SU815497A1 - Saveguard for hydrodynamic level - Google Patents

Description

amplifier 5 is amplified and routed to pulse counter 6.

In the initial state, the electrical disconnecting device 11 is open and the voltage from the power source is completely through the resistor 13 to the electrode 9. The electrically conductive fluid from the pressure vessel 3 enters the control vessel 12 and fills it. When it contacts the electrode 9, a current pulse appears flowing through the power source 10, the electronic device 11 disconnecting device, the resistor 13, the needle electrode 9 and the conductive liquid in the control vessel 12, This current pulse arrives at the trigger 7 and overturns it. At the output of the trigger, a voltage of opposite polarity appears, which locks the amplifier 5, thereby stopping the counting of pulses by the counter 6. From the same voltage, from the output of the trigger 7, an electronic disconnecting device 1 is activated which disconnects the voltage from the power supply 10 from electrode 9, in order to protect the latter from electrochemical erosion.

The electronic disconnecting device 11 is made in the form of keys on field-effect transistors with insulated gate p and p conductivity. Therefore, when the voltage of one polarity is applied to the gates of transistors, one of them is fully open and the other is completely closed. the one of the transistors that was closed opens fully, and the one that was opened closes, and since the transistors are isolated, the control voltage does not fall on the electrode 9. The voltage Source 10 power is turned off almost completely. When installing or repairing the needle electrode 9, there may be cases when it is touched by an electric tool (electric, electric drill, electric screwdriver) on the case of which there is a voltage of up to 380 V. (when probing or when the power tool is poorly grounded)

Since the trigger 7 and the electrons of the HOS tripping device 11 are made on transistors that withstand a maximum voltage of 30 V, then when they hit a voltage of 380 V of industrial frequency, they break down and become completely burned out.

To prevent this from happening, the electrode 9 is connected through a resistor 13 and the threshold element 14 to the electronic disconnecting device 11 and the input of the trigger 7.

When a voltage across the electrode 9 exceeds the breakdown voltage of the threshold device of the Zener diode 14, the latter breaks through to form a series voltage divider, one of whose arms is the resistor 13 and the other is the internal resistance of the open Zener diode 14. Therefore, almost all the voltage from the electrode 9 falls on the resistor 13. Indeed, the internal resistance of the open Zener diode is equal to. the voltage across the electrode 9 is reduced by a factor of 1000.

Zener diode 14. is chosen so that its breakdown voltage is higher than the voltage of power supply 10, but less than the breakdown voltage of transistors in the electronic tripping device 11, Threshold device 14 can also be performed on transistors and microcircuits.

Practically without this protection system, the Electronic Shut-off Device 11 is not operational under operating conditions.

Claims (1)

1. USSR author's certificate 318813, cl. G 01 C 9/06, 1970 (nrotype)