SU1196996A1 - Device for checking conditions of thyristors through control cicuruits - Google Patents

Abstract

1, A DEVICE FOR MONITORING THE CONDITION OF THE THIRISTOR ON THE CONTROL CIRCUIT, LENIUM, contains an anode current sensor, a control signal sensor and a thyristor alarm condition detection unit, characterized in that, in order to simplify and increase reliability, the anode current sensor , the sensor of control signals and the thyristor emergency condition detection unit along the control circuit are completed on the ferride having the first group of actuating reed switches, and the release winding of the first group of actuating reed switches is used as the anodic current sensor, Q S and the actuation winding of the first group of actuating reed switches — as a control signal sensor; O i i; p i; o a B protection and alarm circuit Figure 1

Description

2. The device according to claim 1, characterized in that, in order to expand the functionality of the possibilities by providing control of the thyristor, a delay element is introduced, and the ferride is provided with a second group of actuating reed switches and a third winding, and the actuation winding of the first group of actuating reed switches is used as winding release for sec96996

a swarm of a group of executive reed switches, and a winding of releasing the first group of executive reed switches was used as a winding for the second group of executive reed switches; a third winding was used as a release winding for both groups of executive reed switches and scrapes to connect the output terminals of the thyristor control unit through a delay element.

one

The invention relates to the field of electrical engineering and can be used to control and protect converters.

The aim of the invention is to simplify, increase reliability and expand functional capabilities by providing control of a thyristor probe,

Fig. 1 is a schematic diagram of a device for controlling a thyristor; FIG. 2 is the same, a possible embodiment of its implementation; on fig.Z. - the design of the magnetic system of the device; 4 is a diagram of a control device with two groups of reed switches and three windings; FIG. 3 shows the structure of the magnetic system of the device.

The device 1 for monitoring the state of the thyristor contains ferrid, winding 2 of which is connected to the anode current of the controlled thyristor and used as a sensor of the anode current of the thyristor, and winding 3 is connected to the thyristor control unit 4 and is used as a sensor of control signals. Ferrid has the first group of actuating reed switches 5, an element of magnetic memory, the second group of executive reed switches 7 and the third winding 8.

The device works as follows.

To turn the thyristor on its control electrode, a pulse is fed from the control unit 4. At the same time, the winding 3 of the ferride is excited and the magnetization reversal element 6 of the magnetic memory (Fig. 3) is made of a material with a rectangular hysteresis loop. The time of magnetization reversal of the magnetic memory element can be in units of microseconds, and the magnetic field energy stored by it is sufficient to operate the first

groups 5 executive reed switches and keep them in a closed state after the current in the winding ceases. Closing of reed contacts occurs with some delay

with respect to the excitation pulse (for reed switches of CEM-2, for example, the time from the moment of impulse delivery to the winding to the first collision of the strokes is about 100 μs,

and for reed switches of type CEM-1 - about 300 s). During this time, the thyristor turns on and the current in its anode circuit increases to a value sufficient to excite winding 2,

which remagnetizes the magnetic memory element of the ferride in the direction corresponding to the release of the dry terminals 5; Therefore, in the normal mode of operation of the thyristor of the contact contacts

reed switches do not occur and the signal

It is not supplied from the monitoring device to the protection and signaling circuit.

In the emergency mode of the thyristor, which is characterized by its non-inclusion in the presence of a signal from the control unit 4, winding 2 is not excited and the state of the magnetic memory element is determined by the preceding

3

excitation of the winding 3, i.e. the reed switches 5 of the first group are activated and the signal is given that the thyristor is not included in the protection and signaling circuit.

Thus, if the winding 3 connected to the thyristor control unit 4 is the actuation winding for the first group of reed switches 5, and the winding 2 connected to the anode thyristor circuit is a release winding, the device provides control of not turning on the thyristor. In order for the device to function properly, it is necessary for the thyristor anode current pulse in the normal mode to lag (later end) with respect to the pulse of the control unit 4, which is almost always performed in thyristor converter circuits. In most cases, the duration of the impulse block 4

controlling less time before the first impact of the reed switch contacts when triggered and no overlap is required. constraints on the ratio of the magnetomobile forces (VAT) of windings 2 and 3, If the pulse duration from control unit 4 is longer than the first contact of the reed contacts, it is desirable that

The HVS of the winding 2 connected to the anode current circuit and which is the release winding. Then even short circuits of the contacts of the reed switches will not occur in the normal operation of the thyristors, which eliminates the need to introduce a delay in the operation of the actuating elements of the protection and signaling circuits, moreover, if the electrical circuits are not switched when the reed switches are energized, their service life increases by several orders of magnitude and becomes completely commensurate with the lifetime of the monitored device. Winding 3 can be connected directly to the control electrode circuit. Storey, but may also be connected to a separate and tsyhodu control unit 4 (FIG. 2), two parallel winding included in the anode current of the thyristor circuit may be connected to a linear or non-linear shunt (Figure 2)

If in the proposed device to make so that the winding 3, under 969964

The key to control unit 4 will be a winding release for the first group of reed switches 5, and winding 2 connected to the thyristor anode current circuit will winding the trigger, then the device will signal a different type of damage to the torus breakdown - breakdown, in this case it is necessary that In the normal mode of operation of the thyristor, the MDS winding 3 prevailed and the pulse in it terminated later than the anode current pulse. In winding 2, then the signal from the device will be fed into the circuit

15 protection and alarm in the presence of current in the anode circuit of the thyristor in the absence of a control pulse, i.e., during the breakdown of the thyristor. More convenient in this case is

20 connecting the winding 3 to a separate output of the control unit 4, a pulse must be supplied to it - synchronously or with some delay in relation to the pulse applied to

25 of the thyristor control electrode, and it should end somewhat later than the anode current pulse.

In the design of the magnetic system of ferride (Fig, 3), with which

possible implementation of the proposed

0

device for monitoring the state of the thyristor, the magnetic memory element 6 consists of two cores. (plates), between which the reed switches 5 of the first group are located, 06 hanks 2 and 3 cover the cores of the magnetic memory element 6, and the winding 3 magnetizes the cores in the direction of the longitudinal axes of the first group of reed switches 5, and the winding 2 perpendicular to them.

As a result of the excitation of the winding 3, the residual magnetic flux of the cores of the magnetic memory element 6 magnetized opposite each other is closed through the reed switches 5 of the first group and they are activated. If winding 2 is energized, then the magnetic memory element 6 is magnetized perpendicular to the axis

0 reed switches and does not affect them. In this case, winding 3 is the actuation coil and winding 2 is the release winding. When turning the longitudinal axes

The 5 reed switches 5 of the first group over 90 windings 2 and 3 change their roles, and then devices that control the breakdown of the thyristor are obtained. $ 1 If the magnitude of the anodic current of the controlled thyristor is sufficiently large (hundreds of amperes and above), then the winding 2 can be executed in the form of one or ½ coils of the bus of the corresponding section. A second group of reed switches 7 are entered into the device diagram (Fig. 4) and the third winding 8, the second group of reed switches 7 is located in such a way that the winding .2 for them is the pickup winding, and the winding 3 is the release winding. At the same time, for the first group of reed switches 5 the pickup winding 3, and winding release - winding.2, Thus being in driven one after the other, windings 2. and 3 change the state of the contacts of the first and second groups of reed switches 5 and 7, respectively, to the opposite. The third winding 8, connected like winding 3 to control unit 4, is a release winding for both groups of reed switches. In the normal operation mode of the thyristor, when a pulse signal is applied to its opening, winding 3 is excited and the magnetic memory element is magnetized in the direction providing actuation of the first group of reed switches 5; When a thyristor is opened, its anode current excites winding 2 and the magnetic memory element is re-magnetized in the direction ensuring the operation of the reed switches 7 of the second group and releasing the switches New 5 of the first group. At the end of the normal operation cycle, the control unit 4 with a certain delay in relation to the impulse supplied to the winding 3 receives a signal to the winding 8, which ensures the release of the reed switches of both groups; the GVA of the winding 8 should prevail over the VAT of the windings 2 and 3 and the momentum in it must end late. In the case of a thyristor probe, there is no signal from the control unit 4, and at the same time the excitation of the windings 3 and 8, As a result, the state of the device contacts is determined by the prior excitation of the winding by the current of the punctured thyristor, the contacts of the second reed switch group 7 are closed, as they signal breakdown. 6 If the thyristor is not turned on when there is a signal on the control electrode (and winding 3 is energized) there is no signal in winding 2, and during the period until winding 8 is turned on, the contacts of the first reed switch group 5 are closed, which serves as a non-switching signal to the protection and signaling circuit In order for the device to work without switching the circuits in normal mode, the response time of the reed switches 7 should be longer than the time of reloading of the reed switches 5 of the first group, which can be achieved either by selecting reed switch parameters or cons in a reactive way, for example, using a short-circuited coil installation covering the second group of reed switches 7, In the control device (FIG. 4), windings 2 and 3 and the first group of reed switches 5 are arranged in the same way as in the design of FIG. 3, Angshoic and element design 6 memories. The reed switch group 7 is oriented perpendicular to the reed switch 5 of the first group and is triggered when the magnetic memory element is magnetized by the winding 2. The winding 8 consists of two sections one on each core of the magnetic memory element, the sections being wound so that the cores magnetize according to (shown by arrows) As a result, the residual magnetic flux of the magnetic memory element is pushed from one core to another, it does not affect the reed switches 5 of the first group, and the latter are released, the reed switch 7 of the second group is also released, As the core adjacent to them is magnetized perpendicular to their longitudinal axis, K; onst1) a magnetic system is not the only possible one, c. by means of which the proposed device for monitoring the state of the thyristor is implemented, but in terms of a number of parameters it has an advantage over other types of ferrides, in particular, it is best to release the reed switches using a high-current winding (winding 2),

In the protection scheme

and. alarms 2

b protection and signaling circuit

Claims (2)

LENIA, containing an anode current sensor, a control signal sensor and a thyristor emergency state detection unit along the control circuit, characterized in that, in order to simplify and increase reliability, the anode current sensor, a control signal sensor and a thyristor emergency state detection unit along the control circuit are made on a ferride having a first group of executive reed switches, the release winding of the first group of executive reed switches used as an anode current sensor, and the operation coil of the first group 2. The device according to claim 1, characterized in that, in order to expand the functionality by controlling the breakdown of the thyristor, a delay element is introduced, and the ferride is equipped with a second group of actuating reed switches and a third winding, and the operation winding of the first group of actuating reed switches is used as a winding release for the second group of executive reed switches', and the release winding of the first group of executive reed switches is used as a tripping coil for the second group of executive reed switches s, the third coil winding used as releasing groups for both the executive reed isoedinena sklemmami dlyapodklyu cheniya output terminals of the control unit via the delay element tiristrom