SU1450036A1 - System for controlling power supply to nozzle feeder - Google Patents

Abstract

The invention relates to electrical engineering and can be used in fiberglass manufacturing plants for protection against over-spinning feeder. The purpose of the invention is to increase the reliability of the power control system of the spin-hole feeder. This system protects the spinnered feeder against overload and overheating, while the system uses the software setter to change the setpoint of the operating unit of the overcurrent protection module. 2 Il. -Q "

Description

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1U50036

The invention relates to electrical engineering and can be used in fiberglass manufacturing plants for protection against over-spinning feeder.

The aim of the invention is to increase the reliability of the power control system of the spinneret feeder.

Figure 1 presents the functional diagram of the system; Fig. 2 shows an example of a software master.

The power supply control system of the spinnered feeder contains a switch 1, a thyristic power amplifier 2, a furnace step-down transformer 3, a thermal sensor 4 of a spinnered feeder, a temperature controller 5, implemented as a temperature setpoint 6, an adder 7, a measuring amplifier 8 and a regulating module 9, a software setpoint 10 , block 11 overcurrent protection, made in the form of measuring current transformer 12, matching transformer 13, load resistor 14, rectifier 15, filter 16, differential force tel 17

In the mode when the current in the network exceeds the nominal value, the current flowing through the secondary winding of the matching transformer 13 creates a voltage drop across the load resistor 14, which is fed through the head 15 and the filter 16 is fed to the non-inverting input of the comparator 19 and

10 an inverting input of the differential amplifier 17. In the event of an overcurrent in the network of the installation of the operation of the comparator 19, which is exposed by means of a resistive divider 20,

15. The comparator 19 is triggered, the signal from its output through the amplifier 21 is supplied to the actuator 24, the latter, having triggered, acts on the opening coil of the switch 1, which triggered and disconnects the electrical installation from the alternating voltage source. Simultaneously with the operation of the KOMnapas-opa 19 signal from the VYEKODA differential amplifier 17

25 arrives at indicator 18, which causes its arrow to deviate from zero,

In this mode, the signals from the outputs of the software setpoint 10 are equal to the indicator 18, the comparator 19c therefore does not affect the operation of the blister divider 20 on the inverting input, the amplifier 21, the stabilized power supply 22 with the resistive divider 23, the actuator 24,

Programming unit 10, contains program setting unit 25, integrator 26, differential amplifier 27e, diodes 28 and 29, resistors 30-32,

The system works as follows

In the temperature stabilization mode, the nominal current (10-100 A) flows through the windings of the current transformer 3, and compares in adder 7: two signals from the output of the thermal sensor 4 and from the output of the temperature setpoint 6. The signals at the outputs of the software setting device 10 are equal to zero.

The difference between the signals from the output of the adder 7 is amplified by the measuring amplifier B, developed by the regulating module 9, the output of which is amplified by a thyristor power amplifier 2, maintaining a stable temperature of the feeder at the installation point of the thermal sensor 4 and the nominal current value in the primary windings of transformers 3 and 12,

ka 11 maximum current protection.

When the system operates in the program heating mode, the signal of the temperature setting device 6 is 7-8 mV, which corresponds to the nominal current value in the primary winding of the transformer 3. At the same time, the signal at the first output of the programming setting device 10 decreases according to a predetermined heating program

40 zero from the value equal to and opposite in sign of the difference between the signals of the temperature setpoint 6 and the thermal sensor 4; In the adder 7, the signals of the thermal sensor 4 are added together,

45 setpoint 6 temperature and the signal coming from the first output of the software setpoint 10, the resulting signal is amplified by the measuring amplifier 8, is processed by the module 9, the output signal of which is amplified by a thyristor power amplifier 2, increasing the temperature of the feeder at the installation point of the thermal sensor 4 and

JJJ, the amount of current flowing through the windings of transformers 3 and 12, from zero to nominal, I „of the second output of the program 1 of the multiple sensor 10 to the resistor divider 20

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In the mode when the current in the network exceeds the nominal value, the current flowing through the secondary winding of the matching transformer 13 creates a voltage drop across the load resistor 14, which is fed through the head 15 and the filter 16 is fed to the non-inverting input of the comparator 19 and

the inverting input of the differential amplifier 17; In the event of an overcurrent in the network of the installation of the operation of the comparator 19, which is exposed by means of a resistive divider 20,

The comparator 19 is activated, the signal from its output through the amplifier 21 is fed to the actuator 24, the latter, having triggered, acts on the disconnecting coil of the switch 1, which is activated and disconnects the electrical installation from the alternating voltage source. Simultaneously with the operation of the KOMnapas-opa 19 signal from the VYEKODA differential amplifier 17

arrives at indicator 18, which causes its arrow to deviate from zero,

In this mode, the signals from the outputs of the software setting device 10 are equal, well, therefore, they do not affect the operation of the maximum current protection unit 11.

When the system operates in the program heating mode, the signal of the temperature setting knob 6 is 7-8 mV, which corresponds to the nominal current value in the primary winding of the transformer 3. At the same time, the signal at the first output of the programming setting unit 10 decreases according to a predetermined heating program

zero from the value equal to and opposite to the sign of the difference between the signals of the temperature setpoint 6 and the thermal sensor 4; In the adder 7, the signals of the thermal sensor 4 are added together,

the setpoint 6 of the temperature and the signal coming from the first output of the software setpoint 10, the resultant signal is amplified by the measuring amplifier 8, is processed by the module 9, the output signal of which is amplified by the thyristor power amplifier 2, increasing the temperature of the feeder at the installation point of the thermal sensor 4 and

the amount of current flowing through the windings of transformers 3 and 12, from zero to nominal, I „the second output of the program 1 of the multiple sensor 10 to the resistor divider 20

at the moment of switching on, a signal is received that is opposite in sign to the signal that is on the movable contact of the resistive divider 20 at the nominal value of the current in the primary winding of transformer 3. These two signals are (partially) compensated so that at the first moment at the current in the primary winding of transformer 3 equal to zero, the protection unit 11 is configured to disconnect the object from the network when the current value in the primary winding of the transformer 3 reaches only 20% of the nominal operating value. In the process of heating the spinnered feeder, the signal at the first output of the software setpoint 10 decreases, the current in the primary winding of the transformer 3 continuously increases from zero to the nominal value, the signal at the second output of the programming setting 10 also decreases, therefore from the moving contact of the resistive divider 20, the setting signal current protection, which increases in accordance with the heating program (the installation monitors the temperature of the feeder).

The operation of the software setpoint 10 in the mode during power interruptions is as follows. In this mode, the capacitor of the integrator 26 discharges through the input impedance of the microcircuit. When the power is turned on, the output signal of the integrator 26 becomes equal to zero, and at the output of the differential amplifier 27 and at the outputs of the software setpoint 10, the signals reach their maximum value.

In the program warm-up mode, the process of charging the integrator capacitor 26 takes place, the duration of the flow of the clock (the rise rate of the output voltage of the integrator) depends on the level of the input signal coming from the output of the program setpoint 25, which is a variable resistor, the fixed contacts of which are connected to power supply, and movable - to the input of the integrator 26. The movable contact is set manually. In the integration mode, a monotonically increasing signal is generated at the output of the integrator 26, which is inverted by the differential by the amplifier 27 and is converted into a monotonically killing signal.

during the differential amplifier 27 and the outputs of the software unit 10.

In the temperature stabilization mode, the output signal of the integrator 26 reaches its maximum value, and the signals at the outputs of the programming unit 10 become equal to zero.

The setpoint 6 of the program heating temperature is not rebuilt. The temperature setting device 6 has a manual setting and is adjusted once to the nominal working value of the EMF of the thermal sensor 4 when the spinneret feeder is started up. On the setpoint set three, the temperature remains constant both in the program heating mode and in the temperature stabilization mode.

Upon completion of the warm-up, the signal from the second output of the software setpoint 10 becomes equal to zero, the threshold of the maximum current protection unit 11 becomes equal to the value by which it was set in the temperature stabilization mode at the rated current.

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Thus, the system allows protection with a high degree of accuracy when the rated current is exceeded by 20%, both in the temperature stabilization mode, when the current practically does not change, and in the warm-up mode, when the current rises from zero to nominal operating value. , thus preventing the overhaul of expensive equipment, increases the reliability of the protection of the die feeder.

Claims (1)

Formula of the invention The power supply control system of the spinnered feeder, containing a switch connected to the alternating voltage source, successively connected thyristor power amplifier, an oven step-down transformer, to the secondary winding of which a temperature sensor is connected to be mounted on the spinnerette feeder, a temperature controller, made as serially connected temperature setters, adder, measuring amplifier and regulating module, while the first input of the adder is connected to the output , do thermal sensor, the second input - to the first output of the program setting unit. 5145 The regulator output is connected to the control input of the thyristor power amplifier, which is different from the fact that, in order to increase the reliability of operation, the additional | | / R 1l. Lernapd ff feed -rv-v; protection, the input of which is connected to a source of alternating voltage, the regulating input is connected to the second input of the program master, the output is connected to the disconnecting coil of the switch. J and Phi.1 Jf Fig2