SU794625A1 - Device for protecting stabilized dc voltage supply source - Google Patents

Description

The contact closure pattern Sv is opposite to the contact closure pattern of Pro and 36, and the contacts of relay 5 are closing. In the proposed protection device, the contacts Sv are also closing, whereas the contacts Over 36 are opening. This involves the use of a protection sensor, in which the output voltage is absent in the normal state (as in the prototype). Sensor input i2 is connected to the measuring circuit on the load side. The protection sensor is also connected to the reclosing element 7.

During normal operation of the device, when the output voltage of source 1 does not deviate beyond the zone of pickup of sensor 2, the relay coils and 5 are de-energized, and the usual four-wire is connected through closed contacts of Pro and 36. connection of the power source with the load.

If conditions arise for the operation of sensor 2, the contacts of Prot and 36 are opened, disconnecting the load, and the contacts of S are closed, restoring the connection of the measuring circuit with the power wire. When the protection sensor is turned on again under the influence of a signal from element 7, relay 3 will come to its initial state when contacts A and 36 are closed and contacts S are open. Now, if there is no longer any reason for triggering sensor 2, the measuring circuits of the power supply (feedback) will again close to the load.

However, if the connection of measuring and power circuits would be carried out only through the contacts of the relay 3, when they were switched, there would be a short break of this connection due to the fact that when the output voltage of the protection sensor appears (plot 8, Fig. 2 ) and caused by this actuation of the relay 3, contacts Za, 36 are open, necessarily earlier (plot P), than the contacts of Sv closed (plot 10). Similarly, when switching off the relay 3, for example, under the influence of a signal from element 7, contacts 3 are open before the contacts are closed, 36. The separation time of the measuring circuit (feedback) from the power circuit would be several tens of milliseconds (for example, vm TU-Ii6-523j092-169-10-25 milliseconds}. During this time, the power source could have time to go into the mode of maximum possible unstabilized voltage and when the load is switched on again, to which the protection sensor is connected, as in the previously considered Cases x could happen it myself ovlyklyuchenie.

This disadvantage is eliminated with the help of relay 5, which is assumed to be low-power, and consequently, with greater speed than the main relay 3. The relay is chosen as low-power because, as

it will be shown below, the relay contacts 5 do not commute the load current. When voltage is detected at the output of sensor 2, relay 5 first triggers (plot 11, fig. 2), the winding of which passes the charge current of capacitor 4, and then relay 3 triggers (although the voltage on the windings of both relays appears ). During the charging of the capacitor 4, the relay 5 is turned off and during further operation will be de-energized, and the capacitor 4 will be charged to the voltage at the output of the sensor 2. Relay 3 will remain in the on state. The constant charge time of the capacitor 4, i.e., the capacitance at a given output voltage of the protection sensor and the release voltage of the relay 5, is chosen such that the on-time of the relay 5 is longer than the closing time of the Zv contacts of the relay 3.

When the voltage at the output of sensor 2 is turned off, the relay 3, due to its inertia, will change the position of its contacts not immediately, but with a delay, while relay 5 will turn on with a significantly lower delay than the relay 3. Turns off the capacitor 4 through the windings of both relays (up to the value of the release voltage of the relay 6) contacts Over will be blocked by contacts 5a until (with an appropriate choice of capacitor 4 capacity) until the contacts of relay 3 switch (take the initial position shown in the drawing) and the measuring and the circuit does not connect with the power on the load (plots, fig. i2). So that when capacitor 4 is discharged through the windings of both relays, only relay 5 is triggered, and relay 3 remains in the off state, it is necessary that the resistance of the winding of relay 3 be much lower than that of relay 5. This condition is easily fulfilled, since relay 3 Usually a powerful (contactor), and relay 5 can always be selected from low-power ones, because, as should be considered, plots 9, 10, 11, this relay does not switch the load current (it does not even switch the current of the measuring circuit), since relays switch when the ist The power point is connected to the load of the power and measuring circuits via contacts Z, 36, or when the load is disconnected and the power and measuring circuits are connected by contacts Sv. For example, a pair of 1 relay 8M (contactor) and; relay РЗС-64 РСО. 466.014TU PC4.569.72SH2, which can be used in the proposed device, the resistance of the windings, respectively, is 70 Ohm and 2 kΩ.

The overlap by means of a relay 5 of the moment of no connection by the contacts of the relay 3 of the measuring and power circuits is ensured by a significant difference in speed; power and low: high-power relays (as well as the last choice of capacity

capacitor 4). Especially noticeable. The difference between the times of operation can be obtained if the usual electromagnetic relay is selected as the relay, the closing time and the opening are not between 50-150 ms, and the relay with magnetic control is used as the relay 5, the response time contacts of which are 3-15 times higher than that of electromagnetic relays, even with the same switched power, and the return time to the initial state (release) is shorter than that of the electromagnetic relay of the same switched power - more than 10 r az For example, the response time of said 8M relay. (contactor) and RES-64 (relays with magnetically controlled contacts) have a value of 40 ms and 0, 2 ms, and the release time of these relays is 40 ms and 0.3 ms, respectively.

The proposed device can be made in a multichannel version, while (also as in the prototype) the protection sensors must be by the number of channels, and the outputs of all the protection sensors must be combined and connected to the relay 5 and 5 (the latter through the capacitor 4), and the number Contact groups For, 36, Sv and 5a should be increased accordingly as many times as you need to have channels, and each such contact system (three contact groups of relay 3 and one contact group of relay 5) should be switched on in all channels similarly to the first ka alu.

The protection device of the stabilized power source favorably differs from the prototype, since its use does not lead to restrictions on the possibility of providing stabilization on the load, which

allows to improve the quality of the stabilization of the voltage and bring it to the values achievable for the known connection scheme of the power source with the load by a four-wire line without deterioration of all its other parameters.

Claims (2)

1. USSR author's certificate number 479099, cl. G 05 F 1/58, 1973. 2. USSR author's certificate No. 205120, cl. G05 F 1/58, 1966 (prototype). . . one 5a rear 3S one Behind s 1