DE2122220C3 - Protective circuit for protecting circuit arrangements against voltage and / or current surges - Google Patents

Description

The invention relates to a protective circuit for protecting circuit arrangements against Voltage and / or current surges caused by a device connected to the circuit arrangements, in particular

special due to arc discharges in a cathode ray tube connected to the circuitry, consisting of a network with a number of to connect to the circuit arrangements serving input

terminals and a number of output terminals serving for connection to the device, which Network in branches connecting input and output terminals arranged in pairs Longitudinal resistances and against a reference potential!

contains switched cross resistors.

Such a protective circuit consisting of a network with series and cross resistances is from US Pat. No. 3,181,033. This known protection circuit is intended to be used a carrier frequency telephone line and the input of a power amplifier connected to it will. The series and transverse resistances are dimensioned so that they have a line section with the Form wave impedance of the telephone line. In such a pipe section, the longitudinal and transverse resistances do not significantly interfere with the transmission of the carrier frequency signals to the input of the amplifier. On the other hand, at the output of a power supply unit that is used, for example, to supply a cathode ray tube is used. Series resistance in which the cathode ray tube with the power supply unit connecting network, the series resistances bring with them a considerable power loss if they should ensure adequate protection. It is / was already from the German exposition 1 266 362 known to provide series resistors in a protective circuit, but there, too the use of such resistors is considered disadvantageous because these resistors are switched on continuously and therefore lead to a loss of performance. It is undoubtedly correct that series resistances too large may not be chosen in order to keep the loss of performance within limits, if such Currents of considerable strength already flow through resistances in the normal operating state. From the German Auslegeschrift 1 266 362 it is also known to provide overload protection for To bring about power supply units by a circuit arrangement, which in the event of an overload, an automatic Switching off the power supply causes. In this way, a protective circuit with series resistors can be used be waived. However, such a circuit arrangement is ineffective if the External device connected to the power supply unit causes an overload of the power supply unit, but is effective in the event of a fault, in particular a short circuit or an arc discharge, which flows back into the power supply unit Energy released in the power supply

could cause significant damage. For such applications the known circuit arrangement for switching off the power supply unit is completely useless.

In contrast, the invention is based on the object of providing a protective circuit of the type described at the outset Kind so train that they provide effective protection not only against overload, but also against those released in the event of a short circuit or an arc discharge in the connected device and ensures that the energy flowing back into the circuit arrangement is not caused by the protective circuit conditional losses reach too great an extent.

This object is achieved according to the invention in that in a protective circuit of the initially described type in the network there are four branches, of which the first three each have a resistor and the fourth contains an induction coil that between the input terminal of the first branch and a reference terminal a first Zeneidiuile is connected that between the input terminals of the other three branches and the reference terminal each a capacitor is connected that between the output terminals of the first and third branches as well as the second and the third branch each a second and third Zener diode is shaded uuu that the output terminals of the third and fourth branches are connected to one another.

In the protective circuit according to the invention, therefore, in a special arrangement, apart from resistors also used capacitors and zener diodes, which suddenly occur currents to a To derive the reference terminal or be able to short-circuit it between the outputs of the protective circuit, so that the protection does not produce resistances solely by limiting the current but also by diverting the currents via the capacitors and the Zener diodes. The interaction of resistors, capacitors and Zener diodes ensures that that the currents diverted to the reference terminals, capacitors and Zener diodes are not too large Can assume value, so that as a result of an excessive current in the connected to the reference terminals No harmful voltage changes at these reference terminals or cables along "these lines. This is a very simple way of achieving good protection without that the resistors would have to be dimensioned so large that they cause unacceptable power losses have as a consequence.

The invention is described below with reference to the in The embodiment illustrated in the drawing is described and explained in more detail. It shows

F i g. 1 shows the schematic representation of an electromagnetically shielded cathode ray tube in FIG Connection to a circuit arrangement shown as a block diagram, which is a protective circuit arrangement according to the invention, an Intcnsitätskoupler, a video amplifier and other components includes, and

F i g. 2 shows the circuit diagram of an embodiment of the protective circuit arrangement according to the invention.

The circuit arrangement shown in Fig. J. comprises a video amplifier, an intensity coupler 4 and other circuit components such as microcircuits 8 and 10, all of which are contained in a circuit card cabinet 12 and are connected by a bus bar 14 which is earthed. In addition, in FIG. 1 shows a cathode ray tube CRT, not to scale, with its parts of interest. A protection circuit 16, which will be described in detail later, is inserted between the intensity coupler 4 and the cathode ray tube.

Before the protection circuit 16 was provided, it was found that in the case of arc discharges in

ίο the cathode ray tube how the intensity coupler works 4, which is made up of rather sensitive microcircuits, and how it works the associated, also sensitive microcircuits 8 and 10, which are in the same circuit

Management card cabinet 12 are, can be adversely affected if relatively large voltage drops across resistors and inductances were generated as a result of non-suppressed overload currents that flowed through the busbar 14 of the switch card cabinet. Such processes caused the micro-formwork to work incorrectly. which made it necessary to repeatedly replace the circuit boards of the intensity coupler or the other circuit arrangements.

The cathode ray tube CRT has a glass envelope which has a base 20, a cylindrical neck 22 of small diameter, a tapered portion 24 and a transparent face plate 26 at one end. Outside the tube is an electromagnetic deflection yoke 28 surrounding the neck 22 and an electromagnetic shield 30. Inside the tube is an electron gun and anode and an electrostatic shield 32 in the neck 22.

The electrostatic shield 32 consists of an electrically conductive film of colloidal graphite on the inside of the conical section 24 of the tubular piston. The shield 32 forms an annular conductive band on the inside of the bulb, which ^{covers the inside of the bulb between the anode and a fluorescent screen .S 1} , which is located inside the bulb near the front plate 26.

The shields 30 and 32 are separated by the thickness of the tubular piston between them are the plates of a capacitor. This capacitor is likely to have quite a substantial capacity from about 100 to 20OpF. The electromagnetic Shield 30 is attached to the chassis of a display device and is therefore grounded.

When the cathode ray tube CRT is operated , the electron gun and the anode generate an electron beam for recording information on the fluorescent screen S.

The anode is kept at a constant potential that is far above the potential where the electron gun is located. A typical value for the anode potential is around 15,000 to 20,000 V or more above cathode potential.

The entity coupler 4 and the video amplifier 2 and associated circuit arrangements, such as microcircuit arrangements 8 and 10, each exist made of printed circuit cards that carry flat micro-components and are stacked in one Switching card cabinet 12 are arranged. Up to 30 cards can be inserted in the switch card cabinet 12 each card in a familiar way: with a different place along the

5 6

rail 14 is connected. The bus bar 14 is coupler 4, the video amplifier 2 and others

Keeps microcircuit arrangements 8 and 10 away from the chassis of the display device at one point. the

bound, which is removed from the point at which the protection circuit 16 prevents electrical

electromagnetic shield 30 on the chassis ge energy that is gelic-

is grounded, and there will be a fairly long wire in 5, running along it in full

a harness is used to connect the two locations along different paths to the cathode ray tube

electrically interconnect so that they are nomi- related or unrelated

nell be on the same potential. other circuit arrangements that are not disturbed

Before the use of the invention, if such an arc detection

Protective circuit conducted in the event of an arc discharge io charge takes place.

In the cathode ray tube the said wire of the input terminals 71 to 76 of the protective wiring harness an overload current to the collector 16 are connected to the corresponding output terminals 14 - Output terminals TV to 76 'via wires in one, which for example led to a change in the supply 15 cables 42 and the socket 38 with the corresponding land of the flip-flops, which are present in the microcircuit base pins 36 of the cathode ray tube and 8 and 10 are. These and other with the first grid Gl, the second grid drawbacks were the practical application of visual G2, the focusing F, the cathode K and devices in the way, were the filament H are connected by the application,
20 Between the terminals 71 and 71 'there is a resistor. It was in fact imperative that all stand R 1 switched. Between the terminals 72 and undesired and disadvantageous changes, such as 72 'are connected in series, resistors R 5 and R1 were mentioned here, in the various switching resistors Rd and R 3 connecting in series di> processing arrangements have been successfully combated. Ob- terminals 73 and 73 '. Between the terminals 7 ', probably even when using the 25 and 7 4' according to the invention, there is again a resistor R 4 protective circuit still potential differences along the line. An inductor also connects the protective circuit according to the invention because the control coil L 2 connects the terminals 76 and 76 '. The Kon the potential differences do not exceed a permissible level, the isolators Cl to C 7 are Sn of the protective circuit 1>. Before the application of the invention shown in FIG. 2, arranged in an apparent manner, it was further established that each capacitor is connected to a corresponding one, the busbar 14, which is nominally connected to the same reference terminal TR1 to 7Λ8. The Bc potential lies like the electromagnetic suction terminals are connected to a common ground connection in the event of an arc discharge. A Zener diode ZDl is between; of the cathode ray tube CRT a different 35 terminal 71 and reference terminal TR 1 switched to - potential assumed. The above-mentioned long wire is polarized in such a way that its cathode was connected to terminal 71 and the cable harness, as it is still now, because of its anode connected to reference terminal TR 1, which has its own inductance and is an inductive span. Another Zener diode ZD 2 is upright between the voltage drop, which is connected with a fast terminals 71 'and 74' and polarized so that changing, not suppressed, short-term, through 40 its anode with the terminal 71 'and its cathode the wire of the Wiring harness flowing overload current is connected to the terminal 74 '. A third developed an effect that the replacement of a Zener diode or ZD 3 is connected between the terminals 72 'and several of the circuit cards in the circuit card 74' and polarized so that their cathode with cabinet 12 required. By using the terminal 72 'according to the invention and its anode connected to the terminal, the protective circuit for limiting the 45 74' is connected. The terminal 74 'is directly connected to the rate of change of the overcurrent in the with the terminal 75', however with wire of the cable harness and the bus 14 some applications the terminal 74 'with which is the above mentioned, inductive voltage drop, terminal 75' also by another Zener diode that will now be connected to an arc discharge in the cathode, which is polarized in the correct way, the CR 7 tube is generated, to a few 50 to a potential difference between the side Hl of the volt between the points on the busbar 14 filament H and the cathode K to allow. Each is limited, and the shift of the bus potential used in the protective circuit according to the invention, except for the voltage drop across the Zener diode, is to be polarized in such a way that it is acceptable and without consequences under standard multi-conductor. len operating conditions is non-conductive, but when the in F i g. 2 shown, special execution 55 occurrence of an arc discharge can be conductive in the form of the protective circuit 16 according to the invention.

consists of a network that has resistances R I to In a typical embodiment of the protective

R 6, capacitors Cl to Cl, Zener diodes ZDl circuit 16 have capacitors Cl to C5

to ZD3, induction coils Ll and L 2, which have a capacitance of 0.01 mF, the capacitors C6

between input terminals 71 to 76, output 60 and Cl a capacitance of 0.1 mF, the resistors

terminals 71 'to 76' and reference terminals TR 1 to Rl, RS and R 6 have a value of 1000Ω, the resistance

TR 8 are arranged. As later in individual cases, Rl, R3 and R 4 would have a value of 10,000 Q, the

tcrt is, the network is constructed so that it spe- induction coils Ll and L 2 a self-inductance

/ iellc forms circuit paths through which, when 300 mH occurs, the Zener diode ZD1 has a breakdown

ten an arc discharge at the anode of the 65 voltage of 110 V and the Zener diode ZD 2 and

Cathode ray tube CRT temporary overload currents ZD3 a breakdown voltage of 60ÖV each. the

can flow, whereby the protection circuit increases the breakdown voltage of the selected Zener diodes

greatest Tcii of the ί ilx-rlasisirörnc of the intensity * - is taking into account the above-mentioned potential

tiale for the various electrodes of the electron gun chosen so that in the absence of an arc discharge, each Zener diode in the reverse direction is applied with a voltage which is smaller than the breakdown voltage, so that the Zeneruioden are usually non-conductive. The Zener diode ZDl is still chosen so that it is under the normal operating conditions in the protective circuit has a capacitance of less than 10 pF,

The transition takes place is much too short in terms of the currents that can flow briefly and results in the various difficulties dealt with here. Any resistance in the protective circuit 5 16 is sufficient to limit any overload current flowing through it so that its peak value does not exceed an acceptable value. For example, the resistor R 1 keeps the peak current flowing through it at a value below 15 A, and it keeps the

Grid increases if this circuit arrangement responds to modulation signals for the first grid Gl, and this increase should be kept small. The Zener diodes ZD1 and ZD 3 also have a capacitance in the blocking state, but the requirements of the circuit arrangement do not require that this capacitance be given special attention.

because their capacitance is to a certain extent the resistances R 2 and RS and, accordingly, the rise time of the circuit arrangement for the first resistors R 3 and R 6, peak currents flowing through them are below a value of 1.5 A. For each resistance of the circuit arrangement it is characteristic that an overload current peaks in a relatively short time and then falls over a relatively longer period of time. As a result, the strongest temporal change in the current intensity occurs immediately after the onset of the overload current, and it is the accompanying current change - Dic values of the resistances in the protective circuit 20 den, brief inductive voltages on the strong-16 were determined by trial and error so that they sten, when the change in current is greatest. Than deliver the best result. It goes without saying that.di «.. ·». A typical example, the overload current is achieved by values that can be changed in order to satisfy other terminals of the resistor R 1 at its peak value after approximately reversing conditions. With the selection 1 ns and then needs about 20 [is for the disappearance of the resistance R1 a compromise had to be made. The time required has to be closed by a factor of about 10, because too large a value of the resistor R 1, which is longer than the time that would be required, for example, increases the resistance if the resistor R 1 were short-circuited. Talking time of the first grid G1 to video signals. Accordingly, the resistances limit the overload against a 71.1 small value of the resistance R \ current and lengthen the time in which it changes, which is insufficient to the value of an arc discharge at the anode of the cathode-electrode Overload currents to a lower amperage beam tube overflow through this resistance and at the same time to extend the time during which the load current is limited to the desired value, there will be an estimated 100-fold decrease in the change speaking time on video signals The greatest possible speed of the overload current is achieved, of which the value for the resistor R 1 is preferred, because a circuit arrangement that increases the /? C time constant in the desired manner, which determines how long it lasts ,
until an arc occurs between the anode and the
first grid Gl is destroyed. The said RC- 40
The time constant is the product of the stray capacitances, which are formed by the shields 30 and 32 and other components, and the value of the
Resistance Rl. Since the second grid G2, the

Focusing electrode F and cathode K in the opposite of which all reference terminals are connected, protrude to the first grid Gl with a constant protrude, so that the necessary circuit connection potential can be operated, need to be made in the choice of fertilizer, the value of the Resistors R2, R3 and R 4 none The induction coils Li and Ll are specifically like this

Requirements with regard to a response time are designed so that the anode voltage can be applied to them without being seen, and as a result this current saturation can occur. Each induction coil resistances are made much larger than consisting of about 100 turns in an only peo resistor R 1. Consequently, it was the Widerstän- gen position of about 5 cm length by a Ferritkörden R 2, R 3 and R 4 is a very Much larger value wound and entered in a suitable plastic than the resistor Rl, namely the ten are cast. The induction coils Ll and L2 multiply value. Accordingly, the resistors R 2, 55 ken serve to a certain extent a change in the Ri and R 4 for the purpose of the Überlpststrom-Unter- current flow in the coils, which occurs, pressure much better than the resistor Rl. if at the anode of the cathode ray tube a

In fact, experiments with special catho-arc discharges have been taking place. These Induktionsdenstrahlröhren, which coil in the manner indicated here, are used in place of resistors, but without the protective circuit according to FIG. 2 operated in order to avoid an unnecessary loss of power during the feeding process, it was shown that in the worst case, heating current to the filament should be avoided with the second grid G 2 and the focusing because a current of 600 mA would lead to a large part of the electrode F connected circuit parts of the inside of the voltage, which can temporarily flow currents from the secondary winding S Gesitätskopplers, which is supplied, consume when resistors used reach instantaneous values up to 150A. Those 65 that are large enough to .vire a current very quickly reach its peak value, arc discharge an adequate current in about 100 ns, then drop and are in depression to cause about 2; · <; subsided. The time in which this pre- Each of the capacitors Ci to Cl is in the diagram

309645/430

the cathode ray tube CRT coupled * nd are sensitive to higher rates of change of the overload current, benefit to a large extent. The protection circuit 16 is implemented in the form of a unit which is embedded in a dielectric material which is suitable to withstand extremely high potentials and which comprises the input terminals, the output terminals and a ground terminal

connected way via reference terminals TR 2 to TR 8 to a common ground. In practice, such a connection is formed by short wires a few centimeters long, which are connected to a single, common terminal, which in turn is attached to the electromagnetic shield 3 ') and is thereby connected to this shield. Despite its short length, each of these wires has a small self-inductance of a few nH and as a result can cause an undesirable inductive voltage drop if an arc discharge takes place in the cathode ray tube. However, since the rate of change of the overload current that may flow through these wires is severely limited, such inductive voltage drops can be limited to a few volts, which is acceptable and does not cause any problems. If in the cathode ray tube CRT take place arc discharges each capacitor Cl can to C 7 resulting overload currents via the reference terminals TR 2 to TR 8 derived to keep to such currents from the Intensitätskoppler. 4 If necessary, the Zener diode ZDl also conducts the resulting overload currents to the reference terminal TRl . It is possible to use other suitable Zener diodes instead of the various capacitors C1 to C 7 for diverting overload currents, but it is preferable not to use Zener diodes because Zener diodes are more expensive and less reliable than con.

S capacitors.

The protective circuit according to the invention is so successful that even during extended periods of operation, during which several hundred arc discharges have been observed, certain cathode ray tubes with anode voltages of 17,000 and 23,000 V were operated, when using the protective circuit according to the invention only a single one caused a faulty function of a logic microcircuit.

Although the protective circuit according to the invention is particularly useful for the technical area dealt with here is useful and is preferably used in this area, the protective circuit according to the invention ultimately also be of use in other areas for which similar points of view apply, for example in connection with other tubes working with electron beams, in which certain Tube electrodes operated with high potentials and other tube electrodes operated with low potentials

as be, so that there is considerable tension between the different electrodes.

1 sheet of drawings

Claims (5)

Patent claims: 1. Schulz circuit to protect circuit arrangements against voltage and / or current surges that are triggered by a device connected to the circuit arrangements, in particular by arc discharges in a cathode ray tube connected to the circuit arrangements, consisting of a network with a number of for connection to the Input terminals serving circuit arrangements and a number of output terminals serving for connection to the device, which network contains series resistors connected to input and output terminals arranged in pairs and cross resistors connected to a reference potential, characterized in that there are four branches in the network , of which the first three each contain a resistor (R 1: R 5: K 4) and the fourth an induction coil (Ll) that between the input terminal (Tl) of the first branch and a reference terminal a first Zener diode (ZD 1 ) is connected that between the input terminals mmen (72; 74; 7'5) of the other three branches and the reference terminal each has a condenser (Cl; C5; C 6) connected that between the risers (TY or TT and 74 ') of the first and third branches as well of the second and the third branch a second or third Zener diode (ZD 2 or ZD 3) is connected and that the output terminals (74 'and 75') of the third and fourth branches are connected to one another. 2. Protection circuit according to claim 1, characterized in that the first Zener diode (ZDl) with its anode with the reference terminal and with its cathode with the input terminal (71) of the first branch, the second Zener diode (ZD 1) with its anode with the output terminal (71 ") of the first branch and with its cathode with the output terminal (74 ') of the third branch and the third Zener diode (ZD 3) with its anode with the output terminal (74') of the third branch and with its cathode with the output terminal ( 72 ') of the second branch is connected. 3. Protection circuit according to claim 1 or? characterized in that a fifth branch is available. its input and output terminals (76 and 76 ') by a second induction coil (L 2) are connected, between its input terminal (76) and the reference terminal a quadruple capacitor (C 7) is connected and its output terminal (76 ') with the output terminal (75 ') of the fourth branch is connected. 4. Protection circuit according to one of claims 1 to 3, characterized in that there is a sixth branch whose input and output terminals (73 and 73 ') are connected by resistors (R 6, It 3) and between its input terminal (73 ) and the reference terminal a capacitor (C3) is connected. 5. Protection circuit according to one of claims 1 to 3, characterized in that in at least one of the branches whose input and output terminals are connected by a contradiction «two resistors (R 5 and R 2 or R 6 and R 3) in series are connected and a further capacitor (C2 or C4) is connected between the connection point between the two resistors and the reference terminal.