RU70002U1 - PORTABLE INSTRUMENT MULTI-FUNCTIONAL CONTROL AND MEASURING - Google Patents

Abstract

The utility model relates to measuring equipment and can be used in the commissioning, repair and maintenance of electric motors. The portable device consists of a housing 1, on the front panel of which a microammeter 2 is installed; operation mode selection switch 3; switch 4 for supplying voltage to the device; indicator 5 of the presence of voltage on the device; engine 6 in the form of a resistor; indicators 7 and 8; winding phasing switch 9; thyristor (triac) connection terminals AN, Y, K; the terminals for connecting the housing and motor windings are A, B, C, N. The device operates both from a ~ 220 V power source and from galvanic cells. The electrical circuit of the device consists of the following units: I - power supply; II - the block of the master oscillator, III - block delay circuit; IV - power amplifier unit; V - block of the output transformer; VI - voltage doubling unit; VII - block indicating the state of the thyristor (triac); VIII - block of measurements. The device operates in 4 modes: measuring the thyristor (triac) opening current, measuring the thyristor (triac) opening voltage, measuring the insulation resistance of the motor windings relative to the housing, phasing the motor windings

Description

The utility model relates to measuring equipment and can be used in the commissioning, repair and maintenance of electric motors.

In the process of carrying out these works, it becomes necessary to check for proper functioning and select thyristors (triacs) (in pairs) to protect the power circuits of the electric motor by the identity of the currents and switching voltages; and also there is a need to verify the correct phasing of the motor windings and measure the insulation resistance of the windings.

A search by sources of patent information and scientific and technical literature showed that no portable search was found that would allow performing the indicated functions with the help of a single device during repair, commissioning and maintenance of the electric motor. A portable device not only accelerates the performance of these works, but also provides qualified maintenance.

The technical result achieved by the claimed utility model is to increase the reliability of the electric motor due to protection against overvoltages that occur in the motor excitation winding at start-up, as well as providing the necessary starting torque.

The essence of the utility model as a technical solution lies in the fact that the portable multifunctional instrumentation,

consisting of a power source, a housing on which a microammeter, control and monitoring elements, indicators, a slider in the form of a resistor, connection terminals, as well as a power supply unit (I), a driver unit (II), a delay circuit unit (III) are installed, power amplifier unit (IV), output transformer unit (V), voltage doubling unit (VI), thyristor (triac) indexing unit (VII) and measurement unit (VIII), while the output of the power unit (I) is connected via resistor R18 to the midpoint of the primary winding of the output transformer T2 bl output transformer (V), the secondary winding of which is connected to the on-off switch SA3 of the measuring unit (VIII), which on the other hand is connected to the contact SA1.1 of the four-position switch SA1, which is connected through the microammeter PA1 to the contact SA1.2, which through the resistance R15 , capacitor C9, diode VD9 is connected to terminal “B”, switch SA3 is connected to terminal “A” and terminal “C”, and terminal N is grounded, while the variable resistor R16 of the power supply (I) is connected through resistor R19 to terminal SA1. 1 switch unit SA1 (VIII) and simultaneously with terminal “Y” and through diode VS1 with terminals “K” and “A”, through terminal “A” the measurement unit (VIII) is connected to resistors R17 and R20 and indicators HL2 and HL3 of the thyristor status display unit (triacs) (VII), the output of which is connected to the winding IV of the output transformer T2 of the block of the output transformer (V), and the winding Ш of the transformer T2 is connected on one side through diodes VD8, VD10, resistance R14, with terminal SA1.2 of the switch SA1 of the measurement unit (VIII), and on the other hand is connected to the capacitor C7 of the voltage doubling unit (VI), while projections 1a, 1b of the primary winding of transformer T2 I output connected to power amplifier unit (IV) through the diodes VD5, VD6, terminals

transistors VT5, VT6, transistors VT3 VT4; resistors R8-R11 and elements DD1.3, DD1.4 of the DD1 chip with a delay unit (III), which, in turn, is connected through capacitors C3, C4, diodes VD2, VD3, resistors R4, R5 to the unit of the master oscillator (II ), through its resistors R1-R3, elements DD1.1, DD1.2 of the chip DD1, capacitor C1 and transistor VT1.

In addition, the device can use four galvanic cells as a power source, which makes it possible to use it in the field.

The utility model is illustrated by the figures of the drawings, where in Fig.1 shows a General view of the device; figure 2 - block diagram of the device; figure 3 is an electrical diagram of the device.

The portable device consists of a housing 1, on the front panel of which a microammeter 2 is installed; operation mode selection switch 3; switch 4 for supplying voltage to the device; indicator 5 of the presence of voltage on the device; engine 6 in the form of a resistor; indicators 7 and 8; winding phasing switch 9; thyristor (triac) connection terminals AN, Y, K; the terminals for connecting the housing and motor windings are A, B, C, N. The device operates both from a ~ 220 V power source and from galvanic cells.

The electrical circuit of the device consists of the following blocks:

I - power supply unit; II - the block of the master oscillator, III - block delay circuit; IV - power amplifier unit; V - block of the output transformer; VI - voltage doubling unit; VII - block indicating the state of the thyristor (triac); VIII - block of measurements.

The basis of the device is a voltage converter, consisting of a master oscillator (block II), a power amplifier (block IV), the load of which is the output transformer (block V).

Between the block of the master generator (II) and the block of the power amplifier (IV), a block of the delay circuit (III) is installed, made on diodes

VD2, VD3, resistors R4, R5 and capacitors C3, C4. This block is necessary, because in its absence, a situation arises in which the transistors of the upper (according to the circuit) arm of the power amplifier unit have not yet closed, and the transistors of the lower arm have been opened by the control pulse of the master oscillator. As a result, a through current flows through the terminal transistors VT5, VT6, which causes the failure of these elements.

The output transformer contains four windings. The primary winding, consisting of two sections (1a, 1b) is the load of the power amplifier. Winding II is a source of alternating voltage when checking the correct inclusion of the windings of a three-phase electric motor. Winding III, loaded on a voltage doubling circuit (block VI), is necessary to measure the insulation resistance between the windings and the motor housing. Winding IV provides a mode for measuring the voltage and current of opening the thyristor.

The measurement unit (block VIII), which is part of the device, in the "F" mode acts as an alternating voltage voltmeter, in the "megohm" mode it is a megaohmmeter, in the "current" mode it is a milliammeter, in the "eg" mode it is a DC voltmeter .

The power supply unit (block I), which supplies voltage to the device, is also a source of voltage and current when measuring the parameters of thyristors (triacs).

To reduce the size and lower power consumption from the power source, a converter with a voltage of increased frequency 300-400 Hz is installed in the device.

The master oscillator is assembled on the transistor VT1 and two elements DD1.1, DD1.2 of the chip DD1. The generator frequency is set by the trimming resistor R3, the pulse duration is determined by the chain C1, R2, pauses between control pulses of different shoulders

power amplifiers needed to protect the output transistors VT5, VT6 are created by the chains VD2, R4, C3 and VD3, R5, C4.

On the elements DD1.3 and DD1.4 of the chip DD1 are assembled control pulse shapers of the final stage of the power amplifier. Diodes VD6, VD7 are necessary to eliminate the influence of the self-induction EMF arising in the primary winding of the transformer Tr2 in the pauses between the control pulses.

The alternating voltage removed from the secondary winding (IV) of the output transformer of the power amplifier is applied to the terminals "AN" and "K" of the device, respectively, to the anode and cathode of the tested thyristor (triac). To open the thyristor (triac) it is necessary to apply a constant voltage of a certain value between the control electrode and the cathode, for which the voltage of the power supply unit is used. When the resistor R16 engine moves from the upper (according to the scheme) position to the lower, the DC voltage increases until the thyristor VS1 opens. As a result, pulses of positive polarity are allocated on the resistor R20, which, in turn, will be the power source for the HL3 LED (on the front panel of the device there is indicator 7, the glow of which indicates that the thyristor is open). If the triac is connected to the device, the resistor R20 will highlight all the alternating voltage taken from the winding of the IV output transformer, which will cause the LEDs HL2, HL3 to glow (on the front panel of the device these are indicators 7 and 8).

For the operation of the megaohmmeter, the voltage from the winding III is used, which is rectified and doubled by elements C7, VD8, VD10, C8.

When checking the correct connection of the windings of a three-phase electric motor, the voltage of the winding II of the output transformer is used.

The device operates in 4 modes, so the operation of the device is considered for each mode separately.

The operating mode is “measuring the thyristor (triac) opening current.” The measured thyristor (triac) is connected with the anode to the terminal “AN”, the control terminal is connected to the terminal “Y”, the cathode is connected to the terminal “K”.

On the front panel of the portable device, the switch 3 is set to the "current" position, the engine 6 is turned clockwise until it stops, the switch 4 is set to the "ON" position, the indicator 5 of the voltage on the device lights up; slowly turn the engine 6 counterclockwise until the indicator 7 lights up, indicating that the thyristor is in front of us, at the moment the indicator lights up, the engine 6 stops rotating and the current values for the thyristor are recorded according to the readings of microammeter 2. If indicators 7 and 8 light up at the same time, therefore this is a triac, record the readings of the microammeter for the triac, after which the portable device is turned off. As a result, the thyristors are separated from the triacs and, accordingly, they are selected according to the opening current.

The operating mode is "measuring the opening voltage of the thyristor (triac)."

On the front panel of the portable device, the switch 3 is set to the “for example” position, the engine 6 is turned clockwise until it stops, the switch 4 is set to the “ON” position, the indicator 5 for voltage presence on the device lights up; slowly turn the engine 6 counterclockwise until the indicator 7 lights up, indicating that we have a thyristor; when the indicator 7 lights up, the engine stops rotating and the voltage value for the thyristor is recorded according to the readings of the microammeter 2. If the indicators 7 and 8 light up at the same time, therefore we have a triac, the readings of the microammeter for the triac are recorded,

then the portable device is turned off. As a result, the thyristors are separated from the triacs and selected according to the opening voltage.

The operating mode is “measuring the insulation resistance of the motor windings relative to the housing”.

The motor housing is connected to the “N” terminal on the portable device, the measured winding is connected to the “A” terminal, switch 3 is set to “mOhm”, switch 4 is set to “ON”, indicator 5 lights up, indicating voltage is present on the device; record the number of divisions by the position of the arrow of the microammeter. The insulation resistance values in megohms with respect to the number of scale divisions are given in the table below. The handheld device is turned off.

Number of divisions one hundred 92 80 72 58 42 32 "R" mOhm 0.5 one 2 3 5 10 twenty

The operating mode is “phasing of the motor windings”.

The motor windings are connected by a star, the ends of the windings are connected together and connected to the terminal of the portable device "N"; the beginning of the windings is connected as follows: winding A to terminal “A” of the portable device, winding B to terminal “B”, winding C to terminal “C”. Switch 3 is set to "F" position, switch 9 to "A-B" position, switch 4 is set to "ON", indicator 5 lights up, indicating the presence of voltage on the device.

If the arrow of microammeter 2 deviates from the zero mark, this means that winding A is not turned on correctly with respect to winding B; it is necessary to start and end the winding A to interchange.

Turn switch 9 to position “B-C”, if the needle of the microammeter deviates from the zero mark, this means that winding C is switched on incorrectly with respect to winding B; it is necessary to start and end the winding C to interchange. The handheld device is turned off. If the motor windings are connected correctly, then the microammeter needle does not deviate.

Thus, the claimed portable device allows you to perform several functions: check the correct phasing of the motor windings, measure the insulation resistance of the windings, and check for correct operation and select (in pairs) thyristors (triacs) based on the identity of currents and voltages that are installed in the motor overload protection circuits. The device allows for the commissioning, start-up and technological maintenance of a three-phase electric motor both in stationary conditions and in field conditions.

Claims (2)

1. A portable multifunctional control and measuring device, characterized in that it contains a housing on which a microammeter, control and monitoring elements, indicators, a slider in the form of a resistor, connection terminals are installed, and also includes a power supply unit (I), a driver unit (II) ), delay circuit unit (III), power amplifier unit (IV), output transformer unit (V), voltage doubling unit (VI), thyristor (triac) indexing unit (VII) and measurement unit (VIII), power supply output (I) through resistor R18 connected to the medium days to the point of the primary winding of the output transformer T2 of the output transformer unit (V), the secondary winding of which is connected to the on-off switch SA3 of the measuring unit (VIII), which on the other hand is connected to the contact SA1.1 of the four-position switch SA1, which is connected through the microammeter PA1 to the contact SA1 .2, which through resistance R15, capacitor C9, diode VD9 is connected to terminal "B", switch SA3 is connected to terminal "A" and terminal "C" ", and terminal N is grounded, while the variable resistor R16 of the power supply (I) connected to I cut the resistor R19 with the SA1.1 contact of the switch SA1 of the measurement unit (VIII) and simultaneously with the terminal "Y" and through the diode VS1 with the terminals "K" and "A", through the terminal "A" the measurement unit (VIII) is connected to the resistors R17 and R20 and indicators HL2 and HL3 of the thyristor (triac) status display unit (VII), the output of which is connected to the winding IV of the output transformer T2 of the output transformer unit (V), and the winding Ш of the transformer T2 is connected on one side through diodes VD8, VD10, resistance R14, with contact SA1.2 of the switch SA1 of the measuring unit (VIII), and on the other hand is connected to with a capacitor C7 of the voltage doubling unit (VI), while sections 1a, 1b of the primary winding I of the output transformer T2 are connected to the power amplifier unit (IV) through diodes VD5, VD6, terminal transistors VT5, VT6, transistors VT3 VT4; resistors R8-R11 and elements DD1.3, DD1.4 of a chip DD1 with a delay unit (III), which, in turn, is connected via capacitors C3, C4, diodes VD2, VD3, resistors R4, R5 to the unit of the master oscillator (II ), through its resistors R1-R3, elements DD1.1, DD1.2 of the chip DD1, capacitor C1 and transistor VT1. 2. The device according to claim 1, characterized in that four galvanic cells are installed as a power source, which makes it possible to use the device in the field.