RU163664U1 - SENSOR TEST DEVICE - Google Patents

Abstract

A device for testing non-contact sensors of automatic switches of switchboard electric drives, comprising a transformer, a connector for connecting sensors, a control relay, a first voltmeter, control and indication elements, characterized in that the input of the transformer is connected to a voltage stabilizer, and a voltage switch, a toggle switch and a toggle switch are connected in series with the transformer output a variable resistor, with its output through an ammeter connected to the first voltmeter and the input of the connector for connecting sensors, and the input to the monitoring relay is connected to the output of the socket for connecting sensors and a second voltmeter.

Description

The utility model relates to the field of measurement technology and can be used to test the proximity sensors of DBL and DBP circuit breakers used in switchgear type SPGB-4B electric drives during their repair and preventive maintenance.

A known installation for measuring resistances by an indirect method (RU 43067 U1, IPC G01D 21/00, H01H 73/00, Н02Н 3/10, publ. 12/27/2004), in particular, by the method of an ammeter and voltmeter, when measuring small resistances, containing a source direct current, current regulator, ammeter, voltmeter and measured load, in which the battery is a direct current source, and the current regulator is made in the form of an electronic circuit containing a regulating element.

However, such an installation, designed to measure the resistance of the windings of electrical machines during their testing, has limited functionality and cannot be used to control the electrical characteristics of proximity sensors.

A known layout for testing proximity sensors of a DBL, DBP type auto-switch (Information sheet No. Ш13 (3018), October Center for Scientific and Technical Information and Libraries, St. Petersburg, 2014), containing an SPGB type drive, an auto-switch with sensors, a step-down transformer, a resistor for adjusting the supply voltage of the sensors from 20 V to 28 V and a block for measuring the output voltage.

The disadvantage of this device is the low accuracy and incompleteness of the test due to the lack of measuring instruments and instability of the supply voltage.

Closest to the claimed device is a stand for checking and adjusting proximity sensors such as DBP, DBL (Information card No. 3226, South Ural Center for Scientific and Technical Information and Libraries, 2009), containing a housing inside which a step-down transformer is installed to generate 24 V voltage , a socket for connecting sensors, a control relay that serves as a load, an indicator light, a toggle switch to turn on the power of the device, a voltmeter for measuring the voltage at the output of the sensor.

The main disadvantages of the device are the lack of an ammeter for monitoring current and a device for measuring the voltage at the input of the sensor, which leads to insufficient information determining the suitability of the sensor, as well as low measurement accuracy due to instability of the supply voltage and the use of an analog device.

The utility model is aimed at improving the quality of sensor verification, including by reducing the influence of the human factor and increasing the usability of the device.

The technical result consists in increasing the accuracy and completeness of measuring the parameters of the sensors.

The specified result is achieved by the fact that in the device for testing sensors containing a transformer, a connector for connecting sensors, a monitoring relay, a voltmeter, control and indication elements, the input of the transformer is connected to a voltage stabilizer, a voltage switch, a toggle switch and a variable resistor are connected in series with the transformer output, its output through an ammeter connected to the first voltmeter and the input of the connector for connecting sensors, and the input of the control relay is connected to the output of the connector for sensors and a second voltmeter.

The introduction of a stabilizer eliminates the influence of instability of the supply voltage.

Due to the presence in the device of an ammeter for monitoring current, as well as an additional voltmeter at the input of the sensor, the accuracy and completeness of measuring the input and output characteristics of the sensor, determining its suitability, are increased.

The technical result is also achieved by the fact that the voltage switch makes a rough installation of one of the three required voltages at the input of the sensor, and a more accurate value of the input voltage is set with a variable resistor.

All devices mounted on the front panel of the device are made on a modern digital element base, which allows to reduce the influence of the human factor by reducing the number of operator errors and thereby improve working conditions. Placing on the front panel of a table with electrical parameters of contactless sensors also contributes to increased convenience when working with the device.

In FIG. 1 shows a General view of the proposed device; in FIG. 2 - table of electrical parameters of proximity sensors DBL, DBP; in FIG. 3 is a functional diagram of a device for testing sensors; in FIG. 4 is a general view of the front panel of the control cabinet.

A device for testing sensors (Fig. 1) comprises a control cabinet 2 mounted on a table 1 with a front panel 3, on which electrical measuring instruments, control elements and indication elements in the form of lamps are placed. The contactless sensor 4 to be tested is placed on the table with the possibility of electrical connection with the control cabinet 2.

A voltage regulator 5 is mounted in the control cabinet (Fig. 3), the output of which is connected to the input of the transformer 6. The latter is connected by its outputs to the inputs of the voltage switch 7. A variable resistor 9 is connected to the output of the voltage switch through the toggle switch 8. This resistor exits through an ammeter 10 connected to the first voltmeter 11 and, through the input of the connector 12 for connecting sensors, with the input of the tested proximity sensor.

The output of the proximity sensor through the output of the connector 12 is connected to the second voltmeter 13 and the input of the control relay 14 installed in the control cabinet. In this case, the contacts of the control relay 14 are connected to the corresponding lamp "Control relay" (Fig. 4), which is included in the group of indication elements 15, and the “Network” lamp, which serves to indicate the supply voltage, is connected to the input of the voltage stabilizer 5 (Fig. 3). The rest of the display elements in the form of lamps "20 V", "24 V", "28 V" (Fig. 4), is connected to the voltage switch 7.

Thus, on the front panel 3 (Fig. 4), the following display controls are placed: voltage switch 7 "Select input voltage", toggle switch 8 "Sensor power", variable resistor 9 "Voltage accurately", measuring current consumption ammeter 10, measuring the input voltage is the first voltmeter 11, the connector 12 for connecting sensors, measuring the output voltage of the second voltmeter 13, the display elements 15 in the form of lamps "Network", "20 V", "24 V", "28 V", "Control relay", and also table 16 of the electrical parameters of proximity sensors at.

In this example, the device used electrical meters in the form of an ammeter CA 3020-1 and voltmeters MT4W-AV-44 from the company "Autonics".

The device operates as follows.

To the connector 12 on the front panel 3 (Fig. 3, 4) connect the test proximity sensor.

After turning on the device, the input mains voltage is supplied to the “Network” lamp, which is part of the group of indication elements 15, and to the stabilizer 5 (Fig. 3), from which the stabilized voltage is supplied to the input of the transformer 6.

The converted voltages from the secondary winding of the transformer are supplied to a voltage switch 7, from the output of which the selected voltage is supplied to one of the lamps "20 V", "24 V", "28 V" (Fig. 4) of the group of indication elements 15. The same voltage is supplied through the toggle switch 8 "Sensor Power" (Fig. 3, 4), to a variable resistor 9, which serves to fine-tune the voltage. With a variable resistor 9, the signal, passing through the measuring current ammeter 10, is fed to control the input voltage to the first voltmeter 11 and to the input of the connector 12 for connecting the test sensor. The output voltage of the sensor from the output of the connector 12, measured by the second voltmeter 13, is supplied to the input of the control relay 14, which is the load of the sensor, and turns on the “Control relay” lamp (Fig. 4) with its contacts.

The parameters of the sensor are taken at three positions of the voltage switch 7 (20 V, 24 V, 28 V) and three positions of the rotor sector of the sensor (0 °, 60 °, 120 °). The measurement results should correspond to the table in FIG. 2.

Claims (1)

A device for testing non-contact sensors of automatic switches of switchboard electric drives, comprising a transformer, a connector for connecting sensors, a control relay, a first voltmeter, control and indication elements, characterized in that the input of the transformer is connected to a voltage stabilizer, and a voltage switch, a toggle switch and a toggle switch are connected in series with the transformer output a variable resistor, with its output through an ammeter connected to the first voltmeter and the input of the connector for connecting sensors, and the input to the monitoring relay is connected to the output of the socket for connecting sensors and a second voltmeter.

Images