RU2010134445A - VIBRATION METER FOR EXTREME OPERATING CONDITIONS - Google Patents

Abstract

 1. An electric charge meter containing an input operational amplifier, a first and second parallel RC circuit and an inverter, the input of which is connected to the output of the input operational amplifier, while the first parallel RC circuit is connected between the inverting input of the input operational amplifier and the input of the inverter, and the second parallel RC circuit - between the non-inverting input of the input operational amplifier and the output of the inverter, while the output of the input operational amplifier is the output of the electric charge meter, which is connected in parallel to the first and second parallel RC circuits in the input circuit of the input operational amplifier through isolation capacitors, and at the output galvanically, two groups of k circuits, each of which consists of a first electronic key, a capacitor and a second electronic key, and to the output of the capacitor, which is connected to the second electronic key, a resistor connected to the ground is connected. ! 2. The electric charge meter according to claim 1, characterized in that parallel to the first and second parallel RC circuits are connected in the input circuit of the input operational amplifier through the aforementioned isolation capacitors, and galvanically, the output is two groups of m chains, each of which consists of from a series-connected first electronic key, a resistor and a second electronic key, and to the output of the resistor, which is connected to the second electronic key, is connected a resistor connected to the ground through a condenser Op. ! 3. The electric charge meter according to claim 1, characterized in

Claims (4)

1. An electric charge meter containing an input operational amplifier, a first and second parallel RC circuit and an inverter, the input of which is connected to the output of the input operational amplifier, while the first parallel RC circuit is connected between the inverting input of the input operational amplifier and the input of the inverter, and the second parallel RC circuit - between the non-inverting input of the input operational amplifier and the output of the inverter, while the output of the input operational amplifier is the output of the electric charge meter, which is connected in parallel to the first and second parallel RC circuits in the input circuit of the input operational amplifier through isolation capacitors, and at the output galvanically, two groups of k circuits, each of which consists of a first electronic key, a capacitor and a second electronic key, and to the output of the capacitor, which is connected to the second electronic key, a resistor connected to the ground is connected. 2. The electric charge meter according to claim 1, characterized in that parallel to the first and second parallel RC circuits are connected in the input circuit of the input operational amplifier through the aforementioned isolation capacitors, and galvanically, the output is two groups of m chains, each of which consists of from a series-connected first electronic key, a resistor and a second electronic key, and to the output of the resistor, which is connected to the second electronic key, is connected a resistor connected to the ground through a condenser Op. 3. The electric charge meter according to claim 1, characterized in that between the outputs of the sensor and the input circuit of the input operational amplifier, two groups of n circuits switched simultaneously, and each of which consists of a series-connected electronic key and a resistor, are connected through the said isolation capacitors. 4. The electric charge meter according to claim 1, characterized in that, in order to obtain maximum suppression of pyroelectric interference, the values of the resistors in the first and second parallel RC circuits and isolation capacitors together with a resistor connected in series with it are selected in a certain ratio to each other , the value of the resistors divided by the root of two in the first and second parallel RC circuits should be equal to the value of the separation capacitance multiplied by the value of the resistor connected in series with it and doubled value of the capacitance from the first and second parallel RC circuits, multiplied by the root of two and the ratio of resistors connected to the electronic key and the resistor connected in series with the isolation capacitor in each of two groups of n circuits switched simultaneously.