RU162140U1 - ELECTRICAL INSTALLATION PROTECTION DEVICE FOR OVERHEATING - Google Patents

Abstract

1. A device for protecting an electrical installation against overheating, comprising a current sensor, the primary winding of which has terminals for connection to the power circuit of the protected electrical installation, its secondary winding is connected to the first input of the heating-cooling model, and the ambient temperature sensor, the output of which is connected to the second input of the heating model -cooling, control signal generation unit, the input of which is connected to the first output of the heating-cooling model, the output of the control signal generation unit is connected to the control input comm utilization apparatus and an overheat indicator, characterized in that it additionally includes a temperature meter for an electrical installation point accessible for measurement, the output of which is connected to the first input of the heating-cooling model parameter correction block, the second input of the heating-cooling model parameter correction block is connected to the second output of the model heating-cooling. 2. The device for protecting the electrical installation from overheating according to claim 1, characterized in that the block for adjusting the parameters of the heating-cooling model is made up of a mismatch calculator between the calculated and measured temperature values, the two inputs of which are inputs of the block for adjusting the parameters of the heating-cooling model, the executive body, the first the input of which is connected to the output of the mismatch calculator between the calculated and measured temperature values, the second input is connected to the heating-cooling state sensor electrical installation, the output of the executive body is the output of the block adjusting the parameters of the heating-cooling model. 3. Electrical Protection Device

Description

The technical field to which the invention relates (utility model),

The utility model relates to the field of electrical engineering and the electric power industry, in particular, to means for protecting electrical installations from overheating by currents.

Characterization of analogues of the invention (utility model)

In electrical engineering, a thermal relay is widely known [1]. The basis of this relay is a thermal analogue of the protected object, the input of which gives a signal proportional to the current of the controlled object. By physical modeling of heating and cooling processes using a thermal analogue, the temperature of the electric motor is determined. The temperature value obtained in this way is compared with the established permissible value, and if it exceeds the permissible level, a signal is generated to shut down or unload the electrical installation.

The accuracy of modeling the heating and cooling processes by this thermal analog is very low, because it is very difficult to implement many similarity criteria for the electromechanical heating model and the protected object, and some are impossible.

This is mainly due to the fact that the heating and cooling time constants of the bimetallic elements of thermal relays differ significantly from the heating and cooling time constants of electrical installations.

Therefore, thermal relays are suitable for detecting only gross deviations of the state of the protected object from normal, and those accompanied by a significant increase in current.

A device is known for protecting an electrical installation from overheating based on a thermal analogue of an electrical installation, in which, in order to improve simulation accuracy, thermal processes are modeled using electrical circuits and signals [2].

But this cannot achieve a high degree of adequacy of the model and the real process due to the inability to take into account in the model the changes in the parameters of the controlled object under the influence of the environment.

Description of the prototype selected by the applicant

The closest solution in technical essence is a device in which direct and indirect methods of temperature control based on mathematical modeling of heating processes of electric machines are used together [3].

This overheat protection device of an electrical installation contains a current sensor, the primary winding of which has terminals for connection to the power circuit of the protected electrical installation, its secondary winding is connected to the first input of the heating-cooling model, the ambient temperature sensor, the output of which is connected to the second input of the heating-cooling model , a control signal generation unit, the input of which is connected to the first output of the heating-cooling model, the output of the control signal generation unit, is connected to the control input comm , Gravitational unit and display.

Prototype criticism

A disadvantage of the known device is the low accuracy of temperature determination by the heating model of the electrical installation.

This is due to the low accuracy of the parameters of the heating model. The parameters of the model are determined by many design factors and environmental conditions, which are difficult to take into account in the calculations.

Purpose of the invention (utility model)

The purpose of the proposed utility model is to increase the accuracy of thermal protection of the electrical installation by adjusting the parameters of the heating model in relation to the operating conditions of the protected electrical installation.

The invention (utility model)

This goal is achieved by the fact that in the known device for protecting the electrical installation from overheating, an additional temperature meter is available for measuring the point of the electrical installation, the output of which is connected to the first input of the block for adjusting the parameters of the heating-cooling model, the second input of the block for adjusting the parameters of the heating-cooling model is connected to the second output heating-cooling models.

At the same time, the block for adjusting the parameters of the heating-cooling model is made up of a mismatch calculator between the calculated and measured temperature values, the two inputs of which are the inputs of the block for adjusting the parameters of the heating-cooling model, the executive body, the first input of which is connected to the output of the mismatch calculator between the calculated and measured temperature values, the second input is connected to the sensor of the state of heating-cooling of the electrical installation, the output of the executive body is the output adjusting the model parameters block heating-cooling.

Moreover, the executive body is made in the form of a reversible regulator of a proportional type.

List of figures of graphic images

In FIG. 1 is a structural diagram of a device for protecting an electrical installation from overheating.

The circuit contains: a controlled electrical installation (electric motor), which is connected to the mains through a cable line, a current sensor (current transformer) and a switching device (switch), a heating-cooling model, a block for adjusting the parameters of the heating-cooling model, an ambient temperature sensor, and a meter temperature available for measuring the point of the electrical installation, signal generation unit.

In FIG. Figure 2 shows a diagram of the change in the heating temperature of an electrical installation obtained by indirect and direct measurement.

Case Studies

The proposed device for protecting an electrical installation from overheating can be implemented, for example, as applied to an induction motor as follows.

Losses that inevitably occur in any electrical installation (for example, an electric motor, transformer, reactor, resistor, etc.) during operation are converted into heat. Consequently, the machine heats up relative to the environment. And the most vulnerable element - insulation, is located in close proximity to the heat source - the conductor of the winding.

Losses are in a complex relationship and depend on many factors. Therefore, a rigorous solution to the problem of indirectly determining the temperature of the winding or current-carrying part is very difficult to obtain, and in most cases impossible. In this regard, in order to obtain results with accuracy acceptable for relay protection, simplifications and assumptions are used.

Since the losses in the steel of an asynchronous machine are determined mainly by the level of the supply voltage and are little dependent on the operating mode of the motor, they can be considered a constant value. Losses due to friction and other losses in most cases are much less than losses in the windings of a machine. Therefore, they can also be neglected.

Considering also a number of other assumptions correct for relay protection, heating of an electric machine is represented by the heat balance equation:

ΔPdt = αFTdt + cGdT,

where ΔР is the active power released in the winding; α is the heat transfer coefficient; F is the surface area of the winding; T - excess temperature of the winding over the ambient temperature; C is the specific heat of the winding; G is the mass of the winding.

The first term on the right side of the equation determines the energy diverted from the winding through its surface. The second term is thermal energy, which is spent on changing the temperature of the winding.

The energy released in the winding during the time dt is determined by the electric losses in it:

,

,

where I ₁ is the current in the stator winding; r is the active resistance of the winding.

The solution to this equation has the form:

.Here T _NACH and T _U - the initial and steady-state values of the temperature rise of the winding; τ = cG / αF is the winding heating time constant; steady temperature

.

Thus, the heating curve of the winding is an exponential, the beginning of which corresponds to the initial excess of the temperature of the winding T _NCH over the ambient temperature.

The absolute temperature of the winding (T _ABS ) is the sum of the excess of the temperature of the winding over the ambient temperature (T) and the ambient temperature (T _OCD ):

T _ABS = T + T _OCD .

Using sensors, it is not possible to directly measure the temperature of the winding and the insulation layers adjacent to the winding conductors because of the need to provide electrical insulation for these sensors and winding conductors. In this regard, the temperature is measured using meters (sensors) at other points (for example, on the surface of the housing), where it is possible to measure temperature using sensors, but which are separated from the winding conductor by some thermal resistance (thermal insulation).

The heating-cooling model of the electric motor is constructed with two outputs in such a way that the temperature value on the surface of the electric motor (at the sensor installation site) and the temperature of the winding conductor are calculated.

The accuracy of the heating-cooling model is largely determined by the heating time constant. It, in turn, depends on parameters that are difficult to determine by calculation and which can change during the operation of the electric motor. Correction (change) of the time constant to deviate the calculated temperature from the actual temperature on the surface of the electric motor allows you to bring the processes in the model closer to the real processes of heating the electric motor.

At certain points in time (t1, t2, etc.), the temperature is measured at a certain point of the electric motor and the temperature is calculated at the same point with the initial value of the heating time constant. Compare the obtained values (Fig. 2). If during heating the mismatch between the calculated and measured temperature values is positive (the calculated temperature is greater than the measured one), then in the heating-cooling model the heating time constant of the electrical installation is increased, and the heating process in the model is slower (temperature increments become smaller). If the mismatch is negative (the calculated temperature is less than the measured one), then in the heating-cooling model the heating time constant is reduced, and then the heating process in the model is faster (the temperature increments per unit time become larger). Thus, the heating curve of the model approaches the real heating curve of the electrical installation.

An additional contact of the switching apparatus can be used as a sensor for the state of heating and cooling of the electrical installation. For example, when the switch is turned on and the auxiliary contact is closed, the electrical installation is being heated. When the switch is open and the auxiliary contact is open, the cooling process is in progress.

During cooling, if the mismatch between the calculated and measured temperature values is positive (the calculated temperature is greater than the measured one), then in the heating-cooling model the cooling time constant of the electrical installation is reduced, if the mismatch is negative (the calculated temperature is less than the measured one), then in the heating-cooling model the cooling time constant is increased . Thus, the cooling curve of the model approaches the real cooling curve of the electrical installation.

Moreover, the time constant of heating the electrical installation during adjustment is changed using the executive body of the block adjusting the parameters of the heating-cooling model in proportion to the mismatch, the larger the mismatch, the more the heating time constant is changed.

Thus, over time, for some value of the heating time constant, the heating or cooling processes in the model and in the real object coincide (with a certain error).

Together with calculating the temperature at the control point where the temperature is measured using the current value of the heating time constant, the temperature of the winding conductors and the adjacent insulation layers in the heating-cooling model is calculated. If the calculated temperature of the winding has exceeded the permissible value, then the corresponding information signal and a signal to disable or unload the protected object are formed.

Feasibility or other effectiveness of the invention (utility model)

By adjusting the parameters of the heating-cooling model according to the difference between the calculated and measured temperatures, an increase in the degree of adequacy of the model and the real process is achieved. In turn, increasing the accuracy of the model increases the accuracy of calculating the temperature of the winding and adjacent layers of insulation. This increases the accuracy of the protection against overheating in general, and allows, on the one hand, more fully use the overload capabilities of protected objects, and, on the other hand, prevent their excessive overheating and subsequent damage.

Information sources:

1. Rodstein L.A. Electrical apparatus. - L .: Energoatomizdat. Leningra. Otdel, 1989 .-- 304 p.

2. Thermal analogue of an electric motor // Dudnik MZ and other USSR author's certificate No. 1001294 Н02Н 7/085, published in BI No: 8 02/28/83.

3. Device for protecting the electric motor from overheating // Bulychev A.V., Tretyakov V.L. USSR copyright certificate No. 1374325 H02H 5/04, 7/085, published in BI No. 6.02.02.

Claims (3)

1. A device for protecting an electrical installation against overheating, comprising a current sensor, the primary winding of which has terminals for connection to the power circuit of the protected electrical installation, its secondary winding is connected to the first input of the heating-cooling model, and the ambient temperature sensor, the output of which is connected to the second input of the heating model -cooling, control signal generation unit, the input of which is connected to the first output of the heating-cooling model, the output of the control signal generation unit is connected to the control input comm utilization apparatus and an overheat indicator, characterized in that it additionally includes a temperature meter for an electrical installation point accessible for measurement, the output of which is connected to the first input of the heating-cooling model parameter correction block, the second input of the heating-cooling model parameter correction block is connected to the second output of the model heating-cooling. 2. The device for protecting the electrical installation from overheating according to claim 1, characterized in that the block for adjusting the parameters of the heating-cooling model is made up of a mismatch calculator between the calculated and measured temperature values, two inputs of which are inputs of the block for adjusting the parameters of the heating-cooling model, of the executive body the first input of which is connected to the output of the mismatch calculator between the calculated and measured values of temperature, the second input is connected to the sensor of the state of the heating-core anija electrical, executive output is the output correction unit heating-cooling of the model parameters. 3. The device protects the electrical installation from overheating according to claim 2, characterized in that the executive body is made in the form of a reversible proportional type regulator.

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