DE4202423A1 - HV stabiliser circuit for TV receiver - has capacitor formed by wire, coiled round HV cable and coupled to tap - Google Patents

Abstract

The receiver has a HV transformer (Tr) whose output terminal (c) is coupled to the CRT (7) anode via a HV cable (6), and to earth via a voltage divider (R1,2). The divider tap (d) provides a variable value for a control circuit (8). Between the output terminal and the tap, a capacitor (C1) is formed by a wire (15) coiled round the HV cable and coupled to the tap. Pref. the wire coil is axially inserted onto the HV cable and made of bronze without, or with, insulation. It may have a plug pin coupled to one end for connection to the tap. ADVANTAGE - No need for capacitor to be moulded in its parallel arrangement with the bleeder. Requires no special expensive capacitor.

Description

The invention is based on a circuit according to the Oberbe handle of claim 1. In such a known scarf tion becomes the high voltage at the anode of the picture tube voltage of approx. 25-35 kV with a voltage divider from one high-resistance bleeder and a low-resistance resistor divided. The resulting from the low resistance, The voltage proportional to the high voltage is used as a manipulated variable a control circuit for high voltage stabilization guided. There is a capacitance at the input of the control circuit effective, either as a capacitor to suppress interference voltages or as an unavoidable input capacity of the Control circuit. This capacity prevents voltage Jumps in the high voltage divided accordingly unchanged get to the input of the control circuit. It is therefore known, a condenser parallel to the high-resistance bleeder switch gate. This capacitor forms with the above Capacitance a capacitive voltage divider and enables that a voltage jump in the high voltage in the form un changed to the input of the control circuit. To the However, almost the entire capacitor is inevitable High voltage. The capacitor must therefore withstand voltage of about 35 kV, which in practice is only possible a potting of the capacitor or by an intolerant bar-sized special capacitor can be achieved.

The invention has for its object the Kon to realize capacitor parallel to the bleeder so that a Shedding is not necessary and also not an expensive special capacitor must be used. This task is accomplished by solved the invention specified in claim 1. Beneficial Further developments of the invention are in the subclaims specified.  

In the case of the invention, therefore, the high chip that is present anyway power cable, with which the high voltage from the output of the high voltage transformer led to the anode of the picture tube is used in addition to the realization of the capacitor uses. This cable already has the required high voltage strength. A breakdown of the condensate formed tors is practically excluded. The price for the implementation of the capacitor is low because only a simple jumper wire with a total length of a few Meters is needed. This jumper wire can be uninsulated or be insulated and is preferably made of copper or bronze. Attaching the wire to the high voltage cable, the so-called handling, is very simple. The wire is preferably machined into a spiral and then sitting tightly by hand from one end in the axial direction pushed onto the high-voltage cable before it is plugged in the housing containing the bleeder or inserted into the picture tube is stuck.

The wire wrapped around the high voltage cable forms at the same time a shield for the high-voltage cable against interference. In the invention thus a two double use of components achieved. On the one hand the conductor of the high-voltage cable is used to feed the High voltage to the picture tube and at the same time forms the first Electrode of the required capacitor. On the other hand, forms the wire is the second electrode of the capacitor and acts additionally as a shield for the high-voltage cable.

The invention is explained below with reference to the drawing tert. Show in it

Fig. 1, the circuit according to the invention with the realizable th capacitor,

Fig. 2 shows a constructive solution for the realization of the capacitor by the wire and

Fig. 3 shows the formation of one end of the wire.

Fig. 1 shows the high voltage stage 9 with the Linienendstu ftransistor 1 , which is controlled at the terminal b with the zeilenfrequen th switching voltage 2 , and the high voltage transformer Tr, the primary winding 3 to the terminal a with an operating voltage + UB and its secondary winding 4 the high-voltage rectifier 5 is connected to the output terminal c supplying the high voltage. The terminal me c, at which there is a high voltage UH of 20-35 kV, is connected to the anode of the picture tube 7 via the high voltage cable 6 . The high-voltage cable 6 is also connected to the series circuit comprising a high-resistance bleeder R1 of approximately 1 GOhm and a low-resistance resistor R2 of approximately 1 MOhm. A manipulated variable Us, which represents the fluctuations in the high voltage UH and is applied to the input of the control circuit 8 , is created at the tap d. In the control circuit 8 , Us is compared with a reference voltage. The control voltage Ur thereby obtained reaches the control terminal e of the high voltage stage 9 and acts there to stabilize the high voltage UH.

At the terminal d at the input of the control circuit 8 , the capacity C2 is effective. This capacitance C2 itself prevents a jump 10 in the high voltage UH from reaching the input d. To compensate, a capacitor C1 of about 20-40 pF is therefore connected in parallel with R1. This capacitor C1 causes despite the presence of the C2-voltage jump 10 in the desired manner in the form of unchanged to the input d of the control circuit 8 passes, thus ensuring a rapid control of the jump 10 by the control voltage Ur. At the capacitor C1 is practically the entire high voltage UH, so that this capacitor has a corresponding dielectric strength and therefore had to be poured ver.

Fig. 2 shows a housing 11 , in which two bleeder partial resistors R1a and R1b and the resistor R2 according to FIG. 1 are gela gert. The housing contains two chimney-like, tube-shaped shafts 12 , 13 , at the inner ends of which a body 14 is made of conductive rubber, which in turn is connected to the lower end of resistor R1a. The coming from the terminal c section 6 a of the high-voltage cable 6 is inserted into the shaft 13 so far that the outstanding pointed tip end engages in the body 14 made of conductive rubber. The second section 6 b of the high-voltage cable is meanwhile inserted into the shaft 12 and also connected to the body 14 made of conductive rubber. The cable 6 b is connected at its other end to the anode of the picture tube 7 . The circuit and arrangement described so far is known.

In addition, a bare or insulated jumper wire 15 is now provided. At the upper end, the jumper wire 15 is formed into a coil 15 a by winding it onto a cylindrical body, approximately with the outside diameter of the high-voltage cable 6 . The coil 15 a of the wire 15 is pushed in the axial direction on the high-voltage cable 6 b before the ses is inserted into the picture tube 7 or the shaft 12 . The coil 15 a of the wire 15 sits tightly self-holding on the cable 6 b or is attached to the cable 6 by additional means. The lower end 15 b of the wire 15 is connected to the terminal d, while the upper end 16 of the wire 15 runs freely and is not electrically connected to components. Between the inner conductor 17 of the cable 6 b and the turns of the coil 15 a of the wire 15 , the desired capacitance C1 of about 40 pF is formed. The coil 15 a can also lie on the high-voltage cable 6 a between the shaft 13 and the high-voltage connection c of the high-voltage stage 9 . The coil 15 a also acts as a shield for the cable 6 b against radiation or radiation of interference fields. The wire 15 is preferably made of bronze, copper, aluminum or another electrically conductive material.

In Fig. 3, a plug 18 is attached to the end 15 b of the wire 15 , which is soldered to a nail of a printed circuit board connected to the terminal d or inserted into a plug contact on the circuit board.

Claims (7)

1. Circuit for stabilizing the high voltage in a television receiver with a high-voltage transformer (Tr), the output terminal (c) via a high-voltage cable ( 6 ) with the anode of the picture tube ( 7 ) and via a voltage divider (R1, R2) connected to earth is at the tap (d) a manipulated variable for a control circuit device ( 8 ) is removed, a capacitor (C1) being located between the output terminal (c) and the tap (d), characterized in that the capacitor (C1) is formed by a wire ( 15 ) which is wound around the high voltage cable ( 6 ) and electrically connected to the tap (d). 2. Circuit according to claim 1, characterized in that the wire ( 15 ) is formed into a spiral ( 15 a) and axially pushed onto the high-voltage cable ( 6 b). 3. Circuit according to claim 1, characterized in that the wire ( 15 ) consists of bronze. 4. A circuit according to claim 1, characterized in that the wire ( 15 ) is uninsulated. 5. A circuit according to claim 1, characterized in that the wire ( 15 ) is insulated. 6. Circuit according to claim 1, characterized in that at one end ( 15 b) of the wire ( 15 ) a pin ( 18 ) is struck, which is connected to the tap (d). 7. Circuit according to claim 1, characterized in that at one end ( 15 b) of the wire ( 15 ) is a plug sleeve is beat, which is connected via a pin on the circuit board with the tap (b).