KR800001021B1 - Circuit in a television display apparatus for producing a sawtooth deflection current through a line deflection coil - Google Patents

Abstract

Television display apparatus including a circuit arrange for combined line deflection and supply voltage stabilization, comprising a transformer of which ratio can be freely chosen because the path between the deflection and stabilizing section is blocked at the retrace time.

Description

Sawtooth Wave Deflection Current Generation Circuit

1 shows an embodiment of a circuit according to the invention.

2 shows waveforms generated in the circuit of FIG.

3 shows a variant of the circuit of FIG.

4 shows an embodiment of a circuit according to the invention suitable for a color television receiver.

The present invention relates to a circuit in a television display device for generating a sawtooth wave through a line deflection coil, which is a part of a resonant network in parallel with a first diode, comprising a stray and retrace capacitor, wherein the first diode deflects through the circuit. While current flows during the first portion of the sweep line period, this current flows through the series arrangement of the second diode and the controllable switch during the remainder of the period, i.e., the second portion of the sweep line period. The conduction time of the switch is controlled and the series arrangement of the winding of the first inductance element and the condenser is connected in parallel with the first diode and the deflection coil is coupled to the first inductance element while The junction of the switch is connected to the terminal of the voltage source via the winding of the second inductance element and within the return period the second diode A circuit comprising a switching device for blocking the current in the card.

Such a circuit is known from US Pat. No. 3,912,971. By adjusting the conduction time of this switch, the amplitude of the sweep line voltage and eventually the deflection current can be induced to a predetermined value as a function of the power supply. The auxiliary power supply voltages generated by the circuit are each adjusted but not independently from any value to a predetermined value. For this purpose the transformer ratio of the two windings of the second inductance element can also be used as a parameter. A blocking switching device is absolutely necessary for its predetermined value. Otherwise, the retrace pulse is cut off by the conductive second diode, causing a deflection of the deflection current. The device is configured as, for example, a fourth diode arranged in series with the winding of a second inductance element.

However, it has been found that the desired sweep line voltage cannot be obtained for all values of the supply voltage, especially when the supply voltage is less than the predetermined value of the sweep line voltage. This is the case with television receivers supplied by batteries. It is apparent that a power supply voltage higher than the battery voltage can be obtained by a converter which raises the voltage and gives the power supply voltage supplyable to the deflection current. The advantage of this known circuit is that only one switch is required and no self-stable operation is necessary to obtain the deflection current and auxiliary power. An object of the present invention is to provide a circuit that combines the advantages of a converter that strikes a high voltage (so-called rising converter in English) with the advantages of known circuits. One end of the device is connected and the other end is connected to the power supply via the winding of the second inductance device, and the winding detection of the winding and the conducting direction of the third diode can flow through it during the return period of the deflection current. The feature is that it is. In view of this, it should be noted that the blocking device in the known circuit, i.e., the fourth diode, is necessary only in its predetermined design but is necessary everywhere in the circuit according to the present invention.

1 shows only the most important elements of the line deflection circuit of a television receiver, not shown in detail. The deflection coil Ly, the sweep line capacitor Ct and the return capacitor Cr form a resonant circuit in parallel with the diode D ₁ . The paralleled diode D ₁ is connected in series with the diode D ₂ and the npn transistor Tr, where the conduction direction of the two diodes is optional so that they conduct during the first half period of the sweep line time of the diode D ₁ deflection current and the diode D ₂ during the next half period. It is conducting. The series arrangement of winding L ₁ and condenser C ₁ is nested between junction A and chassis of components D ₁ , D ₂ , Cr and Ly. The emitters of transistor Tr as well as the free ends of components D ₁ , Cr and Ct are connected to the same chassis. Through the choke coil L ₂ and diode D ₄ , the collector of transistor Tr is connected to the positive terminal of the power supply which supplies the DC voltage V _B , and the negative terminal of this power supply is connected to the chassis. The anode of diode D ₃ is connected to tap P of coil L ₂ , and the cathode of diode D ₃ is connected to tap Q of winding L ₁ .

Diode D ₁ conducts during the first half period of the sweep line time. The voltage across the capacitor Ct is applied to the coil Ly through which the coil deflection current iy flows in the direction opposite to the arrow direction shown in FIG. At the beginning of the sweep line time, the transistor Tr is in a non-conductive state. Its collector is at positive voltage and diode D ₂ is in a non-conductive state. At a given moment, Tr is conducted by a pulsed drive signal derived from a line oscillator (not shown). The collector current of transistor Tr flows through coil L ₂ and diode D ₄ , between which D ₂ is not conducting to its anode voltage and the cathode voltage of diode D ₁ is slightly more than its cathode voltage.

Nearly in the middle of the sweep line time current iy, the direction of the current iy is reversed so that D ₂ and Tr flow in total, while the diode D ₂ becomes non-conductive. At the end of the sweep line time, Tr is cut off for the drive signal supplied to its base. An oscillation or retrace pulse is generated at point A and accumulates energy in coil L ₂ , and the energy derived from the power supply produces a current flowing through diode D ₃ to compensate for current losses in the circuit. At the end of the retrace time, the voltage at point A becomes zero again to allow D ₁ to conduct. This is the beginning of a new cycle. Diode D ₃ remains in a conductive state until transistor Tr is conductive so that current through diode D ₃ is transferred by the collector current of transistor Tr. During the entire cycle, current flows continuously through the coil L ₂ and the pulsating current flowing through the power source is lowered and almost no crosstalk occurs.

2a the voltage at point A turning V _A, the collector current of transistor 2b turns is configured for the voltage, the collector voltage of the transistor Tr to turn 2c and 2d the turning time at the point P. T represents the line period, or about 64 μs. T denotes the portion of the period T in which the transistor Tr is conducted. From these, it can be seen that the shortest possible delay of δ _T is almost equal to half of the time of the minor strike period and its possible longest delay is almost the same as the burnout duration. For example, if the delay of the entire return period is 20% of that period, the ratio δ is between 0.4 and 0.8.

DC voltage V ₀ appears across capacitor C ₁ . When the capacitor Ct has a relatively small capacity for the so-called S correction, the DC voltage component of the sweep line voltage across its end, that is, the DC voltage across the capacitor, is equal to the voltage V ₀ . The average value of the voltage V _A is equal to V ₀ . If the value of the voltage V _B is known, the predetermined value of V ₀ can be known and thus the amplitude of the current can be known. These three parameters, the ratio δ and the ratio 1: n of the number of turns drawn to the winding number point P of the coil L ₂ and the ratio of the number of turns drawn to the winding number point Q of the winding L ₁ , 1: m Is important.

The voltage at point Q is equal to (1-m), V ₀ + mV _A. The voltage at the point P (FIG. 2B) is equal to the voltage at the time (1-δ) T at which the diode D ₃ is conducted and is equal to (1-δ) V _{B at} the time δ _T at which the transistor Tr is conducted. At the same time δT, the collector voltage of transistor Tr (Fig. 2c) is actually zero. Diodes D ₂ and D ₄ are not conducting at time (1-δ) _T. At that time its interconnected cathodes, i.e., the voltage of the collector of transistor Tr, is estimated to be the same value as the highest anode voltage, which is the voltage V _A during the return period. At the time interval after the retrace period, at the time interval before the transistor Tr is conducted, this is also the anode voltage of diode D ₄ . That is, since the voltage at the point P is (1-m) and in the same period as V ₀ , the collector voltage is (1-m) equal to V _0- (1-n) V _B.

The voltage across coil L ₁ can be calculated based on this result. This is the relationship between voltages V ₀ and V _B as a function of the world's parameters since the average value of at least one period of this voltage must be zero. This relationship is as follows.

The voltage V ₀ is given a predetermined value by the selection of the parameters m, n and δ. By pulse delay modulation of the pulses driving the base of the transistor Tr with feedback, the ratio δ can be adjusted in a known manner in which the value of voltage V ₀ is independent of the variation of voltage V _B. If simple that is n = 1, and m = 0 case, the connection to the contact point of the diodes D ₃ of enoic lifting coil L ₂ and a diode D _4, and the cathode of the diode D ₃ is connected to the contact point of the wire L ₁ and capacitor C ₁ The case applies as follows:

It can be seen from the above general formula (1) that V ₀ and V _B are the same when V ₀ means that it cannot be controlled or manipulated by δ, ie m = n. For example, this occurs when diode D ₃ is inserted between point A and the junction of coil L ₂ and diode D ₄ , ie when m = n = 1. Thus, it is clear that the circuit must still satisfy another state. This state can be known by assuming the collector voltage of the transistor Tr to be bipolar before the transistor is conductive and within the time interval after the retrace period. If this voltage goes to zero, the time variation of the base control does not affect and this voltage must not be negative, otherwise the collector-base diode of the transistor becomes conductive. This leads to a state in which (1-m) V ₀ must exceed (1-n) V _B. From this point of view, it can be said that this state corresponds to the state where diode D ₃ should not be conducted within time δ _T.

If we know the value of V ₀ / V _B in formula (1) and substitute the value in the formula, we know that n exceeds m. It can be seen from this that V ₀ always exceeds V _B. For this reason, this circuit is suitable for use as a receiver supplied by a battery to a television receiver with a low voltage source.

The ratio of V ₀ to V _B is greater than n is greater than m and it can prove that the variation range of voltage V _B can be compensated by the smaller variation range of ratio δ as n is greater than m.

For this reason it is advantageous to choose n larger than 1 as possible and n as negative as possible. In this way, the circuit shown in FIG. 3 is obtained. Here, the anode of diode D ₃ , but not the anode of diode D ₄ , is connected to the coil L ₂ , and the capacitor C ₁ , not the cathode of diode D ₃ , is connected to the tap of the wire L ₁ . However, there is a restriction in formula (1) that both the denominator and the numerator must be positive. This means that m must exceed 1-1 / δmax, where δmax is the maximum value of δ. For example, when δmax × 0.8, m must exceed −0.25. When n exceeds m, the condition is satisfied at the same time only when the molecule is positive. When m is negative the value of n = 0 is theoretically possible. In FIG. 1 the anode of diode D ₃ is connected to a voltage source. However, it is clear that this circuit does not really work. This is because the current flowing through the coil L ₂ cannot have a path for δ _T at the moment the transistor Tr is switched off. The condition that the denominator and the numerator must be negative in Equation (1) is mathematically theoretically possible, but in practice the circuit cannot be realized.

It should be noted that as described above, diode D ₄ is essential in any environment. This is to be distinguished from the diode in the same place in the circuit described in the above-mentioned patent application and is only limited if the diode is required only for a certain rating. The average value of the voltage at point P in FIG. 1 is V _B and the average value of the voltage at point A is equal to V ₀ . Without diode D ₄ , diodes D ₂ and D ₃ are connected in parallel in opposite conducting directions at voltages V ₀ -V _B , which is not possible.

In practice, coils L ₁ and L ₂ consist of two separate windings interconnected. Thus, in the case of coil L ₂ , one winding is obtained between the power supply and the anode terminal of diode D ₄ and the other winding is obtained between the same terminal and diode D ₃ . The first winding and the diode D ₄ may be interchanged although it is preferred that the winding is directly connected to a point of the electrostatic potential. The same is true for winding II and Iod D ₃ .

In Figures 1 and 3 the winding L ₁ is configured as primary windings of the transformer T, shown as two secondary windings L ₃ and L ₄ as shown in the figure. The return pulses are rectified to generate a DC voltage to other parts of the receiver. One of these voltages is the high voltage for the final anode of the duct. If voltage V ₀ is stable, these voltages are also stable. A modulator (not shown) with a fill delay modulation in a known manner is informed about the voltage V ₀ value by, for example, the secondary winding L ₅ of the facet T (FIG. 1).

4 shows an embodiment of a circuit according to the invention suitable for a color television receiver. The networks D ₁ , Cr, Ly, Ct and the second similar networks D ₁ ′, Cr ′, L ′, Ct ′ are arranged in the manner as specified in more detail in US Pat. No. 3,912,971. The parabolic signal of the feed frequency is supplied through the coil L ₆ so that the line deflection current is provided for so-called east-west modulation. In this circuit, m = 0 and n = 1 have the advantage of no inductance loss. Thus, the current can change in an altitude manner without causing the disturbance. The winding L ₅ is fed back to the drive stage Dr for driving the base of the transistor Tr. In a known method coil L ₂ is the winding of transistor T. The linearity is improved because the anode of diode D ₂ is connected to the tap of winding L ₁ . It is clear that the iodines D ₂ and D ₄ can be replaced by transistors. In an embodiment of the circuit according to the invention the voltage V ₀ is about 36 V relative to the normal value of the battery voltage of 12 V and so the normal value of the ratio δ is about 0.67. Coyle Ly has a magnetic inductance value of nearly 430 μH.

Claims (1)

As described in the text and shown in the drawings, the deflection current is maintained during the second portion of the sweep line period through the series arrangement of the control switch in which the conduction time is controlled and the second diode connected in parallel to the first diode and the sweep line period The first diode, through which the deflection current flows through the first diode during the first part of, provides the sawtooth wave deflection current through the line deflection coil, which is part of the resonant network including the stray and return capacitors connected in parallel and during the return period. The second diode connected to the terminal of the voltage source through a switching device for preventing the flow of current in the two diodes, a series device of windings and capacitors connected with a deflection coil in parallel with the first diode, and a winding of the second inductive element; In a circuit in a television display device including a junction of a switch, one electrode is the first inductive element. A third diode connected to the point and the other electrode connected to the terminal of the voltage supply source through the wire of the second inductor element, and the conducting direction of the third diode and the winding of the third diode so that the current can flow in the retrace period of the unbalanced current. A circuit in a television display for generating a sawtooth wave deflection current through a line deflection coil, characterized in that winding detection is made.

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