DE2256006C3 - High voltage transformer arrangement for horizontal deflection circuit - Google Patents

Description

between the low-voltage side winding of the high-voltage coil and the low-voltage coil. The difficulties mentioned above are thus eliminated.

Further details can be found in the following Description on the basis of the drawings. In it shows

F i g. 1 an electrical circuit diagram of a basic form a horizontal output circuit with a flyback transformer arrangement according to the invention,

F i g. 2 is a schematic sectional view for illustration the structure of an embodiment of the flyback transformer arrangement according to the invention,

F i g. 3 and 4 are schematic representations to illustrate the structural difference between the flyback transformer arrangement according to the invention and a device of the same type known from the prior art,

F i g. 5 is a graph showing the between the high voltage output and the load current at the return transformer arrangement according to the invention and relationships existing in the known flyback transformer arrangement,

F i g. 6 is a schematic sectional view showing the structure of another embodiment the invention,

F i g. 7 a and 7 b are schematic representations of two different intrusion modes in the Embodiment of FIG. 6 provided focusing diode,

F i g. Figure 8 is a graph showing better tracking of the flyback transformer assembly the F i g. 6 obtained focusing voltage compared to the corresponding characteristic of a known flyback transformer arrangement this kind,

F i g. 9 is a schematic sectional view for illustration the structure of a further embodiment of the invention, with individual parts in a block diagram are reproduced

F i g. 10a and 10b, partly in section, elevations of two different shapes, one in another embodiment the high-voltage coil part used in the invention,

F i g. Π a schematic sectional view of a further coil arrangement which, instead of the one shown in FIG. 10a and 10b can be used,

F i g. 12 is a schematic representation of the circuit connection in yet another embodiment the invention,

F i g. 13 is a schematic sectional view showing the structure of the embodiment of FIG. 12th and

F i g. 14 is a graphical representation of the flyback transformer arrangement of FIG. 12 existing Relationships between the focus voltage and the load current.

Let us first refer to FIG. Referring to Fig. 1, one basic form of horizontal output circuit is shown, this circuit having a horizontal output transistor 1, a damping diode 2, a deflection yoke coil 3, capacitors 4 and 5 and a flyback transformer arrangement connected to a picture tube 7 8 includes. The flyback transformer arrangement 8 comprises a high-voltage rectifier diode 9 and a flyback transformer 10. der from a core 13, a low voltage coil 11 and a high voltage coil 12. A terminal 6 of the low voltage coil 11 is connected to a direct current source connected.

Although in FIG. 1 shows an example of a circuit arrangement for deriving the horizontal deflection output and a high voltage output from the The same transistor is shown, but needless to say that instead of the circuit arrangement of the Figure], a different circuit structure is also provided can be, in which the deflection output from a

ίο derived from another transistor.

In Fig. 2 is the structure of an embodiment of the in FIG. 1 shown flyback transformer 10 shown. In the arrangement of FIGS. 2 is the low voltage coil 11 or the primary coil of the return flow

transformer 10 wound on a bobbin 15, carried by the leg of the core 13 will. The high voltage coil 12 or the secondary coil of the flyback transformer 10 is on a Coil bobbin 14 wound around the bobbin 15

spanned in a coaxial arrangement. The high-voltage coil 12 consists of a plurality of windings 12 <7, 12b to 12wj and 12w, which are connected in series. In the case of the in FIG. 2, the windings near the winding 12a represent the low-voltage side windings of the high-voltage coil 12 and the windings near the winding 12/1 represent the high-voltage side windings of the high-voltage coil 12. The core 13 consists of two parts that meet at a joint 16. Thieves-

Train number 17 denotes the grounded or first end of the High voltage coil 12.

An important feature of the invention lies in the fact that the low voltage coil 11 near the high-voltage side windings of the high-voltage

voltage coil 12 is arranged, as shown in FIG. 2 shows. This arrangement differs fundamentally from the arrangement generally provided in known flyback transformers.
Aut the operating characteristics of the flyback transformer arrangement according to the invention, which therefore has this structural difference, should be based on FIG. 3 and 4 will be discussed in more detail. In Fig. 3 shows the structure of the flyback transformer arrangement according to the invention in a schematic form, while FIG. 4 is a schematic representation of the structure of a known flyback transformer arrangement in which a coil arrangement such as that described above is provided. In the known flyback transformer arrangement, a high-voltage coil with a low-voltage side winding 18e and a high-voltage side winding 18/7 is magnetically coupled to a low-voltage coil 19 in the manner shown in FIG. 4 is shown. In Fig. 3 and 4, the main magnetic flux 20 is indicated by dashed lines, while the leakage flux is indicated by a dash-dotted line. In both flyback transformer arrangements, the low-voltage coil as well as the high-voltage coil are completely penetrated by the main magnetic fiow20. However, in the case of FIG. 4 the low-voltage side windings of the high-voltage coil in the case of FIG. 3, however, the high-voltage side windings

gene of the high-voltage coil, albeit the contribution of the leakage flux 21 compared to the magneüschen Main river 20 is only very small.

The solid curve in FIG. 5 gives the change in high voltage output versus high voltage load current or high voltage regulation in the invention. ^; en flyback transformer arrangement again, while the dashed curve denotes the high voltage regulation in the known flyback transformer arrangement. From Fig. 5 clearly shows that the undesirable fluctuations in the high voltage output in the flyback transformer arrangement according to the invention are markedly reduced in comparison with the known flyback transformer arrangement.

F i g. Figure 6 shows another embodiment of the invention incorporating a focusing power source. When arranging the F 1 g. 6 ibt a focusing coil 22 wound on a rinen bobbin 23, which is on the Legs of a core 13 mounted in one position is in which the degree of magnetic coupling between this coil and a low voltage coil 11 is less than that between a high voltage coil 12 and the low voltage coil 11. The Focusing coil 22 can be connected to the high voltage coil 12 and to a focusing diode 24 in such a manner be conductively connected, as shown in FIG. 7a and 7b, respectively. In the case of FIG. 7 a is the first end of the High-voltage coil 12 is grounded in terms of alternating current via a capacitor 25, this being at the same time serves to smooth the focus voltage that is above the Focus coil 22 appears. The one shown in Fig. 7b λ "T-dimension is the same as that of an arrangement at the one focusing power source from a middle one Point of the high-voltage coil 12 is tapped. The tracking of the with the in F i g. 6 flyback transformer arrangement shown The focus voltage obtained is shown in FIG. 8 reproduced and for comparison with that of a known flyback transformer arrangement contrasted with this type. In Fig. 8 denote the solid line, the dash-dotted line Line and the dashed line in the arrangements of FIG. 7a and 7b or in the known one Device tracking to be achieved. The hatched area bounded by thin, solid lines indicates the focus voltage range required to obtain a good image. the The term "second end" of the high-voltage coil in this context refers to that connection denote connected end at which positive return pulses appear when the other or the first The end of the high voltage coil is grounded. It should be noted that the term "second end" is not about is to be understood in such a way that this would simply be understood as the end that is opposite to the end of the coil at which the winding process is initiated.

Some of the methods described below are for increasing the dielectric strength of the present invention Flyback transformer arrangement very effective, especially for increasing dielectric strength between the high-voltage side windings of the high-voltage coil and the low-voltage coil.

In one of the preferred methods for this purpose, a flyback transformer 10 such as that in FIG. 6 shown installed together with a high-voltage rectifier diode 9 in a housing 26, and in the interior of the housing 26 becomes a certain Amount of insulating oil filled in as shown in FIG. 9 shown is. By filling the insulating oil into the housing26, the dielectric constant of the interior can be adjusted, such as it is given before the insulating oil is filled in, and the stray capacitance of the high-voltage coil can increase accordingly, which causes considerable fluctuations in the operating characteristics of the flyback transformer arrangement be evoked. But it has been shown that the high voltage regulation and tracking of the Focusing voltage are completely free from fluctuations when the working characteristics of the flyback transformer arrangement is appropriately regulated in the state of lin immersion in the insulating oil. Out Fig. 9 it can be seen that the flyback transformer 10 and the high-voltage rectifier diode 9 are accommodated in the housing 26, the interior of which is filled with the isüueröl 29, the high-voltage output, the focus output and the other output and input at a high voltage output connector 27, a focus voltage output connector. 1 28 as well as a low voltage output or input connection 30 are removed or fed.

According to a second method, a stepped bobbin 31 serves as the one in FIG. 10a shown or cm tapered bobbin like that of FIG. 10b for mounting the high-voltage coil in the form of a step winding, in order to increase the insulation distance between the high-voltage side windings of the high-voltage coil and the low-voltage coil and to reduce the stray capacitance of the high-voltage coil. In [-all for example a W'abenwic ¹ --lung can Based on the same reasoning, an arrangement w ie the F i g. 11 are created, in which the high-voltage coil 12 is carried by a bobbin 33, which has the shape shown. The same idea can also be applied to a step winding.

A method for influencing the tracking of the focusing voltage even more precisely is to be found on the basis of the F i g. 12, which is a Schematic representation of a preferred arrangement of the elements in yet another embodiment of the invention, and on the basis of F i g. 13, a schematic sectional view for explanation the structure of the in F 1 g. 12 embodiment shown. In the arrangement of FIGS. 12 and 13 is a low voltage coil 11 in a main winding 34 and an auxiliary winding 35, which are connected in series, the main unc the auxiliary windings 34 and 35 of the low-voltage coil 11 with the high-voltage side winders a high-voltage coil 12 or with a focusing coil 22 are magnetically closely coupled.

This arrangement is advantageous in that the focus coil 22 is affected by the magnetic flux fluctuation the low voltage coil 11 is easier to control than when it is magnetically less close to the Niedei span voltage coil 11 would be coupled, and because the changes in the focus voltage relative to the changer the high voltage load current can be reduced. This mode of operation is graphically shown in FIG. 1-illustrates in which the solid line shows the changes in the focus voltage in the case of a difference Development of the low-voltage coil into a main and auxiliary winding and the dashed line dii appropriate changes in the event that the Nie

The voltage coil is not divided into these windings is.

The flyback transformer arrangement according to the invention offers the following advantages:

1. The flyback transformer assembly produces a high voltage output that is far less Dimensions subject to changes in tension.

The following is assumed that the internal impedance Zt represents the changes in the Hoehspannungsausgangs Rücklauflransformatoranordnung. This internal impedance Z results in

Zi- (high voltage output in kiloxolts if /// 7 · 0) - (high voltage output in kilosoll
if /; / v A milliamps) / A megohms,

where Im denotes the high voltage lasing current. The value of the internal impedance Z is kept within the scope of the invention at 1.2 to 2.5 megohms, while the value of Z in known flyback transformer arrangements is generally 3 to 3.5 megohms. It is thus clear that the changes in the high voltage output can be achieved considerably within the scope of the invention.

It is also common practice to include an element such as a saturable reactor in series To lay a DC circuit that "supplies the horizontal output circuit in a television receiver, to control the DC supply voltage and thereby stabilize the high voltage output. But the effective internal impedance can only be reduced to about 1.5 to 2.5 megohms, even using the mil-ic method. In contrast, the effective internal impedance can be further reduced within the scope of the reduction, without the need for such a slave circuit, and if such a circuit with the one according to the invention Arrangement should be combined, ii.:Bc the effective! Nncnimpedanz even further ■■ reduce, namely down to about 0.7 to 1.7 megohms.

To reduce the internal impedance of flyback transformer assemblies a so-called fifth harmonic tuning system is usually provided, as is the case, for example, from the USA patent 3 500 116 is known. so a system in which one A fifth harmonic is superimposed on the fundamental. The invention is intended to be comparative in the following a flyback transformer arrangement operating according to such a system can be compared.

In the flyback transformer arrangement operating according to the fifth harmonic tuning system, the ratio of the voltage E // r < _{5 ) appearing across the high-voltage coil to the voltage Ec <5)} appearing across the low-voltage coil is given by the equation

₎ : NUs)

where Νημ denotes the number of turns of the high-voltage coil, Nn ₅ ) the number of turns of the low-voltage coil, and further where λ, · 0. It is therefore difficult to obtain a sufficiently high output voltage. In the context of the invention, the ratio of the voltage EnT appearing across the high-voltage coil to the voltage Ev appearing across the low- voltage coil is through

EurlEc - (1:%) (Nu ₁ Ni.)

express, in which Nu denotes the number of turns of the high voltage coil and N /. the number of turns of the low-voltage coil, while \ n: 0. A sufficiently high output voltage can thus be achieved without further ado, although the frequency can still be sufficiently reduced.

Also is the operational efficiency of a reverse transformer arrangement bad, in which the fifth c-harmonic tuning system is provided,

ίο «because a higher input power is required for the same load than if such a system were not provided. Such a problem can arise in the context of the implementation
The flyback transformer arrangement according to the invention is able to deliver a focusing voltage of satisfactory tracking / ii.

In a known from the prior art horizontal output circuit with a transistor as The active element was a particularly high winding ratio between the low voltage coil and the high voltage coil of the reverse transformer necessary. Will a 1 focus on a medium Place the high voltage coil of the flyback transformer tapped, so is the tracking

J5 the l'okussicr tension very unsatisfactory, as out F i p. H can be seen, and such an I okussicrleistungsquellc was practically unusable Hey The procedure for supplying the focusing voltage is therefore usually such that the high output voltage of the flyback transformer was divided by an opposing land. Yet this system is under among other things, afflicted with a deficiency, as the tension-unestciling resistor has a very high resistance value and must be sufficiently isolated.

whereby the circuit structure becomes quite complicated. These deficiencies are eliminated by the invention, and a focus voltage of satisfactory tracking is obtained.

Also, a system employing a Cockcroft circuit to rectify and boost the high voltage output of the flyback transformer has generally adopted the method of applying the focus voltage from the cathode of the diode in the first stage. However, it has been confirmed by experiments that the track reverberation that can be achieved within the scope of the invention is far better than with such a system. In the case of the Cockcroft system, in which the rectifier, for example, has three stages in the form of a? so-called doublets are arranged, the high output voltage E _{0 of} the system is through in the unloaded state

E ₀ - 2 E;, 'T ₀ + E'

given, where Eut ₀ the output voltage de ¹ flyback transformer in the unloaded state unc E'nTo draw the harmonic voltage of the output de flyback transformer in the unloaded state bc. The focusing _{voltage EV 0} in the unblocked state is through

given. In contrast, the high-voltage output E of the S \ Mcm and the focusing voltage E ₁ in the loaded state are through

E 2 E

"R

I. α τ

where Ein · the output voltage of the reverse E'htq E'ht

running transformer in load / .stand and i "; / rdie," "" "<

t'Jher oscillation voltage of the output of the return " ^T ° ^F -" ^T

transformers in the load country.

However, because 5 he _e ibt for the ratio EIE ₁ to E _{0 0} JEF

l (2Eiir- E'iit) Eht \ _ (2 · E'htIEiit

2 f E'iiT ₀ IEuT ₀

The tracking of the focus voltage is best when the above ratio is equal to 1 The ob However, the ratio tends to deviate greatly from 1, which results in poor tracking.

For this purpose 4 sheets of drawings

Claims (8)

Claim 3, characterized in that the patent claims low-voltage coil (11) is in a main winding. and an auxiliary winding (35) is divided with the high-voltage side winding of the 1. In a horizontal deflection circuit provided 5 high-voltage coil (12) or with the Fokushene high-voltage transformer arrangement, the sierspule (22) are magnetically closely coupled,
a low voltage coil, a core, a high voltage coil with a high voltage side Winding and a low-voltage side winding development as well as a high voltage rectifier one io
comprehends, characterized by a
tighter magnetic coupling between the high-voltage side winding of the high voltage The invention relates to a formatoranordnung as talablenkschaltung provided high voltage Trans between the low voltage side winding _l5 in a horizontal coil (12) and the low-voltage coil (II), the low voltage coil of the high voltage coil (12) and the low - A core, a high-voltage coil with a high-voltage coil (11). voltage-side winding and a low-voltage 2. High-voltage transformer arrangement according to the voltage-side winding and a high-voltage claim 1, characterized in that the rectifier engages. Relation between the ratio Ej _{/ T} 'Ec of ao Conventional high-voltage transformers are built up in the high-voltage coil (12) induced voltage in such a way that the low-voltage side windings have a value of £ 7 / r to that in the low-voltage source (11) of a high-voltage coil in the vicinity of a low-induced voltage E _c and the ratio of the potential part or a low-voltage coil are assigned to the number of turns Nh of the high-voltage, while the winding coil (12) on the high-voltage side is assigned to the number of turns Nl of the low-voltage coil in a sufficient coil (11) by Eht \ E _q = - (1 -γ λ) (NhJNl) the isolation distance from the low voltage coil is given, where «> 0. are ordered to avoid an abrupt potential gradient between 3. High-voltage transformer arrangement according to see these coils and avoid the electrical claim 1, characterized in that additional insulation of the high-voltage parts ensure, a focusing coil (22) loaned and the 30 In such a known arrangement, there is a magnetic coupling between this and therefore the Leakage flux between the high-voltage coil is less tight than the low-voltage coil and the low-voltage coil due to the low-voltage magnetic coupling between the high-voltage coil and then traverses the low-voltage side winding of the high-voltage coil side windings of the high-voltage coil near the (12) and the low-voltage coil (11). ₃₅ low voltage coil. As a result, the in 4. High-voltage transformer arrangement after the high-voltage coil induced voltage to claim 3, characterized in that the different points between the first, earthed, one end of the coil that is at ground potential and the second end of the coil with the load Copy the end of the high-voltage coil (12) with the connected end of the coil with strong voltage fluctuations Focusing coil (22) via a rectifier 40 kungen: The induced voltage is in the high element (24) and with the windings on the voltage side at ground potential near the second end the part connected via a capacitive element (25) higher and in the low-voltage side windings that is. near the first end lower, which can be attributed to 5. High voltage transformer assembly after is that of the low voltage coil Claim 1, characterized in that the stray flux extending in the manner described above Low-voltage coil (11), the core (13), which is the low-voltage side windings of the high-high-voltage coil (12) and the high voltage coil crossed. This leads to occurrence rectifier (9) in a housing (26) recorded a higher potential on the high-voltage side are, with the remaining parts of the interior of the windings and is therefore in terms of the insulating housing (26) are filled with insulating oil. 50 tion undesirable. 6. High-voltage transformer arrangement according to Also is the form of fluctuation in the high-voltage claim 1 or 5, characterized in that the output is related to the high-voltage load current the high-voltage coil (12) either according to the or the high-voltage regulation also unbe method the stair winding, the honeycomb winding, caused, for example, by an unlung, the step winding or some other increase in stray capacitance that is desired, and the highly suitable winding method is wound. Voltage output increases with an increase in 7. High-voltage transformer assembly abruptly after high-voltage load current. Claim 1 or 6, characterized in that the invention has for its object a return transein to create a stepped bobbin (31) or a tapered formator assembly when in operation Coil bobbins (32) are provided which have a part 60 with only the smallest possible fluctuations in the high-chip size Diameter and a part of the small throughput in relation to fluctuations in the have knife, the high-voltage side load currents occur. Winding and the low-voltage side winding This object is achieved according to the invention at eini the high-voltage coil (12) to the large high-voltage transformer arrangement of the input! Diameter having part or solved in the manner mentioned 65 in that the magnetic small diameter part of the coil coupling between the high-voltage side Wick body (31, 32) are wound. hung the high voltage coil and the low voltage 8. High-voltage transformer arrangement after voltage coil is narrower than the magnetic coupling]