JPH0675379B2 - Traveling wave type deflection device - Google Patents

Description

The present invention relates to a traveling wave type deflection device for a cathode ray tube (CRT).

[Prior Art] If the deflection voltage does not change while the electron beam passes through the deflection device, it is possible to obtain deflection of the electron beam proportional to the magnitude of the deflection voltage. However, if the deflection voltage changes while the electron beam passes through the deflector due to the high frequency of the deflection voltage, the desired deflection becomes impossible.

In order to solve this problem, a traveling wave type deflector is used. In the traveling wave type deflection device, the traveling speed of the deflection signal propagating from one end to the other end of the traveling wave type deflection conductor (delay circuit) of the helical type or the like and the traveling speed of the electron beam are substantially matched. As a result, the deflection action time becomes long, the electron beam can be sufficiently deflected, and it becomes possible to provide a wide-band deflection device.

In order to form such a traveling wave type deflection device easily and firmly, it is disclosed in Japanese Patent Publication Nos. 57-10538 and 57-10539 that a strip-shaped conductor is spirally wound around a long insulating substrate. It is disclosed. Further, since the facing distance between the pair of spiral conductors gradually increases along the beam traveling direction, it is also possible to provide a capacitance correction member in order to compensate for the nonuniformity of the characteristic impedance based on this. Is disclosed in.

[Problems to be Solved by the Invention] By the way, the conventional device is not manufactured in consideration of the reduction of the inductance at the end of the spiral conductor. That is, at one end and the other end of the spiral conductor, the spiral conductor is arranged adjacent to one side, but the spiral conductor is not arranged on the other side, so that the inductance due to the interaction is small. Therefore, the characteristic impedance from one end to the other end of the spiral conductor cannot be made uniform.

FIG. 8 schematically shows the characteristic impedance of a conventional deflector having a length of 1. The characteristic impedances Z ₁ and Z ₂ at one end portion A and the other end portion B of the deflecting portion are lower than the characteristic impedance Z _{0 at the} central portion. Assuming that the terminating resistor R is connected to such a deflection unit at a short distance and the amplifier Q is also connected at a short distance, R =
The traveling wave signal supplied from the amplifier Q when Z ₀ = Z ₁ = Z ₂ is transmitted in synchronization with the electron beam in the deflection section, deflects the electron beam, and is terminated by the terminating resistor R. However, when R = Z ₀ = Z ₁ > Z ₂ , the traveling wave signal supplied from the amplifier Q is transmitted in synchronization with the electron beam through the deflection unit,
The electron beam is deflected, but the signal wave signal is partially reflected at the other end portion B, and the backward wave transmission is generated in the deflection unit (delay circuit),
Moreover, the electron beam is deflected by this backward wave. The backward wave passes through the one end portion A and is reflected again by the amplifier Q to generate a forward wave.

Further, as shown in FIG. 8, when both Z ₁ and Z ₂ are not equal to Z ₀ and R, reflection occurs at both one end portion A and the other end portion B.

If reflection occurs in the traveling wave type deflector as described above, ideal deflection becomes impossible and waveform distortion occurs.

Therefore, it is an object of the present invention to provide a traveling wave type deflection device which can easily make the characteristic impedance uniform.

[Means for Solving the Problems] The present invention for achieving the above object comprises first and second deflecting bodies that are arranged opposite to each other with an electron beam passage interposed therebetween, and the first deflecting body is a first deflecting body. One spiral conductor and a first ground conductor extending in the same direction as the first spiral conductor and arranged inside the first spiral conductor; The deflector comprises a second spiral conductor and a second ground conductor extending in the same direction as the second spiral conductor and arranged inside the second spiral conductor. In the corrugated deflection device, the first and second spirals are arranged so as to be adjacent to or close to the first and second ground conductors and to face the first and second spiral conductors, respectively. At least the first turn and the last one turn of the conductor A traveling wave characterized in that first and second characteristic impedance compensating plates formed so as not to exist are provided, and the first and second spiral conductors have substantially the same characteristic impedance over the entire length. It relates to a mold deflection device.

As claimed in claim 2, narrowing the widths of the portions of the first and second ground conductors corresponding to the one end and the other end of the first and second spiral conductors to make the characteristic impedance uniform. You can also

[Operation] In any of the first and second aspects of the invention, the reduction of the inductance at the end of the spiral conductor that occurs in the conventional device is compensated by the characteristic impedance compensating plate or the capacitance depending on the ground conductor. The characteristic impedance can be made uniform.

When the characteristic impedance is made uniform as described above, the reflection at the end of the deflection signal can be prevented or reduced, and the waveform distortion can be improved.

[Embodiment] Next, a CRT of an oscilloscope according to an embodiment of the present invention will be described with reference to FIGS.

As shown in FIG. 6, the CRT 1 has an evacuated pipe body 2,
It is composed of a cathode ray tube electrode assembly 3 and a fluorescent screen 4 incorporated therein.

The cathode ray tube electrode assembly 3 includes an electron gun 7 including an assembly 6 of a cathode and a control grid and an anode 6, a first quadrupole lens 8, a second quadrupole lens 9, and a vertical deflection device 10 related to the present invention. It comprises a third quadrupole lens 11, a horizontal deflection device 12 and a deflection magnifying electron lens 13, which are supported on common insulating supports 14, 15.

The fluorescent screen 4 includes a festival plate 16 and a fluorescent material layer.
It consists of 17 and a conductor layer 18. The conductor layer 18 is connected to the post-acceleration electrode 19 extending to the vicinity of the deflection magnifying electron lens 13.

The vertical deflecting device 10 according to the present invention comprises first and second deflecting bodies 21 and 22 arranged so as to sandwich the beam passage 20 as is apparent from FIGS. 1, 2 and 4. ing.
The first deflector 21 includes a first insulating substrate 23, a first spiral conductor 24, and a pair of first ground conductors 25a and 25b, and extends in the beam traveling direction (Z-axis direction). Are arranged as follows. Similarly, the second deflector 22 also has a second insulating substrate.
26, a second spiral conductor 27, and a pair of second ground conductors
28a and 28b, and are arranged so as to extend in the beam traveling direction (Z-axis direction). As is clear from FIG. 6, the mutual distance between the first and second deflectors 21 and 22 gradually increases as the beam travels in the beam traveling direction. As a result, the electrostatic capacities of the first and second spiral conductors 24 and 27 also change, and therefore the electrostatic capacity compensating plate 35 is used to compensate for this.
a and 35b are arranged along the deflecting bodies 21 and 22.

The first and second ground conductors 25a, 25b, 28a, 28b are the first and second insulating substrates 23, 26 and the first and second spiral conductors.
A groove 29 made of a strip-shaped metal plate having a strength capable of supporting 24 and 27 and provided in the first and second insulating substrates 23 and 26 so as to extend in the beam traveling direction (Z-axis direction). ,
Located within 30. First and second ground conductor 25
The a, 25b, 28a and 28b are located inside the first and second spiral conductors 24 and 27, and together with the first and second spiral conductors 24 and 27 form a traveling wave transmission circuit.

The first and second spiral conductors 24 and 27 are formed by winding strip-shaped metal plates around the first and second insulating substrates 23 and 26.
In order to form the first and second spiral conductors 24 and 27 easily and accurately, a pair of side surfaces of the first and second insulating substrates 23 and 26 have grooves 31 as shown in FIG. Is provided.

The pair of first ground conductors 25a and 25b are connected to each other by a connecting conductor 32 at one end and the other end as shown in FIG. 1, and are bent so as to function as a supporting leg of the first deflector 21. It is supported by the insulating support 14 of FIG. The second ground conductors 28a and 28b are also configured similarly to the first ground conductors 25a and 25b.

The first and second characteristic impedance compensating plates 33a, 33b, 34a, 34b each consisting of two sheets according to the present invention are made of conductive plates (metal plates), and the first and second ground conductors 25a, 2
It is located on 5b, 28a, 28b. As is clear from FIG. 1, the characteristic impedance compensating plates 33a and 33b are spiral conductors.
The spiral conductor 24 does not face the entire length of the spiral conductor 24, but faces the region other than the one end and the other end. That is, the capacitance between the portion formed of the combination of the characteristic impedance compensating plates 33a and 33b and the ground conductors 25a and 25b and the spiral conductor 24 is the same at one end and the other end of the spiral conductor 24. The characteristic impedance compensating plates 33a and 33b are arranged so as to be smaller than the space. The amount of decrease in capacitance is set so as to correspond to the amount of decrease in inductance at one end and the other end of the spiral conductor 24. In addition, the second characteristic impedance compensating plates 34a, 3
4b has the same structure as the first characteristic impedance compensating plates 33a and 33b.

First and second spiral conductors in the vertical deflection device 10
Inductance per turn of 24 and 27 is L,
Twice the opposing capacitance C ₁ per turn of the first and second spiral conductors 24 and 27, and between the first and second spiral conductors 24 and 27 and the capacitance compensation plates 35a and 35b. C ₂ per turn of each of the first and second spiral conductors 24 and 27, ground conductors 25a, 25b, 28a and 28b, and characteristic impedance compensating plate
The sum of the capacitance C ₃ per one turn between the combination of 33a, 33b, 34a and 34b and C ₃ is the capacitance between the adjacent ones per turn of the first and second spiral conductors 24 and 27. The characteristic impedance Z ₀ and the phase velocity v of the delay circuit based on the first and second deflectors 21 and 22 where C ₀ and the angular frequency are ω are given by the following equations.

The second term and the following terms that depend on the angular frequency ω in equations (1) and (2) are called dispersion terms, and it is desirable that they are as small as possible. In this embodiment, since the insulating substrates 23 and 26 support the spiral conductors 24 and 27, it is possible to reduce C ₀ .
The terms below can be reduced.

Now, ignoring the second term and below in equation (1), the characteristic impedance is Can be shown as The inductance per turn at the end of the spiral conductor 24 is L ₁ , the capacitance is C ₄ , the inductance per turn at the parts other than both ends is L ₂ , and the capacitance is
If you say C ₅ , Adjust the capacitances C ₄ and C ₅ so that That is, since the inductance L ₁ at the end is smaller than the inductance L _{2 at} other portions, it is necessary to reduce the capacitance C ₄ at the end.
The characteristic impedance is made uniform by increasing the capacitance C ₅ of the portion other than the end portion, and a transmission line having no reflection phenomenon is formed.

[Modification] The present invention is not limited to the above-described embodiments, and the following modifications are possible, for example.

(1) Instead of providing the characteristic impedance compensating plates 33a, 33b, 34a, 34b, the width of the portions of the ground conductors 25a, 25b, 28a, 28b facing the one end and the other end of the spiral conductor 24 is narrowed. The capacity may be reduced by.

(2) Instead of adjusting the capacitance depending on the location of the characteristic impedance compensating plates 33a, 33b, 34a, 34b, the width may be adjusted to adjust the capacitance.

(3) The characteristic impedance compensating plates 33a to 34b may be formed to have a wider width in the beam traveling direction as shown in FIG. If formed in this way, it is possible to compensate for the change in electrostatic capacitance due to the mutual distance between the pair of deflecting bodies 21 and 22 gradually increasing in the beam traveling direction as shown in FIG. In this case, the capacity compensating plates 35a and 35b shown in FIG. 6 can be omitted.

(4) Two earth conductors 25a, 25b, 28 for each deflector 21, 22
a, 28b and two characteristic impedance compensating plates 33a, 33b,
Instead of providing 34a and 34b respectively, one earth conductor and one characteristic impedance compensating plate may be provided, or one earth conductor having a characteristic impedance compensating function may be provided.

[Effects of the Invention] As is clear from the above, according to the present invention, it is possible to prevent the characteristic impedance from decreasing at the ends of the spiral conductor and improve the uniformity of the characteristic impedance. This suppresses waveform distortion due to reflection.

[Brief description of drawings]

FIG. 1 is a sectional view showing a traveling wave type deflecting device according to an embodiment of the present invention by cutting line II in FIG. 2, and FIG. 2 is a portion corresponding to line II-II in FIG. Sectional view, FIG. 3 is a plan view showing a characteristic impedance compensating plate, FIG. 4 is a perspective view showing a part of a deflector, FIG. 5 is a partially cutaway perspective view showing an insulating substrate, and FIG. 6 is a CRT. FIG. 7 is a partially cut-away side view showing FIG. 7, FIG. 7 is a plan view showing a modified characteristic impedance compensating plate, and FIG. 8 is a view showing a deflection circuit with the characteristic impedance schematically shown. 10 ... Vertical deflection device, 21, 22 ... First and second deflecting bodies, 23 ... First insulating substrate, 24 ... First spiral conductor, 25a, 25b ... First ground Conductor, 26 ... Second insulating substrate, 27 ... Second spiral conductor, 28a, 28b ... Second earth conductor, 33a, 33b, 34a, 34b ... Characteristic impedance compensation plate.

Claims (2)

[Claims] 1. A first deflector and a second deflector, which are opposed to each other with an electron beam passage interposed therebetween, and the first deflector is the same as the first spiral conductor and the first spiral conductor. A first ground conductor extending in a direction and disposed inside the first spiral conductor, wherein the second deflector has a second spiral conductor and the second spiral. A traveling wave type deflection device comprising: a second conductor extending in the same direction as the linear conductor and arranged inside the second spiral conductor; Adjacent to or adjacent to the first and second spiral conductors, respectively, and at least at the first and last turns of the first and second spiral conductors. First and second characteristic impedances formed so as not to face each other A traveling wave type deflection device, characterized in that a scanning compensator is provided, and the first and second spiral conductors have substantially the same characteristic impedance over the entire length. 2. A first and a second deflecting body, which are opposed to each other with an electron beam passage interposed therebetween, wherein the first deflecting body is the same as the first spiral conductor and the first spiral conductor. A first ground conductor extending in a direction and disposed inside the first spiral conductor, wherein the second deflector has a second spiral conductor and the second spiral. A traveling wave type deflection device comprising: a second conductor extending in the same direction as the linear conductor and arranged inside the second spiral conductor; Is composed of a plate-like body facing the first and second spiral conductors,
The width of the portion of the ground conductor facing the one end and the other end of the first and second spiral conductors is narrower than the width of the portion facing the center of the first and second spiral conductors. The
A traveling wave type deflection device, wherein the first and second spiral conductors have substantially the same characteristic impedance over the entire length.