-like shape that follows the shape of the picture tube. At the front end of the coil 1 facing the display screen, the coil halves la and lb have front conductors lc and ld which extend in a semicircle outside the picture tube 3. Electric currents 1-^ and I2 in the coil halves, where I2' provide a vertical magnetic deflection field B in the deflection zone of the picture tube 3. An electron beam 2 through the deflection zone is deflected sideways and strikes the screen surface 3a. The lateral deflection, the so-called line sweep, takes place at a frequency of 31.7 kHz, while the deflection with regard to height, i.e. the image sweep, takes place at a frequency of approx. 50Hz, and is taken care of by means of a coil not shown.

In Figure 3, the picture tube 3 is shown in a first vertical plane through the longitudinal axis of symmetry z of the tube. This plane is parallel to the direction of the deflection field B, and in Figure 1 it is denoted by VP1. The rear part 3b of the picture tube is surrounded by the deflection coil, as indicated earlier. In turn, the coil is surrounded by a shield housing 4 of ferrite with a funnel-like shape which shields the deflection field B against external disturbances. The deflection coil 1 for the high-frequency line sweep produces a magnetic leakage field BL outside the picture tube. The ferrite housing 4 acts on this leakage field, so that the field lines 5 essentially depart from the forward-facing outer edge 6 of the ferrite housing. The leakage field BL is composed of a magnetic dipole field DL and a magnetic quadrupole field KL, as will be explained below with reference to figures 4a, 4b and 4c. The deflection coil 1 is shown in figure 4a, and for the sake of clarity, the upper half la and the lower half lb are shown at a distance from each other. In Figure 1, a horizontal plane HP is drawn which includes the axis of symmetry z and is arranged at right angles to the deflection field B, the coil 1 having a projection in this plane as shown in Figure 4b. The coil is permeated by the currents 1^ and I2 and produces the above-mentioned dipole field DL, which can best be characterized by a magnetic dipole D1. In figure 1, another vertical plane VP2 is also drawn which is arranged at right angles to the axis of symmetry z, and in this plane the deflection coil 1 has a projection which is shown in figure 4. The upper half la of the projected deflection coil becomes flowed through by the current I-L and produces a magnetic dipole field which can best be characterized as a magnetic dipole D2. This dipole is parallel to the axis of symmetry z and is located at the front conductor lc of the upper coil half la. In a similar way, the lower half lb of the deflection coil will produce a magnetic dipole field with current I2, and this field can best be characterized as a magnetic dipole D3 which is located at the front conductor ld of the lower coil half lb. Both dipoles D2 and D3 are mutually opposite in direction and together they form a magnetic quadrupole Kl, which is characteristic of the above-mentioned magnetic quadrupole

KL.

The leakage field BL is considered, as mentioned above, to exert a harmful effect on a person who is in the vicinity of the field. To reduce this effect, one will try to reduce the field strength for this field, as will be described in the following. According to the present invention, two magnetic compensation fields are provided, a dipole field DK and a quadrupole field KK, to counteract the magnetic leakage field BL. Here, the dipole field DK is directed opposite the dipole field DL for the deflection coil, and the quadrupole field KK is directed opposite the quadrupole field KL for the deflection coil. In Figure 5, the picture tube 3 is shown viewed from above with the deflection coil 1 and the ferrite housing 4. The compensating dipole field DK is produced by means of a first compensating loop 7 which is located mainly in the horizontal plane. The surface in the horizontal plane HP which is surrounded by the first compensation coil has its center of gravity TP1 on the axis of symmetry z at the forward-facing outer edge of the ferrite housing 4. The loop in the example is formed with a rectangular part 7a between the dotted lines in the figure and two lobes 7b. These lobes extend from the rectangular part 7a, slanting forwards along the rear side of the picture tube 3 and outwards so that they come in line with the outer edge of the display screen 3a. The loop 7 comprises a plurality of windings, but for the sake of simplicity only one winding is shown in the figure. The first compensation loop 7 is shown in perspective in figure 6. In the area 7a, the windings for the loop are partially separated to surround the ferrite housing 4 and the picture tube 3. The remaining parts of the loop are located in the horizontal plane HP. The loop 7 is electrically connected in series with the deflection coil 1, as shown schematically in figure 7, and is permeated by the currents 1^ + By means of the loop 7, a magnetic dipole field DK is produced, which extends in an area in front of the picture tube's screen 3a. By selecting a suitable current direction in the loop 7, the compensating dipole field DK will have a direction opposite to the dipole field DL which is produced by means of the deflection coil 1, as can be seen from figure 5. The field strength for the compensating dipole field DK can be varied using a varying number of windings in the loop 7, and by changing the favorable size of the loop. The compensation dipole field DK is characterized here as a magnetic dipole DK1. This dipole has the same size and position as the above-mentioned dipole Dl with regard to the leakage field DL, and the dipole DK1 and the dipole Dl are mutually arranged with the opposite direction. By adjusting the first compensation loop 7 in this way, the strength of the dipole field DK can be adjusted so that the leakage field DL is counteracted and the resulting field strength reduced to a considerable extent. This reduction of the field strength occurs in a large area in front of the display screen 3a, if the center of gravity TP1 and the compensation loop are positioned as discussed above. The picture tube 3 is shown from behind in Figure 8a, together with the ferrite housing 4 and the first compensation loop 7. The compensating quadrupole field KK is provided by the second compensation loop 9 which comprises an upper half 9a and a lower half 9b. In Figure 8b, the picture tube is shown viewed from the side, comprising both compensation loops 7 and 9. The second compensation loop is essentially flat and parallel in relation to the second vertical plane VP2 and surrounds a surface with a center of gravity TP2 which is located on the longitudinal symmetry axis 6 at the front conductors lc and ld of the deflection coil 1. In the illustrated embodiment, the coil 9 is symmetrical about both the first vertical plane VP1 and the horizontal plane HP. However, it may be necessary for the loop 9 to have a somewhat different and asymmetrical form for compensation of the irregularities in the leakage field KL, which can be effected by e.g. a metal frame, not shown, which carries the picture tube 3. The second compensation loop is electrically connected in series with the first compensation loop 7 and the deflection coil 1, as schematically illustrated in figure 7, and is fed by the currents 1^ + I2-I the upper half 9a of the second compensation loop

9, a magnetic field is produced, which can be characterized as a magnetic dipole DK2, and in the lower half 9b, an oppositely directed dipole field is produced, which can be characterized by a magnetic dipole DK3. Both magnetic dipoles DK2 and DK3 together form a magnetic quadrupole KK1, which characterizes the above-mentioned compensating quadrupole field KK. By appropriate choice of current direction in the loop 9, loop size and number of windings, the second compensation loop 9 can be arranged so that the quadrupole field KK produced acts against the quadrupole field

KL at the deflection coil 1, and will consequently reduce the magnetic field strength in the surroundings of the picture tube 3, to a considerable extent.

An alternative embodiment of the first compensation loop 7 is shown in Figure 9. A compensation loop 8 is composed of two loop parts 8a and 8b, which are electrically connected in series with each other and with the deflection coil 1. The part loops are flat and lie in the horizontal plane HP. The surfaces surrounded by the sub-loops have a common center of cavitation TP1 at the same point as the first compensation loop 7 at the front edge 6 of the ferrite housing 4. It should be understood that the compensation loop 7, unlike the compensation loop 8, affects the quadrupole field in the surroundings around the picture tube 3. The compensating ion loop 7 namely has a loop part 7c according to Figure 6, which is parallel to the second vertical plane VP2. The size and number of windings in the second compensation loop 9 must be adjusted in relation to the way in which the first compensation loop is realized.

Figure 10 shows a diagram with an example of how the magnetic field strength in the surroundings around the picture tube is affected by the compensation loop 7. Figure 11 shows a diagram illustrating the corresponding effect when both compensation loops 7 and 9 are connected. It should be understood that the y component of the magnetic field is measured in the horizontal plane HP along a circle with a radius of 40 cm that encloses the picture tube. The center of this circle is located on the longitudinal axis of symmetry z in the vicinity of the centers of gravity TP1 and TP2 for the loops, so that the distance between the display screen 3a and the measurement points on the z-axis is 30 cm. The numbers along the x-axis on the respective diagrams indicate the time variation in mT/s of the magnetic field. The measured values for the picture tube without any compensation loop are plotted on a curve 10. The measured values with the first compensation loop 7 connected are plotted on a curve 11. Measured values with both the first compensation loop 7 and the second compensation loop 9 connected is plotted on curve 12 in Figure 11.

There is described above a device for producing magnetic compensation fields BK which counteract the magnetic leakage field BL which has its origin in the deflection coil 1 for the line sweep. A leakage field coming from a deflection coil for the image sweep can also be counteracted by means of a corresponding device.

Claims (6)

1. Device for a picture tube (CRT) for reducing the magnetic field strength in the picture tube's surroundings, the picture tube comprising a deflection coil which produces a magnetic deflection field in the transverse direction of the electron beam and a magnetic leakage field in the picture tube's surroundings, as well as a shielding housing of magnetic material which surrounds the deflection coil - one, characterized in that the device comprises a first compensation loop (7, 8) which extends over the picture tube (3) in an area at the shielding housing (4) and is arranged mainly symmetrically about a first plane (HP) which is arranged at right angles to the direction of the magnetic deflection field (B) and includes the longitudinal axis of symmetry (z) of the picture tube and a first vertical plane (VPl) as if grasps said axis of symmetry (z) and is arranged at right angles to the horizontal plane (HP), and that the first compensation loop (7, 8) is electrically connected to the deflection coil (1), the projected area of the first compensation loop (7, 8) in the first plane (HP) has such a size and current direction (I]_+I2) for the first compensation ion loop (7, 8) is arranged in such a way that a magnetic compensation field (DK) is produced, said field mainly having the opposite direction to the magnetic leakage field (DL, KL) within an area in front of the image surface (3a) of the picture tube (3) to reduce the magnetic field strength in this area. 2. Device as stated in claim 1, in that the deflection coil has front electrical conductors which partially enclose the picture tube, characterized in that another compensation loop (9) with an upper half (9a) and a lower half (9b) is placed outside the picture tube ( 3) in an area at the front conductors (lc, ld) of the deflection coil (1), and extends mainly parallel to another vertical plane (VP2) which is perpendicular to the longitudinal axis of symmetry (z), the other compensation ion loop e is electrically connected to the deflection coil (1), so that both halves (9a, 9b) of the loop (9) produce mutually opposite magnetic fields (DK2, DK3), as the current direction (I1+I2) in the other compensa- sion loop (9) is arranged so that the loop produces a magnetic compensation field (KK) which is directed opposite the leakage field (DL, KL) in an area around the picture tube (3) to reduce the magnetic field strength in this area. 3. Device as stated in claim 1 or 2, in that the screen housing of magnetic material is funnel-shaped and includes a wide end with an edge facing the display screen of the picture tube, characterized in that the first compensation loop (7, 8) mainly extends in said horizontal plane (HP) and that the projected area in the horizontal plane (HP) has its center of gravity (TP1) on the longitudinal axis of symmetry (z) at the wide end edge (6) of the screen housing (4). 4. Device as specified in claim 2 or 3, characterized in that the projected area of the second compensation loop (9) on the second vertical plane (VP2) has its center of gravity (TP2) on the longitudinal axis of symmetry (z) at the front conductor specified above (lc, ld) of the deflection coil (1) facing the projection surface (3a). 5. Device as stated in one of the claims 1 - 4, characterized in that the first compensation loop (7, 8) is connected in series with the deflection coil (1). 6. Device as stated in one of claims 2 - 5, characterized in that the second compensation loop (9) is connected in series with the deflection coil (1).