DE1766924C2 - Circuit for high voltage generation for television receivers - Google Patents

Description

M] / L (C + C ₀ )

25th

where L _{e is} the equivalent resonance inductance according to the equivalent circuit, C _{e is} the equivalent resonance capacitance and Q is the capacitance between the drive electrodes (3, 4) of the piezoelectric transformer oscillating at the fourth harmonic of the return pulse frequency, where (C + Co) is large in comparison to Cb and the frequency characteristic (21) of the drive voltage applied to the drive electrodes via the series resonance circuit shows a minimum (28) at the resonance frequency and a maximum (26,27) on each side next to the minimum.

40

The invention relates to a circuit for generating high voltage for television receivers a piezoelectric transformer having two drive electrodes and an output electrode <n and a drive signal source connected to the drive electrodes via a choke, the inductance the choke the capacitive part of the existing at the input of the piezoelectric transformer Impedance compensated by resonance formation. w

A television receiver requires high voltage to light up the cathode ray tube. Known television receivers use a flyback transformer as a high voltage generator, which as Winding transformer is constructed. Isolation problems arise with this r>. In addition, the Flyback transformer has a complicated structure and is relatively large.

As a high voltage generator for cathode ray tubes, the use of winding bo loose piezoelectric transformers known ("Solid State Magnetic and Dielectric Devices" London 1959, pp. 170 to 197). The two driving electrodes and one The piezoelectric transformer having the output electrode is connected to the h "> Drive signal source connected. The inductance of the choke is chosen so that it is through the Capacitance formed between the drive electrodes capacitive component of the input impedance of the piezoelectric Transformer compensated by resonance formation. The resonance formation results in further an increased voltage increase. However, the known piezoelectric transformer is for the practical operation as a high voltage generator for television receivers is not yet suitable: the load resistance changes in television receivers because its resistance value depends on the brightness of the picture and the size of the beam current is dependent cannot be kept constant over a wide range of the resistance value. Next will be with one Television receiver, the pulses supplied by the drive signal source do not have a constant frequency under all circumstances be. The frequency dependency of the output voltage is very pronounced, so that already at relatively small deviation from the resonance frequency of the piezoelectric transformer, the output voltage can decrease so much that a grid no longer appears on the screen

The frequency characteristic also has strongly pronounced maxima, as does the temperature characteristic the transformer output voltage is not horizontal. All that leaves the piezoelectric transformer little for practical use as a high-voltage generator for television receivers appear suitable.

The object of the invention is therefore to provide a high-voltage generator for television receivers to create usable piezoelectric transformer that is as spread as possible Frequency characteristic and horizontal temperature characteristic are independent of the resistance value of the load Has constant output voltage Starting from a circuit for high voltage generation according to the im This object is achieved according to the invention solved by the features mentioned in the characterizing part of the claim.

One recognizes first that here as a driving signal source the horizontal output circuit of the television receiver is used. The high voltage generator is therefore at Horizontal return pulse frequency operated. The horizontal output circuit supplies pulses with the Return pulse frequency of 15.84 kHz with a harmonic component. That's cheap because it's a piezoelectric Transformer with practical dimensions easiest at the frequency of the fourth higher harmonic of the flyback pulse frequency can be operated. On the other hand, there is a difficulty in that the frequency of the flyback pulses occasionally deviates from its normal value differs and also the resonance frequency of the piezoelectric transformer, for example temperature-dependent is changeable. With a frequency adjustment within a narrow range of, for example, up to 350 Hz functional bandwidth Therefore, the output voltage of the high voltage generator can drop so much that on The screen of the television receiver no longer appears. It is therefore also a capacitor connected between the drive electrodes, which together with the one on the piezoelectric transformer between the drive electrodes existing capacitance the capacitive portion of the input of the piezoelectric Transformers existing impedance forms. This becomes quite large compared to the capacity chosen between the drive electrodes. Which emerges from the

Parallel connection of the capacitance of the additional capacitor to the capacitance between the drive electrodes resulting total capacitance and the inductance of the between the horizontal output circuit and a The choke connected to the drive electrodes must meet the resonance conditions. The circuit is like this dimensioned that the frequency characteristic of the Series resonant circuit made up of a choke and additional capacitance for the drive voltage applied to the drive electrodes has a minimum at the resonance frequency and a maximum on either side of the minimum This frequency characteristic works together with the frequency characteristic showing a maximum at the resonance frequency of the piezoelectric transformer, so that the overall frequency dependence of the Output voltage of the high voltage generator a certain compensation with respect to the peaks of the frequency characteristics in the direction of a flattening of the characteristic curve, as well as a broadening of the Frequency band in which there is still an output voltage sufficient for raster generation on the screen Is available to more than double. This effect is further enhanced by the activation of the counter-inductively with the choke of the series resonant circuit reinforced choke coil, which the The frequency characteristic curve is designed to be even more favorable. Such a spread frequency characteristic curve results in a greater operational reliability for the television receiver. In addition, there is also less dependency the output voltage from the temperature and the resistance value of the load are observed. With the appropriate Accordingly, the circuit is designed to meet the needs of the application in television receivers well adapted.

An exemplary embodiment of the invention is illustrated with reference to FIGS. 1 to 10 explained. It shows

F i g. 1 shows a circuit for generating high voltage for television receivers using a piezoelectric Transformer,

F i g. 2 in the circuit of FIG. 1 occurring pulse shapes,

3 shows a graph of the relationship between output voltage and load for the in F i g. 1 circuit shown,

4 shows an equivalent circuit to explain the essential part of the circuit of FIG. 1,

Fig. 5 is a graphical representation of the relationship between load resistance and effective resonance input resistance of the piezoelectric transformer,

Fig. 6 is a graph showing the relationship between the load resistance and the drive voltage generated by the series resonance circuit,

F i g. 7 a graphical representation of the relationship between flyback pulse frequency and output voltage, Drive voltage and output current of the circuit of Fig. 1,

F i g. 8a and 8b show the resonance waveforms of the piezoelectric transformer,

F i g. 9 temperature characteristics of the in F i g. 1 shown circuit and

Fig. 10 is a graph showing the relationship between flyback pulse frequency and output voltage of the piezoelectric transformer.

Fig. 1 shows a circuit diagram of a device for High voltage generation for television receivers. A piezoelectric element 1 consists of a piezoelectric Ceramic materials, e.g. B. barium titanate.

PZT ceramic (a _{ceramic material consisting essentially of PbTiO 3} and PbZrO ₃ ) or PCM ceramic [a ceramic material consisting essentially of Pb (MgIz ₃ NbZz ₃ ) O ₃ , PbTiO ₃ and PbZrO ₃ ]. The driving section 2 of the element 1 is provided with electrodes 3 and 4 on the opposite sides and polarized in the direction of its thickness. A generator section 6 of the element 1 is provided with an electrode 7 on its end face and is in

ίο Polarized lengthways Electrodes 3 and 4 of the Driving section 2 are connected to the horizontal output circuit 5 of the television receiver. The electrode 7 of the generator section 6 is via rectifier diodes 8 with any ohmic load symbolizing load resistor 10 and a smoothing capacitor 9 connected.

The following is the work described above Device explained in more detail The electrical energy of return pulses 11 (Fig.2), which from Horizontal output circuit 5 given to electrodes 3 and 4 is made by the electrostrictive Effect converted into mechanical energy, so that the whole body of the piezoelectric element 1 mechanically vibrated along the element 1 is such a

2 ^r j generates resonance vibration with a frequency that depends on the length of the element and the self-propagation speed of the vibration in the material, as a result of which a standing wave of large amplitudes is built up by stress strains. The voltage load on the generator section 6 of the element 1, which is increased in this way, generates a sufficient potential difference between the electrode 7 and the earth due to the piezoelectric effect. According to such a principle, a considerably stepped-up alternating

Γ) get voltage. This alternating voltage is through the rectifier diode 8 rectified and the capacitor 9 smoothed, and a high DC voltage is applied to the load resistor 10 in this way. The features of the circuit explained up to this point are known. at Problems occurring in a circuit with only these features are described below with reference to the drawings explained in more detail.

3 shows a characteristic curve 15 which shows the ratio between the output DC voltage and the load

4> indicates resistance in the device shown in FIG. 1, for example. The ordinate indicates the value of the output DC voltage applied to the load resistor 10, while the abscissa indicates the electrical resistance value Rl of the load resistor 10.

in This load resistance 10 is the electrical resistance between the anode and cathode of a cathode ray tube in a television receiver. The value of this Resistance changes according to the brightness of the image or the size of the beam current across one

τ; Range from 50 ΜΩ to an infinitely high value. With such a change in the load resistance, the output voltage changes across a Range from 10 to 3.6 kV, which corresponds to about 36% of the maximum value of the output voltage and

M) causes a corresponding change in the width of the picture frame.

F i g. Fig. 7 shows a curve 20 showing the frequency characteristic of the output voltage of a known device designated. In this figure, the ordinate denotes the

bi DC output voltage Ea at Lastwide.iland 10, while the abscissa represents the frequency of the return pulses. It is assumed that the resistance value Ri of the load twisting force in pin fpopr

Value of 68 ΜΩ. As the illustration shows, the available frequency band is very narrow, with the 50% The frequency below the maximum value is approximately in the range of 350 Hz. If the Resonance frequency of the piezoelectric transformer due to a temperature rise or If the characteristics change gradually, the output voltage drops considerably. if Furthermore, the frequency of the flyback pulses deviates from its normal value, there is no high voltage and the grid does not appear on the screen.

F i g. 9 also shows a curve 36 which is a temperature characteristic of the output voltage. In the illustration, the ordinate indicates the output DC voltage Ea at the load resistor 10, while the abscissa indicates the ambient temperature. From the figure it can be seen that the output voltage drops by 40% when the ambient temperature varies from 25 to 6O ⁰ C. This effect of the temperature 2 «cannot be prevented in the existing piezoelectric ceramic materials, since it is a consequence of the temperature dependence of the mechanical Q, ie of the Qm of the piezoelectric material.

Fig. 1 shows an additional one with a choke 12 between the output terminal of the horizontal output circuit 5 and the electrode 3 and in particular a capacitor 13 between the two electrodes 3 and 4 provided embodiment with which the above-mentioned three main disadvantages of known devices. The aim is to fix the load characteristics, the frequency characteristics and the temperature characteristics of the piezoelectric transformer can be improved.

With a modified structure, the r> Load characteristics of the output voltage improved considerably, with the change in the output voltage is only 10% when the load resistance value is as shown in FIG. 3 can be taken from characteristic curve 16, from changed an infinitely high value to 50 ΜΩ.

The frequency characteristics of the output voltage are also greatly improved, as shown by curve 22 in Fig. 7, since the frequency band corresponding to a 50% drop in the output voltage is 850 Hz. At the same time the output voltage is 4; voltage itself greatly increased.

Furthermore, the temperature characteristics of the output voltage can be greatly improved, inasmuch as the waste of the output at 6O ⁰ C is only 14%, such as curve g in F i 37th 9 shows

The reasons for such remarkable effects caused by the above-mentioned structure of the circuit are explained in detail below. First, the effects on the load characteristics are examined. The in F i g. 1 can be used for the resonance frequency in the equivalent circuit in FIG. 4 are redrawn, in which L is the inductance of the choke 12 and C is the static capacitance of the capacitor 13. G> is the static capacitance between the two electrodes 3 and 4 of the to piezoelectric element 1, and L _ft C _e and R _c are each the equivalents of resonant inductance, capacitance and resistance. Although the drive voltage for the circuit of FIG. 1 consisted of return pulses 11, for the sake of simplicity it is assumed that t> 5 in the equivalent circuit of _{FIG. 4 a sinusoidal voltage E 1 is applied} as a drive signal. The voltage applied to electrodes 3 and 4 is denoted by Ε. For this voltage E, the following formula applies:

IwL +

jwL Z

jwC + j-

E, - W ² LC + I

where Z = JwL _1. +. - + R ,. JwC ₁ .

C = C + C _n .

The values of C 'and L are to be chosen so that they meet the following condition:

₌ ".Ι, = \ I \ CL = l / 1'L..C, ..

Then the voltage E ₁ at an angular frequency ηί is given as follows:

E ₁ = - * - f = -j

/ HO L

Thus the voltage E, is proportional to E ₅ , C, w and R ₁ ..

On the other hand, with the characteristics it is a; piezoelectric transformer known that, other; than with ordinary transformers, R _c increases as Rl decreases. An example of this characteristic is shown in FIG. 5 is represented by curve 17.

Therefore, from the above formula (4) and ir F i g. 5 shows that the voltage E, magnitude: becomes when Rl decreases. F i g. 6 shows examples of this relation, neglecting the internal resistance of the current source, namely the curve If shows the relation of E / E _s to load resistance Rl when C is 12,000 pF (ie C ₀ = 2000 pF and C = 10,000 pF). As curve 18 shows, E / E _s increases when the load resistance Rl becomes smaller, the quotient being 1.6 for an infinite value of Rl , while it is 3.7 when Rl is 50Ω. This ratio is used to compensate for the load characteristic of the piezoelectric! Elements itself, according to which the output also becomes smaller when Rl decreases, such as curve 15 in FIG. 3 shows. As a result of the combination of two characteristic curves running in opposite directions, a satisfactory load characteristic curve is obtained, as shown by curve 16 in FIG. From curve 19 in FIG. 6, which shows this relationship when C = Cö = 2000 pF, that is, when no capacitor is connected across the piezoelectric element (C = O), it can be seen that the drive voltage E i is too small to generate a sufficient output voltage. In order to obtain a sufficient output voltage, C must be quite large compared to Co.

Next, the effects of the circuit in improving the frequency characteristics are discussed. F i g. 7 is a graph explaining this improvement. 7 has curve 20 that a relation between the DC output voltage and the flyback pulse frequency in the case of F i g. 1 shows essentially two resonance peaks 24 and 25. The

Resonance peak / e 24 results from the A / 2 resonance (a type of resonance in which half a wavelength of the standing wave extends the full length of the element), as shown in Fig. 8a. The best length of the Element is the one that has an A-mode resonance on the harmonic four levels higher allows, whereby the following conditions are met:

1. No audible vibration noise,

2. a sufficient outcome,

3. no breakdown of the insulation in the voltage generating section,

4. small dimensions and

5. No overheating of the piezoelectric element.

The resonance peak 25 is caused by the λ-type resonance shown in FIG. 8b. The return pulse frequencies, which cause the λ / 2 and λ resonances agree with each other if the following conditions are met:

1. The speed of propagation of vibration is in all parts of the piezoelectric element same.

2. The speed of propagation does not change with frequency.

3. The mechanical characteristic impedances in the drive section and in the generator section of the Elements match exactly.

However, since these conditions cannot be met in general, curve 20 shows how shown, two resonance peaks 24 and 25. That is why it must be decided which of the two types of vibration to be used to generate the high voltage. You will find that the Α-type is made up of is preferable for the following reasons:

1. The load characteristics of the output voltage are better.

2. The throttle 12 can be made smaller.

3. The node of the stress lies on the boundary between the driving section and the generator section. (The strength of the element is relatively low in the vicinity of the limit, because of the directions of polarization cross at this point.)

Explanation follows by taking an example in which the piezoelectric element is such that it oscillates in Α-resonance with the fourth harmonic of the flyback pulse frequency.

Assuming that the curve 20 in FIG. 7 designated return pulse frequency, which is in the A-type oscillates, is 15.84 kHz, then the A resonance frequency is 15.84 kHz x 4, that is 63.36 kHz.

If now the values of C 'and L are chosen so that the following condition is met [s. Formula (3)]:

63.36 10 ³ =

then the voltage applied to the two electrodes 3 and 4 of the drive section is derived from a considerable part of components other than the fourth harmonic of the pulse frequency, and it becomes a nearly sinusoidal voltage with a frequency four times the return pulse frequency, such as curve 14 in F. i g. In this case, the frequency characteristic 2 of the output voltage has a minimum 28 in the vicinity of the A resonance pulse frequency and a maximum 26 and 27, respectively, on either side of the minimum 28. The existence of such a characteristic can easily be ascertained by checking the relation between E, and win formula (1) can be proven.
Superimposing curve 21 with curve 20 accordingly results in a sufficiently flat frequency characteristic, as shown by curve 22, as occurs in a broadband resonance amplifier.
Now the output achieved by the circuit should

H) same effect on the temperature characteristics of F i g. 9 will be explained. With the existing ceramic materials, the mechanical Q or Q _n , changes with the temperature. Q _n , decreases as the temperature increases. Since the step-up ratio of a piezoelectric transformer is proportional to Qm , the output voltage drops as the temperature rises, as shown by curve 36 in FIG. It is a known fact that a decrease in Q _n occurring in the equivalent circuit of FIG

: o contained resistance R _c increases. On the other hand, increasing the resistance value /? _{c increases} the voltage E, which is applied between the drive electrodes. In this way, the temperature characteristic can be improved considerably, such as curve 37 in FIG. 9 shows, wherein the reduction in the step-up ratio of the piezoelectric transformer is compensated for by the increase in the voltage to be applied between the drive electrodes.

Curve 23 in FIG. 7 showing the frequency characteristic of the DC output voltage for the infinitely high Load resistor 10 (FIG. 1), has a steep peak 29. The presence of such pronounced tip is very dangerous and annoying in practice, as the insulation punctures or that

υ the piezoelectric element can be mechanically damaged can if the frequency of the return pulse deviates from the normal frequency. Such a tip occurs when the λ / 2 resonance of the element with the second harmonic of the flyback pulse frequency has not been switched off by the choke 12 and the capacitor 13. So it is above all important to remove such a spike by eliminating the A / 2 resonance by some means or is suppressed.

In Figures 8a and 8b, lines 30 and 31 show the distribution of displacement and stress, respectively for the λ / 2 oscillation, the lines 32 and 33 the same for the Α oscillation and the lines 34 and 35 the position of the node in the distribution of the shift in the Α-resonance, with these points approximately at a Quarter or three quarters of the length of the element. By firmly pressing the element together on the mentioned point of the node, the oscillation of the A / 2 type is considerably suppressed, as Fig. 8a shows, while the Α-type vibration is hardly suppressed.

F i g. 10 shows to explain the above Suppression effect a characteristic curve 39, which corresponds to the curve 20 in FIG. 7, which, however, represents the case in

t> 0 denotes the element at the node of the A resonance oscillation is pressed firmly. As the characteristic curve 39 shows, the resonance peak caused by the λ / 2 oscillation is 24 has completely disappeared and there is only one resonance peak 25 '. Turn 40 is the one Frequency characteristic of the DC output voltage when the load resistance value is 68 ΜΩ, and the curve 41 is the same characteristic when the load resistance value is extremely high. In both cases, it can be seen that

the curves do not have a maximum 27 as in FIG. 7 have.

Another method of eliminating the steep tip 29 in the method shown in FIG. 7 there is curve 23 therein, the return pulse resonance frequency of the Λ / 2 type as far as possible from the return pulse resonance frequency of the λ-type.

This results in a frequency characteristic as shown as curve 41 in FIG. 10 appears.

F i g. 1 shows the circuit of the circuit in which a mutual inductance between the choke 12 and a choke coil 43 is provided through which direct current is conducted to the horizontal output circuit 5

10

will. Here, the choke 12 and the choke coil 43 can form a unit, and furthermore, by appropriately calculating the mutual inductance, a flatter curve of the frequency characteristic of the output can be obtained. In addition, the frequency line 2V of the input direct current flowing through the choke coil 43 becomes almost identical to the characteristic line 21 of the driving voltage as shown in FIG. 7 shows provided that the ordinate has a different scale. This allows the peaks 26 'and 27' in the curve to be reduced.

In addition 5 Iilatt drawings

Claims (1)

Claim: Circuit for high voltage generation for television receivers with two driving electrodes. and a piezoelectric transformer having an output electrode and a drive signal source connected to the drive electrodes via a choke, the inductance of the choke compensating for the capacitive component of the impedance present at the input of the piezoelectric transformer by forming resonance, characterized in that the drive signal source is the horizontal output circuit (5) of the television receiver is, a choke coil (43) connected between the horizontal output circuit and a direct current source is at the same time mutually inductively connected to the choke (12), and the inductance L of the choke connected between the output terminal of the horizontal output circuit and one (3) of the drive electrodes (3, 4) ( 12) and the capacitance C of a capacitor (13) connected between the two drive electrodes (3, 4) meet the condition