RU2175138C1 - Method and device for measuring power circuit insulation resistance in live electrical equipment of vehicles - Google Patents

Abstract

FIELD: instrumentation engineering for electric- traction vehicles. SUBSTANCE: for measuring insulation resistance of any pole of power circuit to ground measuring voltage is applied to power circuit through series resistor inserted between ground and non-checked pole of power circuit. The latter pole is placed at measuring-voltage potential of same polarity as that of operating voltage across pole under check. Transient process is ceased at no voltage across insulation resistance of non-checked pole by adjusting voltage between the latter and ground. Source current and voltage across pole under check are measured and insulation resistance of power circuit pole under check relative to ground is calculated; to this end measured voltage is divided by measured current. Insulation resistance measuring device has measuring voltage source, limiting resistor, indicator, metering circuit shaper, microprocessor unit, two voltage sensors, and two current sensors. Proposed method provides for more comprehensive diagnostics of power mains and for continuous in-service measurements of insulation resistance. EFFECT: enhanced reliability, speed of response, fire and electric safety. 2 cl, 3 dwg

Description

 The invention relates to a control and measurement technique for electrical installations of vehicles, designed to improve the reliability and safety of generation, conversion and consumption of electricity.

 More specifically, this method and device for continuous measurement of parameters and monitoring the operability of electrical insulation relate to techniques for improving the fire and electrical safety of power circuits for generating, converting and consuming electric energy, for example, DC power circuits of transport electrical installations of high-speed and suburban electric trains, trams, subway trains, electrical installations of sea ships and ships and so on.

 There is a method of increasing fire safety of systems for generating and converting electricity by evaluating leakage currents in AC power circuits with a grounded neutral. The method is based on highlighting the difference between the input and output currents of the load at the power board. The difference in these currents is used to judge the level of fire safety, evaluating the possibility of an electric arc between the current-carrying conductors of the cable and the ground (case). The leakage currents also judge the electrical safety of the operating personnel and provide protection for leakage currents above 10 mA. An example is a residual current device type UZO-20, TU 16-92 IZHTSh. 656111.085 TU, the city of Stavropol, the "Signal" railway station - an analogue.

 A known system for increasing fire and electrical safety, containing a zero-sequence current sensor, a device for measuring the current value and an actuator for disconnecting a dangerous section of an electrical installation. The sensor is made in the form of a toroidal core, inside of which there are phase and zero conductors of the alternating current circuit. The sensor is installed near the switchboard [Pavlov V.N. and others. "Ensuring safety when using hand-held electrified tools at various stages of vessel construction", abstract of the VI International Scientific and Technical Conference, April 1998 - analogue].

 A disadvantage of the known method and system is the need for a return conductor of equal cross section inside the toroidal sensor. Another disadvantage is determined by the need to isolate a weak useful signal with an accuracy of fractions of milliamps against the background of a working current of hundreds to thousands of amperes, for example, in shipboard systems for generating and distributing electricity, which is a rather complicated task.

 A known method of measuring the insulation resistance of DC networks relative to the housing (ground), which consists in the use of an additional source of constant measuring voltage, and to eliminate the influence of the operating voltage of the monitored network before measuring compensate for the network voltage relative to the housing by introducing an adjustable constant voltage source, then turn on the source measuring voltage and counting the readings of the measuring device [Auth. testimonial. USSR, N 369515, publ. 11/08/1973, BI N 10, analogue].

 The disadvantage of this method is the need for 2 DC sources: compensating and measuring. In vehicle power networks, for example, traction electrical installations at voltages up to 3000 V, under alternating loads of up to 700 A, variable terrain, when energy can return to the network when braking on descents (generation mode), it is structurally and technologically impossible to guarantee compensation in conditions of the changing voltage of the control object.

 A known system for automatically measuring the insulation resistance of ship electrical networks, comprising a control unit to which a measuring voltage source is connected, a voltage comparison unit, one input and one output of which are connected to the control unit, the second input to the hull, and the second output to the input of the unit compensation control, and a compensation unit connected to the output of the compensation control unit, and the second input of the compensation control unit and the output of the measuring body are connected to the control unit, and the input of the control unit is with the input terminal of the device, in addition, a DC voltage isolation unit is inserted into it, the input of which is connected to the system input terminal, and the output is connected to the control unit, and the DC component of the measurement current connected between the control unit and the measurement body, and the output of the compensation unit is connected to the phases of the controlled network [Aut. testimonial. N 773527, published 23.10.80g. , BI N 39, analogue]. The disadvantage is the limited information content of the system, due to the ability to measure parameters only common to the network - the equivalent insulation resistance. Other disadvantages of this system are structural complexity, the impossibility of continuous continuous monitoring of the insulation resistance of the network during the movement of electric vehicles.

A known method of measuring the insulation resistance of electrical networks with static converters and a device for its implementation. The method is based on superimposing alternating polarity of the measured DC voltage on the controlled network and measuring, at the end of the transient process in the controlled network, the constant current component in the measuring constant voltage source circuit and calculating the value of insulation resistance. At the same time, the transient in the controlled network is stopped, without waiting for its end, after which the constant component of the voltage at the insulation impedance and the specified current are measured, and the value of the insulation resistance is calculated by the formula
R _of = K (U ₂ -U ₁ ) / (I ₁ -I ₂ ),
where R _of is the equivalent insulation resistance;
K is the coefficient of proportionality, taking into account the operating ranges of measuring the value of insulation resistance;
U ₁ and U ₂ - the magnitude of the voltage between the phase (pole) and the housing of the monitored network, measured in the first and third clock cycles of the device, respectively;
I ₁ and I ₂ - the magnitude of the currents of the measuring circuit, measured in the second and fourth clock cycles of the device, respectively. (RF patent G 01 R 27/18 RU 2028634 -prototype).

The disadvantages of this method and device are insufficient information content, low speed, high probability of methodological error, the dependence of the measurement result on changes in the operating voltage of the control object. This is due, in particular, to the fact that:
-measurement of insulation resistance contains four working cycles. Moreover, a possible change in the parameters of the control object during the entire four-cycle measurement cycle leads to the possibility of the appearance of a methodological measurement error;
- the multi-cycle measurement process does not allow to quickly take into account the change in the parameters of the control object, for example, a change in the mains operating voltage, and also complicates the design, increases the cost of the measuring tool, and makes it impossible to continuously monitor the insulation resistance of the network, which is important for vehicle electrical installations. The problem of controlling the insulation resistance of each pole separately is also not solved, which is a drawback in ensuring fire and electrical safety of power circuits of electrical installations of vehicles when they are used in a wide range of climatic zones, with large vibrations, alternating loads. The problems of the continuity of measuring the insulation resistance during operation of systems for generating, converting and distributing electricity in transport, and reducing the cost of the necessary equipment have not been solved.

 A method is proposed for measuring the insulation resistance of the power network of electrical installations of vehicles under operating voltage, in which a direct current measuring voltage is applied to the power network, the transient process of recharging capacitors in the controlled network is stopped, without waiting for it to end, the voltage across the insulation resistance and the current of the measuring voltage source are measured, differing so that when measuring the insulation resistance of any of the poles of the power network relative to the ground (housing), measure the imposed The voltage to the power network is connected through additional resistance between the ground and the uncontrolled pole of the power network, to which the potential of the measuring voltage, which coincides in sign with the sign of the operating voltage at the controlled pole, is connected, the transient is stopped at a voltage equal to zero on the insulation resistance of the uncontrolled pole by regulating the voltage between the uncontrolled pole and the ground, measure the current of the measuring source and the voltage at a controlled Yuce and calculating the insulation resistance controlled pole power network with respect to earth by dividing the measured voltage to measured current.

 Also proposed is a device for measuring the insulation resistance of the power network of electrical installations of vehicles under operating voltage, comprising a measuring voltage source, a limiting resistor and an indicator, characterized in that a measuring circuit former, a microprocessor unit, two voltage sensors and two current sensors, one input of each sensor are introduced into it voltage and each current sensor is connected to ground, the second input of one voltage sensor is connected to the positive pole of the power network, the second input of another date a voltage sensor is connected to the negative pole of the power network, the first input of the microprocessor unit is connected to the output of one voltage sensor, the second input of the microprocessor unit is connected to the output of another voltage sensor, the third input of the microprocessor unit is connected to the output of one current sensor, the fourth input of the microprocessor unit is connected to the output of another current sensor, one output of the microprocessor unit is connected to the input of the indicator, and the other output of the microprocessor unit is connected to the input of the meter shaper circuits, the second input of which is connected to the output of the measuring voltage source, and the third input is connected to the other output of the measuring voltage source through a limiting resistor, the first output of the measuring circuit driver is connected to the positive pole of the power network, the second output is connected to the negative pole of the power network, third output connected to the input of one current sensor, the fourth output is connected to the input of another current sensor.

 The proposed method for measuring the insulation resistance of the power network of electrical installations of vehicles under operating voltage provides the possibility, in contrast to the prototype, to determine separately the insulation resistance of each pole of the controlled circuit relative to the housing. This allows you to judge separately about the health of the insulation of each of the poles of the monitored network, based on the measurement of insulation resistance separately of each pole. Such a solution qualitatively improves the depth of assessment of the operability of insulation directly during the operation of the controlled network, without removing it from the operating mode of operation.

 The sign "... when measuring the insulation resistance of any of the poles of the power network relative to the ground (housing), the superimposed measuring voltage on the power network is connected through an additional resistance between the ground and the uncontrolled pole of the power network, to which the potential of the measuring voltage, which coincides with the sign sign of the operating voltage at the controlled pole, "allows you to form a measuring structure and formulate a calculation algorithm that meets the measurement requirements with disobedience isolation of any pole network and the continuity of the processes of obtaining and processing information, which excludes the methodical error of measurement.

The sign "stop the transition process at a voltage equal to zero, on the insulation resistance of the uncontrolled pole by regulating the voltage between the uncontrolled pole and the ground." This feature allows you to get:
- access to obtaining the initial data necessary for calculating the insulation resistance of the monitored pole, since with this method of connection and only at zero voltage between the uncontrolled pole and the ground, it is possible to measure the voltage and current corresponding to the measured insulation resistance;
- significantly increase the speed of measurement due to the forced stop of the process of recharging the capacitors of the power network at zero voltage without changing the polarity, which is provided in the prototype.

 The sign "measure the current of the measuring source and voltage at the controlled pole and calculate the insulation resistance of the controlled pole of the power network relative to the ground by dividing the measured voltage by the measured current" allows directly in the process of measuring voltage and current, simultaneously with the measurement, without using data obtained outside the current tact, calculate the measured insulation resistance.

 Naturally, constructive simplicity of the implementation of the method in the form of a device is achieved, which is due to the use of a minimum set of processes necessary for solving the task in the method and blocks in the device.

 Additionally, miniaturization of the proposed method and device is achieved through the use of modern methods of processing information and the formation of measurement schemes. It is these methods that allowed, when solving the problem, in addition to the necessary voltage and current sensors, to limit oneself only to the introduction of an electronic shaper of measurement circuits, which forms different circuits for measuring the insulation resistances of different poles, and also provides voltage regulation according to the commands of the microprocessor unit entered into the meter.

In addition to performing the main task - measuring the insulation resistance of each pole separately, a number of additional technical results are provided, in particular:
- improving the methodological accuracy of measuring insulation resistance;
- a significant increase in performance;
- work with voltage fluctuations of the controlled network without methodological errors;
- simplicity of design and reliability of the meter.

 Improving the methodological accuracy of measuring the insulation resistance is achieved due to the fact that when measuring the insulation resistance of any of the poles relative to the housing, the measuring voltage superimposed on the network is continuously regulated as a function of the voltage across the insulation resistance of an uncontrolled pole. In this case, directly in the process of measuring the current of the measuring voltage source and measuring the voltage at the controlled insulation resistance of the pole, the estimated parameter is calculated. In the prototype, instead of a continuous process, an intermittent measurement process is implemented, one cycle of which contains four working cycles. The insulation resistance is calculated necessarily using data not only of the current measure, as in the proposed method, but according to the data of all four last measures. It turns out that to calculate the insulation resistance in the prototype, the results of measurements performed on previous measures with a time shift are used. Therefore, it is possible to change the parameters of the controlled network during the transition from measure to measure, which inevitably leads to a methodological error. The proposed method is free from this drawback, since the voltage and current required to calculate the insulation resistance are measured simultaneously with the parameters of the controlled network being constant, at which the measurement circuit is regulated.

 A significant increase in the speed of the proposed method is determined by the following. A feature of the prototype is a change in the polarity of the measuring voltage source during the measurement process. The consequence of this is the need to pass through zero the voltage of the overcharge of the capacities of the controlled network (Fig. 2 prototype). In the proposed method, the transient is always stopped at the mains voltage at a controlled resistance of the pole insulation, which corresponds to a shorter preparation time for current and voltage measurements (Fig. 3). In addition, as already mentioned above, the prototype requires data not only of the current, but also of the previous measures of the measurement process, which increases the speed of the proposed method compared to the prototype.

 Simplicity of design and reliability are determined both by the features of the proposed method of measurement, and the approach to the implementation of the device. The features of the proposed measurement method are processes, the combination of which ensures essentially continuous measurement of the insulation resistance of the pole of the controlled network relative to the housing in static mode without switching or switching, which, when implemented, allows to save the resource of components.

 The implementation of the device based on microprocessor technology allows both to ensure miniaturization of the meter and to obtain practical trouble-free operation, since in this case the meter does not contain elements with low resource indicators.

 An important feature of the proposed measurement method is the independence of the result from the magnitude of the operating voltage of the controlled network. A wide range of operating voltage fluctuations is the norm in electrical installations of vehicles. For example, in ship DC power networks, fluctuations in the operating voltage amount to tens of percent.

 The proposed method and device meet the criterion of "novelty", as they have distinctive features from prototypes, consisting in the use in the proposed method of a set of actions for forming measurement schemes, regulating processes, measuring voltages and currents, computing results in accordance with the procedures regulated by the proposed measurement method insulation resistance of power networks of electrical installations of transport under voltage, at which a measuring voltage is applied to the power network constant current, stop the transient process of recharging capacities in a controlled network, without waiting for it to end, measure the voltage at the insulation resistance and the current of the measuring voltage source, characterized in that when measuring the insulation resistance of any of the poles of the power network relative to the ground (case), the applied measurement voltage to the power network is connected through additional resistance between the ground and the uncontrolled pole of the power network, to which the meter potential is connected voltage, coinciding in sign with the sign of the operating voltage at the controlled pole, stop the transient at a voltage equal to zero, on the insulation resistance of the uncontrolled pole by regulating the voltage between the uncontrolled pole and the ground, measure the current of the measuring source and the voltage at the controlled pole and calculate the insulation resistance controlled pole of the power network relative to the ground by dividing the measured voltage by the measured current.

 The "novelty" of the proposed device is determined by the presence of new structural elements and new connections between the elements in the proposed device for measuring the insulation resistance of power networks under voltage, containing a measuring voltage source, a limiting resistor and an indicator, characterized in that a measuring circuit former, a microprocessor unit are introduced into it, two voltage sensors and two current sensors, one input of each voltage sensor and each current sensor is connected to ground, the second input of one sensor and the voltage is connected to the positive pole of the power network, the second input of another voltage sensor is connected to the negative pole of the power network, the first input of the microprocessor unit is connected to the output of one voltage sensor, the second input of the microprocessor unit is connected to the output of another voltage sensor, the third input of the microprocessor unit is connected to the output one current sensor, the fourth input of the microprocessor unit is connected to the output of another current sensor, one output of the microprocessor unit is connected to the indicator input, and the other output of the microprocessor unit is connected to the input of the measuring circuit driver, the second input of which is connected to the output of the measuring voltage source, and the third input is connected to the other output by the measuring voltage source through a limiting resistor, the first output of the measuring circuit former is connected to the positive pole of the power network, the second output connected to the negative pole of the power network, the third output is connected to the input of one current sensor, the fourth output is connected to the input of another sensor .

 The above properties do not coincide with the properties that are the hallmarks of the known technical solutions, and is not the sum of their properties, which allows us to consider the claimed solution to meet the criterion of "significant differences".

 The essence of the proposed method is illustrated by an example of its implementation.

 In FIG. 1 shows a device for measuring the insulation resistance of a power network of electrical installations of transport.

 In FIG. 2 shows a diagram of measuring the insulation resistance of the positive pole of a power network.

 In FIG. 3 is a graph of transients of the voltage poles of the power network.

 The device for measuring the insulation resistance of the power network of electrical installations of vehicles under operating voltage contains a measuring voltage source 1, a limiting resistor 2, an indicator 3, a measuring circuit driver 4, a microprocessor unit 5, two voltage sensors 6, 7, two current sensors 8, 9, one input of each the voltage sensor and each current sensor is connected to ground, the second input of one voltage sensor 6 is connected to the positive pole of the power network, the second input of another voltage sensor 7 is connected to the negative field som of the power network, the first input of the microprocessor unit is connected to the output of one voltage sensor 6, the second to the output of another voltage sensor 7, the third to the output of one current sensor 8, the fourth to the output of another current sensor 9, one output of the microprocessor unit 5 is connected to the indicator 3, and the other output of the microprocessor unit 5 is connected to one input of the measuring circuit driver 4, the second input of which is connected to the output of the measuring voltage source 1, and the third input of the measuring circuit generator 4 is connected to another output of the measuring voltage source 1 through the limiting resistor 2, the first output of the measuring circuit driver 4 is connected to the positive pole of the power network, the second output is connected to the negative pole of the power network, the third output is connected to the input of one current sensor 8, the fourth output is connected to the input of another sensor current 9.

 The microprocessor unit (MPB) 5 of the measuring device performs the functions of controlling the measuring system, forming circuits for measuring the insulation resistance of specific poles, regulating voltage, calculating the insulation resistance and generating the calculated values of the insulation resistance. At the command of the MPB 5, the measuring circuit former (FIS) 4 collects the desired measuring circuit. An example implementation of such a circuit is shown in FIG. 2 for the case of measuring the insulation resistance of the positive pole. After the formation of the measuring circuit, the MPB 5 acts on the FIS 4 regulator so that, according to the voltage sensor 7, maintain a voltage of zero at the insulation resistance uncontrolled in this cycle. In stable voltage mode, the BCH 5 reads the voltage sensor 6 and the current sensor 8. After that, the BCH 5 divides the measured voltage by the measured current and sends the result as the insulation resistance of the positive pole to indicator 3. In this case, the solution to the main problem, that is, the resistance measurement, is obvious pole isolation. Additional tasks are also being addressed. Confirmation of the increase in speed is determined by the fact that the measurement of the insulation resistance of the pole contains only one transient, unlike the prototype. In addition, the start time of fixing (regulating) the voltage at the pole insulation resistance does not exceed the time constant of the measurement circuits, as shown in the graph (Fig. 3).

 The described procedure for measuring the insulation resistance of a pole contains a process for regulating a fixed voltage, which allows you to automatically take into account the change in the parameters of the test object not only before the measurement, but also immediately before reading the sensors. Such an algorithm allows the measurement to be carried out without a methodological error, and when implementing this method, the miniaturization and reliability of the insulation resistance monitoring device can easily be solved, which improves the fire and electrical safety conditions of power circuits of electrical installations of vehicles.

Claims (2)

 1. The method of measuring the insulation resistance of the power network of electrical installations of vehicles under operating voltage, at which a measuring DC voltage is applied to the power network, stop the transient process of recharging the capacities in the controlled network, without waiting for its end, measure the voltage on the insulation resistance and the current of the measuring voltage source, characterized in that when measuring the insulation resistance of any of the poles of the power network relative to the ground (housing) superimposed on the power network of The test voltage is connected through an additional resistance between the ground and the uncontrolled pole of the power network, to which the potential of the measuring voltage, which coincides in sign with the sign of the operating voltage at the controlled pole, is connected, the transient is stopped at a voltage equal to zero, on the insulation resistance of the uncontrolled pole by regulation voltage between the uncontrolled pole and the ground, measure the current of the measuring source and the voltage at the controlled pole and use the insulation resistance of the controlled pole of the power network relative to the ground by dividing the measured voltage by the measured current.  2. A device for measuring the insulation resistance of the power network of electrical installations of vehicles under operating voltage, containing a measuring voltage source, a limiting resistor and an indicator, characterized in that a measuring circuit driver, a microprocessor unit, two voltage sensors, two current sensors, one input of each sensor are introduced into it voltage and each current sensor is connected to ground, the second input of one voltage sensor is connected to the positive pole of the power network, the second input of another voltage sensor It is connected to the negative pole of the power network, the first input of the microprocessor unit is connected to the output of one voltage sensor, the second input to the output of another voltage sensor, the third input to the output of one current sensor, the fourth input to the output of another current sensor, one output of the microprocessor unit with an indicator input, and the other output with the first input of the measuring circuit former, the second input of which is connected to one output of the measuring voltage source, and the third input is with the other output of the measuring source voltage through the limiting resistor, the first output of the measuring circuit driver is connected to the positive pole of the power network, the second output to the negative pole of the power network, the third output to the input of one current sensor, and the fourth output to the input of another current sensor.

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