RU2531850C1 - Method to measure resistance to dc in windings of electric equipment - Google Patents

Abstract

FIELD: measurement equipment.

SUBSTANCE: invention relates to the field of electric measurements of resistances in active-inductive circuits. The method consists in the fact that stabilised DC is sent via the serially connected winding and a reference resistor, and the DC value is calculated on the basis of preliminary measurement of the winding resistance. They measure voltage drops on the winding and reference resistor, and their ratio is calculated, to produce a sought-for winding resistance. Besides, in the process of current growth in the winding to the rated current they increase voltage of the current stabiliser power supply to the maximum, and after setting the current as equal to the rated they reduce this voltage. At the same time at the moment of the winding current equality to the rated current, they set the speed of current variation as many times less than the speed before this moment.

EFFECT: reduction of the resistance measurement time.

5 dwg

Description

The invention relates to the field of electrical measurements, in particular to measuring the active resistance of the windings of various electrical equipment, for example: transformers, reactors, reactors, electric motors, electric generators, electromagnets, etc. The invention can be used in energy during commissioning, preventive and repair work on electrical equipment, as well as at manufacturers of such equipment.

GOST 3484.1-88 recommended a method for measuring the direct current resistance of the windings of power transformers, which consists in passing a direct current from a constant voltage source through a winding and an ammeter, and characterized by a measuring transient process in which the current in the winding and the voltage on it change simultaneously according to a nonlinear law, as shown in FIG. Measurement of current and voltage to calculate the resistance in the winding is possible only after the establishment time t _{mouth of} their values: t _mouth ≈4.6 · τ when setting the current and voltage with an error of δ = -1% and t _mouth ≈9.2 · τ at δ = -0.1%, where τ is the transformer time constant equal to: τ = L _rpm / R _rpm .

Due to the long measurement time by this method, in most modern instruments of this purpose, it is not a voltage source that is used, but a current source - a compensating type DC stabilizer.

Known, for example, “Resistance Meter PFI-10R” (manufacturer LLC NPF INFOCHROM-99, Moscow. Description of the device on the site www.infochrom.ru). In accordance with the block diagram of the device, it uses a method according to which a constant constant current is passed through a winding and a reference resistor, first they wait for the current strength in the winding to reach the given setpoint current t _mouth , and then the winding voltage will be established (analog-to-digital converter 1 ) and on a reference resistor (analog-to-digital converter 2), and their ratio is calculated, based on which the desired winding resistance is obtained. Graphs of the processes in question are depicted in figure 2.

Thus, the replacement of the voltage source by the current source led to the separation of parallel processes of establishing voltage and current into two successive stages: at the first stage, the voltage on the winding is maximum and almost unchanged, and so in the winding it increases to the current setting of the current stabilizer; at the second stage, the voltage decreases from the maximum value to a drop on the winding I _set · R _rm , and the current is set almost equal to the set current, but continues to be established finally.

In this method, the time for the current to reach the specified current I _{mouth is} significantly reduced by eliminating its last part with a very low rate of change of current strength, but the second stage was added.

The consequence of the method is the division of the entire range of resistance measurements into several subbands with a tenfold ratio of resistances at the ends of each subband and a constant current strength within the subbands. This leads to the following disadvantages:

- on the full scale of the measured resistances, there are several sections according to the number of subbands with increased measurement error at the beginning of each subband;

- tenfold change in the ratio of the useful signal to interference at the edges of the subranges when measuring the resistances of transformers at a high-voltage substation under interference conditions;

- a tenfold increase in power dissipation on the current stabilizer at the beginning of each subband, when the measured resistance is still small.

Another disadvantage of the method is still a large measurement time, especially with high-power power transformers, reaching tens of minutes.

As a prototype closest to the claimed one, the method implemented in the invention “Device for measuring the active resistance of the windings of electrical equipment” (RF patent No. 2480774, class G01R 27/08, published in Bull. No. 12, 2013) was selected.

The method consists in passing a constant constant current through a winding and a reference resistor, the value of which is calculated based on a preliminary measurement of the resistance of the winding, measuring the voltage drop across the winding and the reference resistor, and calculating their ratio, based on which the desired resistance of the winding is obtained. In addition, at the first stage, while the current in the winding rises to the calculated current, the supply voltage of the current stabilizer is increased to reduce the duration of the stage due to an increase in the rate of change of current, and at the second stage, when the current in the winding is almost equal to the calculated current, but continues finally installed, reduce it to reduce the power dissipation on the regulating transistor of the current stabilizer. Graphs of changes in current and voltage in the winding coincide with similar graphs shown in figure 2 for the previous invention.

Preliminary knowledge of the estimated value of the measured resistance allows you to calculate and set for each measured resistance the maximum possible current strength, limited only by the power of the current stabilizer. This eliminates the three listed disadvantages of the previous method. But there remains a serious drawback of the method used in the prototype - a large measurement time.

The objective of the invention is to reduce the duration of the second stage, as well as the duration of the first stage, but without increasing the duration of the second stage, and thereby reducing the duration of the measurement as a whole.

To determine the reasons that impede the reduction of the measurement duration, it is necessary to consider the operation of the compensation current stabilizer. The current regulator mismatch amplifier amplifies the difference Δi = I _set -i (t) between the set current and the changing winding current and controls the regulator regulator transistor.

At the first stage, this difference is large and the transistor is fully open. Therefore, all voltage from an adjustable voltage regulator is applied to the winding, distributed between the resistance and inductance of the winding as follows: U _rm = E = i (t) · R _rm + L _rm · di / dt, where di / dt is the derivative or the rate of change of current .

When i (t) = I _{mouth, the} amplifier sets such a voltage at the control input of the transistor that a current equal to I _{mouth is established} . And since the current stops changing, that is, di / dt = 0, then the voltage across the winding should become equal to: U _obm = I _set · R _obm .

But due to the inertia of the amplifier and the transistor, as well as when the loop stabilizer current is not large enough, the control signal is delayed and the actually set current will be slightly higher than the current I _set , so at the second stage it continues to slowly change until it is completely established. A changing current induces a voltage across the winding, which is also slowly set. When reducing the time of the first stage by increasing the rate of change of current, the delay of the control signal becomes even greater and the actually set current is even more different from the current I _set , which increases the duration of the second stage.

The inertia of the nodes of the current stabilizer can be reduced using faster elements, but there are not only technical limitations, but also limitations associated with the need to ensure the stability of a closed system of automatic control with deep negative feedback, which is the compensation current stabilizer. Such a system will be stable and will not self-excite if the phase shift due to the inertia of the amplifier does not reach 180 ° at all frequencies in the pass band of the current stabilizer, at which its loop gain exceeds unity; that is, it is necessary to limit both the gain and speed of the current stabilizer. Therefore, this problem is not solved technically.

The solution is achieved by the fact that in the method of measuring the direct current resistance of the windings of electrical equipment, which consists in passing a constant constant current through the winding and a reference resistor, the value of which is calculated based on a preliminary measurement of the winding resistance, measuring the voltage drop across the winding and the reference resistor and calculate their ratio, on the basis of which the desired resistance of the winding is obtained, moreover, at the time of the current rise in To the coil, to the calculated current value, maximize the voltage of the current stabilizer, and after setting the current to the calculated one, reduce this voltage, additionally slow down the rate of change of current by the moment of equal current in the winding and the calculated current by several times compared with the rate of change of current before this moment.

The technical effect is achieved due to the fact that the lower the rate of change of current in the winding compared to the rate of change of the control signal at the input of the regulating transistor of the current stabilizer, the smaller the current will change during the delay time of this signal. So there will be a more accurate actual setting current setting I _set . Therefore, the final establishment of current and voltage will be faster to complete, and the second stage will be shorter. And since now the rate of change of current in the winding at the time of comparison with the setpoint current does not depend on the rate of change at the first stage, it is possible to increase the rate of change of current at the first stage to reduce its duration without any effect on the duration of the second stage.

Thus, the proposed method allows to reduce the duration of both stages independently of each other and to reduce the total measurement time.

The novelty of the proposed method, distinguishing it from the prototype method, is the deliberate deceleration of the rate of change of current in the winding by the time of its equality to the rated current of the stabilizer setting. The means for this in this invention was chosen to regulate the voltage supply of the current stabilizer.

Figure 3 shows graphs of the establishment of current and voltage in the process of measuring resistance by the proposed method.

Figure 4 shows the experimental graph of changes in the measurement error of the resistance of the winding relative to the steady-state value for the prototype method.

Figure 5 shows a similar graph, but for the proposed method.

As follows from the graphs shown in figure 3, an intermediate stage with a low rate of current change is formed from time t ₁ when the supply voltage of the current stabilizer decreases from the maximum value of E ₁ at the first stage to the required value of E ₂ . In this case, the current value of the rate of change of current (di / dt) ₁ at time t ₁ decreases to the required value (di / dt) ₂ . Modern switching adjustable stabilizers operate at high modulation frequencies, so the time Δt of switching to a new voltage value is only tens of milliseconds.

Find the formula for calculating the required value of E ₂ . For an LC circuit connected to a voltage source E ₁ at time t ₁ , the Kirchhoff equation is valid:

We determine from (1) the inductance value:

Assuming that for such a short time Δt of the establishment of voltage E _{2 the} values of i ₁ and L are practically unchanged, we rewrite expression (1) for the time t ₂ = t ₁ + Δt in the following form:

and substitute expression (2) into it. As a result, we get:

From the expression (4) it follows that to reduce the rate of change of current by several times, it is necessary to reduce the ratio between the voltage drop across the inductance U _L = (E ₁ -i ₁ · R) and the voltage drop across the resistance U _R = i ₁ · R by so much same time.

In this case, the ratio decreases due to a decrease in U _L (at a constant U _R ) due to a decrease in E ₂ . Figure 1 clearly shows how, when the ratio between U _R and U _L changes, the current and its rate of change change, but here E = const.

In the practical implementation of the proposed method for determining the required voltage value E _2, the quantities are measured: E ₁ , i (t), di / dt, and L and then E _{2 are} calculated from them. The maximum allowable speed value (di / dt) ₂ at an intermediate stage is determined by the actual speed of the current stabilizer and the smallest time constant of the windings of the controlled equipment.

If the value (di / dt) ₂ is chosen too small, this will not interfere with the functioning of the method, but will only slightly increase the duration of the intermediate stage. Its duration can be adjusted by setting the moment t ₁ in the range of values i (t ₁ ) = I ₁ = (0.9-0.99) · I _set .

The method was tested in a prototype of the device on a power transformer TDTN 31500/110. For the second stage, steady-state current and voltage values were recorded, the winding resistance values were calculated from them, and then, for clarity, they were converted into error values of the resistance measurement relative to the steady-state value and graphs were constructed based on them. Figure 4 shows a graph of measurement by the method of the prototype, without an intermediate step, and figure 5 is a graph of measurement by the proposed method. Delays of 3 from the beginning of the graphs are caused by a delay in the digital filter, which averages the instantaneous measurements for 3 s.

It has been experimentally proved that the proposed method reduces the time of the second stage, determined by the time of establishing the resistance of the winding with an error of δR = 0.05%, from t _mouth = 24 s to t _mouth = 1.0 s, that is, more than an order of magnitude.

The experiment was not performed for the first stage, since, on the one hand, it is obvious that the degree of decrease in its duration is determined exclusively by the limiting values of the voltage E ₁ and the power of the adjustable voltage stabilizer, and on the other hand, the influence of the current rate of change at the first stage on the duration of the second stage basically excluded in the proposed method, as shown above. This exception occurs automatically by constantly monitoring the rate _of change (di / dt) _{1 of} the current change in the first stage, no matter how it is increased by increasing E ₁ , and the corresponding decrease in the rate of change of current (di / dt) ₂ in the intermediate stage.

Therefore, it is proved that the proposed method allows to reduce the total duration of the measurement and completely solves the problem.

Claims (1)

A method for measuring the direct current resistance of windings of electrical equipment, which consists in passing a constant constant current through a winding and a reference resistor, the value of which is calculated based on a preliminary measurement of the winding resistance, measuring the voltage drop across the winding and the reference resistor, and calculating their ratio, on the basis of which the desired resistance of the winding is obtained, and during the increase in current in the winding to the calculated current, the maximum but they increase the supply voltage of the current stabilizer, and after setting the current equal to the calculated one, reduce this voltage, characterized in that by the moment of equal current in the winding to the calculated current, the rate of change of the current is set many times lower than the speed before this moment.

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