CS276856B6 - Water level sensor circuit - Google Patents

Abstract

The essence of the circuit is that the output of the RC member (10) is connected to the RF input of the generator (11), the first output of which is connected to the second gate input / 4 / NAND whose first input is connected to the power terminal, the gate output / 4 / NAND is connected to the first resistor terminal (R4), whose second terminal is connected to the diode anode (D2 / LED whose cathode is connected to ground) while the second RF output of the generator (11) is connected via coupling coupler / 04 / to the sensing probe (S), first to the second gate port (3 / NAND) and second to the first resistor port (R5), the second port of which is connected to both the power terminal and the first gate port (3 / NAND), the output of which is connected via a rectifier (12) to the input of the switching transistor block (13), to which the relay (14) is connected. The sensing probe (S) is formed by an electrically conductive strip, which encircles the electrically non-conductive tank watermark tube.

Description

The invention relates to a water column sensor.

Currently, most inductive float sensors are used to sense the water level. However, these devices are relatively expensive. Even greater problems are with the installation of these devices. Three valves, respective pipes and welds on the expansion tank are required to connect the float chamber of the sensor to the expansion tank. Weldments on the pressure vessel, which is the expansion tank, can only be performed by companies designated for this purpose. It is always necessary to carry out a new inspection of the pressure vessel after each intervention in the pressure vessel. These sensors need regular maintenance. This means flushing the float chamber and adjusting the transistor relay. In addition, they are quite faulty, because sometimes it happens that the float stays hanging and the sensor does not work.

The above-mentioned drawbacks are eliminated by the connection of the water column sensor according to the invention, the essence of which consists in the output of the RC member connected to the input of the RF generator, the first output of which is connected to the second input of the NAND gate, the first input of which is connected to the supply terminal. the NAND gate is connected to the first terminal of the resistor, the second terminal of which is connected to the anode of the LED whose cathode is connected to ground, while the second output of the RF generator is connected via a coupling capacitor to the sensing probe, the second input of the NAND gate and to the first terminal of the resistor, the second terminal of which is connected to the supply terminal and to the first input of the NAND gate, the output of which is connected via a rectifier to the input of a switching transistor block to the output of which a relay is connected. In this case, the sensor probe can be formed by an electrically conductive strip with which the electrically non-conductive tube of the tank watermark is surrounded.

The main advantage of connecting a water column sensor is simple installation, as no intervention in the pressure vessel is required. Its weight is very low, about 0.2 kg, so the sensor can be prepared using a metal cable tie over a rubber pad directly on the glass tube of the watermark of the expansion tank. The metal strip also forms a probe. Other advantages are high reliability, low costs and minimal maintenance.

The attached drawing shows a block diagram of the water column sensor.

The output of the RC member 10 is connected to the second input of the HF generator 11, the first output of which is connected to the second input of the NAND gate 4, the first input of which is connected to the supply terminal, the NAND gate output 4 being connected to the first terminal of the resistor R4. is connected to the anode of the LED diode D2, the cathode of which is connected to ground, while the second output of the RF generator 11 ie the coupling capacitor C4 is connected to the sensing probe S, to the second input of the gate 3. NAND and to the first terminal of the resistor R5 the second terminal is connected on the one hand to the supply terminal and on the other hand to the first input of the gate 3. NAND, the output of which is connected via a rectifier 12 to the input of the block 13 of switching transistors, to the output of which the relay 14 is connected.

The high-frequency voltage generated by the RF generator 11 passes through the coupling capacitor C4 to the sensing probe S and at the same time to the input of the NAND gate 3, which evaluates the presence of RF voltage at the S sensing probe. rectified in the rectifier 12 and the relay 14 is closed by means of the block 13 of switching transistors. Information on the state of the water level is given via the contacts of the relay 14. Gate 4 NAND is used to signal the function of the RF generator 11. During operation, the D2 LED lights up and signals operation. Description of the function of the circuit used as a maximum water level sensor: If the water in the watermark on the expansion tank rises to probe S, it drains the RF voltage below the threshold voltage level of gate 3. NAND and relay 14 drop out and the maximum expansion level tanks.

In the idle state, ie when the water level is not at the sensing probe S, the RF voltage passes through the third gate 2 NAND and relay 14 is closed via the block 13 of switching transistors. It drops out in the event of a fault.

If the connection is used as a minimum level sensor, the switching contacts of relay 14 are used to report the fault condition. In the event of a fault, ie if the water disappears in the watermark, relay 14 is energized. The power supply for the connection and fault signaling is 24 V AC.

The water column sensor connection can be applied to any pressure expansion tank that has a watermark. It can be used as a minimum, operating and maximum water level sensor. It will also replace the Mertik import level sensor from the GDR.

Claims (2)

PATENT CLAIMS 1. Connection of a water column sensor, characterized in that the output of the RC member / 10 / is connected to the input of the RF generator / 11 /, the first output of which is connected to the second input of the gate / 4 / NAND, the first input of which is connected to the power supply terminal. , the gate output / 4 / NAND is connected to the first terminal of the resistor / R4 /, the second terminal of which is connected to the anode of the diode / D2 / LED, the cathode of which is connected to ground, while the second output of the RF generator / 11 / is via a coupling capacitor / C4 / connected on the one hand to the sensing probe / S /, on the one hand to the second gate input / 3 / NAND and on the other hand to the first terminal of the resistor / R5 /, whose second terminal is connected to the power supply terminal and to the first gate input / 3 / NAND , the output of which is connected via a rectifier / 12 / to the input of a block / 13 / of switching transistors, to the output of which a relay / 14 / is connected. 2. The circuit according to claim 1, characterized in that the sensing probe (S) is formed by an electrically conductive strip by which the electrically non-conductive tube of the tank watermark is surrounded.