RU113014U1 - DEVICE FOR DETERMINING PULSE LOSS OF ELECTRIC PULSING CURRENT MACHINES - Google Patents

Abstract

A device for determining the ripple losses of an electric machine of a pulsating current, containing a current converter with galvanic isolation, located in the power circuit of the tested electric machine; a rectifier unit with a smoothing reactor in the power circuit; a measuring shunt located in the armature power circuit of the tested electrical machine with a magnetoelectric ammeter; additional resistance with a magnetoelectric voltmeter; an adjustable resistor and an inductive shunt in the shunt circuit of the excitation windings of the engine and generator, a high-voltage direct current source, in the power circuit of which a smoothing reactor is located, characterized in that it additionally contains a voltage converter with galvanic isolation located in the power circuit of the tested electrical machine, and an analog-to-digital converter, the analog inputs of which are connected to the measuring outputs of the current and voltage converters, and the digital outputs are connected to the personal computer of the information-measuring system.

Description

The utility model relates to the field of instrumentation and can be used to determine the ripple losses of electrical machines.

It is known that ripple losses are determined using a small-sine electrodynamic wattmeter, the serial winding of which is connected to the secondary winding of an air current transformer (VTT), and the parallel winding is connected through a capacitor, which provides compensation for the phase measurement error. The primary winding of the VTT is connected in series to the motor power circuit. The measurement system, consisting of a power meter, VTT and a compensating capacitor, should be set up on an alternating current of frequency 100 Hz using a standard instrument with a standard current transformer according to clause 5.6.1 of GOST 2582-81 “Electric rotating traction machines”.

Closest to the technical nature of the proposed utility model, adopted as a prototype, is a device for determining ripple losses, containing a current transducer with galvanic isolation, located in the power circuit of the tested electric machine; a rectifier installation, in the power circuit of which a smoothing reactor is located; measuring shunt in the power circuit of the armature of the tested electric machine with a magnetoelectric ammeter; additional resistance with a magnetoelectric voltmeter; adjustable resistor and inductive shunt in the shunt circuit of the excitation windings of the engine and generator, a high-voltage direct current source in the power circuit of which a smoothing reactor is located (R.I. Alikin, A.G. Zakharov, A.I. Mikhailov, V.T. Mushta “Experimental determination of additional ripple losses and efficiency of traction electric motors of pulsating current.” Locomotive engineering. - vol. 17, p. 81-91).

The disadvantages of the known device include the following:

The use of VTT does not allow measuring the true values of alternating current flowing in the power circuit of the test object, because the readings of the ammeter connected to the measuring (secondary) winding of the VTT are conditional values of alternating current, determined according to the graduation of the VTT, which must be carried out on alternating current in conjunction with the type current transformer used, for example, I509. When calibrating the measuring complex, it becomes necessary to select a separation capacity for different measurement limits along the voltmeter circuit of the wattmeter. Since the ripple losses vary from several hundred watts to several tens of watts, with such a wide range of variation in the magnitude of the ripple losses, it is not possible to measure with a single current transformation coefficient, because for small values of the variable component of the ripple current, the readings of the low-sine wattmeter are insignificant. In this regard, it becomes necessary to use the I54M multi-limit measuring current transformer, which makes it possible to change the current transformation coefficient in a wide range. The calibration process with the selection of capacity is very laborious and reliable calibration is difficult to carry out. In this regard, the results on the determination of pulsation losses are obtained with an error. Since VTT is not a typical measuring device and is not included in the list of equipment and devices for metrological support, its use is impractical. Since the reliability of the values (measurement error) of the alternating current component in the power circuit of the tested object is unknown (the magnitude of the alternating current component is determined indirectly), a scheme for determining ripple losses using modern standard measuring instruments is proposed.

The objective of the utility model is to increase the accuracy and reliability of measuring the ripple losses of an electric machine, and reduce losses.

The problem is solved in that in a device for determining the ripple losses of a pulsating current electric machine, comprising a galvanically isolated current transducer located in the power circuit of the tested electric machine; a rectifier installation, in the power circuit of which a smoothing reactor is located; a measuring shunt located in the power circuit of the armature of the tested electric machine with a magnetoelectric ammeter; additional resistance with a magnetoelectric voltmeter; adjustable resistor and inductive shunt in the shunt circuit of the field windings of the engine and generator, a high-voltage direct current source in the power circuit of which a smoothing reactor is located, differences are introduced - it additionally contains a voltage converter with galvanic isolation located in the power circuit of the tested electric machine, as well as analog -digital converter, the analog inputs of which are connected to the measuring leads of current and voltage converters, and the digital leads are connected to a personal computer information-measuring system.

The technical result — obtaining reliable values of the ripple losses of the ripple electric machines — is achieved by measuring the total power consumed by the motor using modern measuring technology using current and voltage converters with galvanic isolation, for example, of the LEM type, with access to the information-measuring system.

The figure 1 shows a device for determining the ripple losses of electrical machines of a ripple current.

In figure 2 - instantaneous values of current and voltage.

In figure 3 - ripple losses of a traction motor type NB-520 V in nominal mode.

The device comprises (Fig. 1) a test electric machine 1, powered from a rectifier installation 2. A current converter 3 and a voltage converter 4 are installed in the power circuit of machine 1, which are connected to an information-measuring system 5 (IMS) containing an analog-to-digital converter 6 (ADC) and personal computer 7 (PC). In addition, a measuring shunt 8 with an ammeter 9 is located in the power circuit of machine 1, and a voltmeter 10 with an additional resistance 11 is connected to measure the voltage at the terminals of machine 1.

As a current transducer 3 and a voltage transducer 4, a current sensor of the LT1000 type and a voltage sensor of the LV100 type of compensation type, for example, LEM, are used. The voltage sensor 3 is connected to the windings of the machine 1 and 20 through the additional resistance 12, and to the ADC 6 through the load resistance 13, determined depending on the input voltage of the ADC channel 6. The current sensor is connected through the load resistance 14.

A smoothing reactor 15 with adjustable inductance is located in the power circuit of the rectifier installation 2 to change the ripple of the armature current in the power circuit of the machine 1. A smoothing reactor 17 is connected to the power circuit of the high-voltage direct current source 16 to prevent the AC component from penetrating from the installation 2, and to ensure thereby, reliable operation of the source 16 in the switching relation. To set the bypass of the main poles 18 of the engine 1 and the main poles 19 of the generator 12, an adjustable resistor 20 and an inductive shunt 21 are connected.

The operation of the device is as follows.

According to the mutual load scheme (Fig. 1), electric machines — engine 1 and generator 12 — are fed from power supply 2. After setting the current load mode, the machines are started 1.12 by applying voltage from power source 16. Then, the operating mode of motor 1 is set to on the clamps (control by voltmeter 10) and current load (control by ammeter 9), using an adjustable resistor 20 and an inductive shunt 21 of shunting the main poles 18, 19 of motor 1 and generator 12, respectively.

In a given mode, the instantaneous values of current and voltage from the converters 3 and 4 are recorded on the IIS 5, the curves of which are presented in figure 2.

As the ADC 6 use an external module type E14-440 manufactured by CJSC "L-Card". As a PC - a laptop with minimal requirements:

- Windows operating system (98, ME, 2000, XP, Vista);

- 32 MB of RAM;

- 50 MB of disk space.

Software (software) is installed on the PC, for example, "Power Graph" Version 3.3 (User Guide, Interoptics - since 2008), designed to register, visualize, process and store analog signals and which allows you to use the PC as standard measuring instruments.

Two physical channels of the ADC 6 are configured (input lines on the external connectors of the ADC, designed to connect two sources of analog signals - current sensors 3 and voltage sensor 4 to two logical channels used in the "Power Graph" to record data).

The registration frequency for the channels is set as high as possible to obtain the final result with the least error.

In a given mode, the signals from current transducers 3 and voltage 4 are fed to the IIS 5. Using the "Power Graph", instantaneous values of current and voltage are recorded.

The number N of recorded values of the ripple current and voltage in the period is determined. For a period, a period of time of at least ten function periods is taken.

Two more new logical channels are created with the calculated data: the current values of current and voltage, which are determined by the formula

where Y is the effective value of current or voltage,

T is the period

x ( t ) is a function of current or voltage versus time.

The current values of current and voltage are calculated using the statistical signal processing function:

where N is the sample size (in our case, N is the number of recorded values in the selected period),

x _j - instantaneous values of current or voltage (data of the source channel),

RMSPt (X; N) - function of statistical signal processing (function for calculating the rms value for a given number of points N),

X is the vector of instantaneous values x _j (X = [x ₁ , ..., x _N ]).

In the settings of the channels recorded current and voltage, for calibrating the input signals indicate the multiplication coefficient A, which is calculated by the formula

where Y ' is the value of current (or voltage) measured by ammeter 9 (or voltmeter 10),

Y is the effective value of the current (or voltage) recorded in the logical channel.

The calculated effective values of current and voltage should coincide with the values of current measured by ammeter 9 and voltage measured by voltmeter 10.

According to GOST 2582-81, clause 5.6.1, the ripple losses of the ripple current motors should be determined by measuring the total power consumed by the ripple motor and direct current P ₁ , at constant speeds and power at the terminals of the load generator.

Additional ripple losses should be taken equal

find how

where i ( t ) is the function of current versus time,

u ( t ) is a function of voltage versus time,

i _j , u _j - instantaneous values of pulsating current and voltage,

To find create another logical channel with a calculation algorithm resulting from the above formula:

1. Multiplication of source channels of instantaneous values of current and voltage p _j = i _j · u _j , j = 1, ..., K, where p _j are instantaneous power values, K is the number of all recorded values in the source channel.

2. Finding the smoothing function (averaging) of the Smooth signal where P is the vector of instantaneous values of P _j (P = [p _l , ..., p _N ]).

p ₁ is defined as

where U ₀ , I ₀ - constant components or arithmetic means for the period of voltage and current, respectively.

For this, two more new logical channels are created with the calculated data: constant components of current and voltage using the signal smoothing (averaging) function: for current - Smooth where I is the vector of instantaneous values i _j (I = [i ₁ , ..., i _N ]); for voltage - Smooth where U is the vector of instantaneous values u _j (U = [u ₁ , ..., u _N ]). Next, additional pulsation losses are found by formula (3).

The proposed device is used to determine the ripple losses in the department of electrical machines "All-Russian Scientific Research and Design Institute of Electric Locomotive" (OJSC "VELNII"). As an example, figure 3 shows the curve of the ripple losses of the traction motor type NB-520 V on the ripple factor of the armature current K _p .

The positive effect of the proposed device is that the use of current and voltage converters with galvanic isolation in the circuit of the tested object eliminates the use of a compensating capacitor and an air current transformer, which is not a typical measuring device, thereby significantly reducing the costs associated with the manufacture of VTT. The use of modern measuring instruments allows one to obtain reliable values of ripple losses.

Claims (1)

A device for determining ripple losses of an electric pulsating current machine, comprising a galvanically isolated current transducer located in a power circuit of a test electric machine; a rectifier installation, in the power circuit of which a smoothing reactor is located; a measuring shunt located in the power circuit of the armature of the tested electric machine with a magnetoelectric ammeter; additional resistance with a magnetoelectric voltmeter; adjustable resistor and inductive shunt in the shunt circuit of the field windings of the engine and generator, a high-voltage direct current source, in the power circuit of which there is a smoothing reactor, characterized in that it additionally contains a voltage converter with galvanic isolation located in the power circuit of the tested electric machine, and an analog-to-digital converter, the analog inputs of which are connected to the measuring leads of current and voltage converters, and the digital outputs are connected enes to the PC information and measuring system.