RU221918U1 - FIRE PREVENTION DEVICE DUE TO CONTACT CONNECTION FAILURES IN THE ELECTRICAL NETWORK - Google Patents

Abstract

The utility model relates to the field of monitoring the state of contact connections in a power electrical network and can be used to prevent a fire in the event of a faulty contact connection in an electrical network or electrical installation, and can be used in Smart Home systems. The device contains an indicator, an input panel, to which an electrical installation is connected through the electrical network and contact resistance, a high-voltage divider, the input of which is connected to the electrical network, and the output is connected to the input of a low-pass filter, the output of which is connected to the first amplifier, the output of the amplifier is connected to the first an analog-to-digital converter, the output of which is connected to a microcontroller, which is in communication with the first and second indicators, the first electrical installation is connected to the electrical network through the first transition resistance and the first current sensor, the second electrical installation is connected through the second transition resistance and the second current sensor to the electrical network . Due to the second amplifier connected to the second analog-to-digital converter, the output of which is connected to the microcontroller, the third amplifier connected to the third analog-to-digital converter, the output of which is connected to the microcontroller, it became possible to prevent fire due to faulty contact connections in the electrical network. The technical result of implementing the claimed solution is to identify a faulty contact connection in the electrical network when connecting two electrical installations, and to prevent a fire. 1 ill.

Description

The utility model relates to the field of monitoring the state of contact connections in a power electrical network and can be used to prevent a fire in the event of a faulty contact connection in an electrical network or electrical installation and can be used in Smart Home systems.

A known device for non-destructive testing of faults in the electrical network (RU 2656117), selected as an analogue, contains an input panel, to which an electrical installation unit for measuring the total current, a low-pass filter, an amplification unit, and a unit for comparing the magnitude of the accumulated signal are connected in series through the electrical network and transition resistance. with a given value and a fire hazard signal generation unit, to the other input of which a threshold regulator is connected, the power supply is connected to a total current measurement unit, an amplification unit, a fire hazard signal generation unit, and a threshold regulator.

The disadvantage of this method is the impossibility of localizing high transient resistance in protected circuits in non-sparking mode in the presence of two or more electrical installations.

A known device for non-destructive testing of faults in the electrical network (RU 2762125), selected as a prototype, contains an indicator, an input panel to which an electrical installation is connected through the electrical network and a transition resistance, a high-voltage divider, the input of which is connected to the electrical network, and the output is connected to the input low-pass filter, the output of which is connected to the amplifier, the output of the amplifier is connected to an analog-to-digital converter, the output of which is connected to a microcontroller, which is connected to the first and second indicators, the first electrical installation is connected to the electrical network through the first contact resistance and the first current sensor, output the first current sensor is connected to the input of the first amplifier-limiter, the output of which is connected to the microcontroller, the second electrical installation is connected through the second transition resistance and the second current sensor to the electrical network, the output of the second current sensor is connected to the second amplifier-limiter, the output of which is connected to the microcontroller.

The disadvantage of this device is the inability to detect contact connection faults in the electrical network when connecting a load with a current consumption less than the rated one.

The technical result of the claimed utility model is to detect a faulty contact connection in the electrical network when connecting two electrical installations and to prevent a fire.

The proposed fire prevention device due to faulty contact connections in the electrical network, containing an indicator, an input panel to which an electrical installation is connected through the electrical network and contact resistance, a high-voltage divider, the input of which is connected to the electrical network, and the output is connected to the input of the low-pass filter , the output of which is connected to the first amplifier, the output of the amplifier is connected to the first analog-to-digital converter, the output of which is connected to the microcontroller, which is connected to the first and second indicators, the first electrical installation is connected to the electrical network through the first contact resistance and the first current sensor, the second electrical installation , connected through the second transition resistance and the second current sensor to the electrical network.

The device contains a second amplifier connected to a second analog-to-digital converter, the output of which is connected to a microcontroller, a third amplifier connected to a third analog-to-digital converter, the output of which is connected to the microcontroller.

Due to the second amplifier connected to the second analog-to-digital converter, the output of which is connected to the microcontroller, the third amplifier connected to the third analog-to-digital converter, the output of which is connected to the microcontroller, it became possible to prevent fire due to faulty contact connections in the electrical network.

When current flows through the transition resistance of the contact, heat will be released on it and, according to the Seebeck effect, thermoEMF will appear in the form of a constant voltage, the value of which is directly proportional to the temperature difference of the conductor contacts:

,

where T ₂ and T ₁ are the temperatures of the hot and cold contacts, respectively; S ₁ and S ₂ are the Seebeck coefficients for the first and second material, respectively, α is the thermoEMF coefficient of the contact pair, ΔT is the temperature difference.

The power released at the contact connection can be determined from the current and resistance:

P=I ² R (2)

From the Joule-Lenz law we can calculate the heat generated:

dQ=P⋅dt=I ² ⋅R⋅dt (3)

where dQ is the amount of heat; I is the effective value of the current through the conductor; R – contact resistance; t – current flow time.

Part of this heat heats the contact resistance, which leads to an increase in its temperature, and the remaining part is removed due to heat transfer. The heat used to heat the contact resistance can be determined from the expression:

dQ₁=m⋅c⋅ΔT (4)

where m is the contact weight; c is the specific heat capacity of the contact material.

The heat dissipated by the contact during the time dt is determined from the formula:

dQ ₂ =K⋅S⋅ΔT⋅dt (5)

where K is the general heat transfer coefficient, taking into account all its types; S – contact cooling surface.

The heat balance equation has the form:

dQ=dQ ₁ +dQ ₂ (6)

Taking into account (3), (4) and (5), the heat balance equation will take the form:

I ² ⋅R⋅dt=m⋅c⋅ΔT+K⋅S⋅ΔT⋅dt (7)

From here the contact resistance is found:

The resulting R value is used to calculate the temperature change at rated current through the contact resistance:

The obtained value ΔT is used to calculate thermoEMF in accordance with formula (1), which is compared with the specified value adopted for the corresponding degree of fire hazard of the electrical network and, if necessary, a warning signal is generated about the occurrence of a fire hazardous situation.

In fig. Figure 1 shows a diagram of the proposed device.

Table 1 shows the results of monitoring thermoEMF and generating a fire hazard signal.

The fire prevention device due to faulty contact connections in the electrical network (Fig. 1) contains an input panel 1, to which the first electrical installation 5 (EU) is connected through the electrical network 2, the first contact connection 3 and the first current sensor 4 (DT1). and also through the second contact connection 6 and the second current sensor 7 (DT2), the second electrical installation 8 (EU) is connected. A high-voltage divider 9, a low-pass filter 10 (LPF), a first amplifier 11, a first analog-to-digital converter 12 (ADC 1), a microcontroller 13 (MK), to which the first 14 and second 15 indicators are connected, are connected in series to the electrical network 2. The first current sensor 4 (DT1) is connected to the microcontroller 13 (MK) through the second amplifier 16 and the second analog-to-digital converter 17 (ADC 2), the second current sensor 7 (DT2) is connected to the microcontroller 13 (MK) through the third amplifier 18 and the third analog-to-digital converter 19 (ADC 3).

Contact connections 3 and 6 are made on standard sockets, for example, Legrand model Cariva 773659 with a maximum current of 16 A, the first and second current sensors 4 and 7 are made on standard Hall sensors, for example, Allegro model ACS758LCB-100B. The high-voltage divider 9 is made on 10 MLT 2 resistors. Low frequency filter 10 (LPF) and amplifiers 11, 16 and 18 are made on an operational amplifier, for example K140UD6. Analog-to-digital converters 12 (ADC 1), 17 (ADC 2), and 19 (ADC 3) are made on a standard K572PV3 ADC chip. Microcontroller 13 standard, for example, ARDUINO. Indicators 14 and 15 are made on two LEDs, for example AL307.

The proposed device was used to monitor the malfunction of the contact connection of an electric stove and a table lamp with the electrical network.

Control procedure. The first electrical installation 5 (1.8 kW electric stove) was connected to the electrical network 2 with a voltage of 220 volts 50Hz through the first contact connection 3 and the first current sensor 4 (DT1). Through the second contact connection 6 and the second current sensor 7 (DT2), a second electrical installation 8 (EU2) was connected, which was used as a 95 W table lamp.

First, the first electrical installation 5 was connected to the electrical network 2. At the output of the first current sensor 4 (DT 1), a signal appeared, which, through the second amplifier 16 and the second analog-to-digital converter 17 (ADC 2), was digitally sent to the microcontroller 13 (MK). At the same time, the thermoEMF was measured and recalculated to a current of 16 A. To increase the thermoEMF of the first contact connection (which is equivalent to an increase in contact resistance), the first contact connection was placed in a heat chamber and heated to a temperature of 100±5°C. At the output of the first current sensor 4 (DT 1), a signal appeared, which entered through the second amplifier 16 and the second analog-to-digital converter 17 (ADC 2) in digital form to the microcontroller 13 (MK). At the same time, thermoEMF was measured and recalculated to a current of 16 A. Then the first electrical installation 5 was turned off.

The thermoEMF measurement results are shown in Table 1, from which it can be seen that when the thermoEMF signal exceeded 0.5 V, microcontroller 13 issued a fire hazard signal to the first indicator 14.

Then the second electrical installation 8 was connected to the electrical network 2. At the output of the second current sensor 7 (DT 1), a signal appeared, which was sent through the third amplifier 18 and the third analog-to-digital converter 19 (ADC 3) in digital form to the microcontroller 13 (MK). At the same time, thermoEMF was measured and recalculated to a current of 16 A. To increase the thermoEMF of the second contact connection (which is equivalent to an increase in contact resistance), the second contact connection was placed in a heat chamber and heated to a temperature of 100±5°C. At the output of the second current sensor 4 (DT 1), a signal appeared, which entered through the third amplifier 18 and the third analog-to-digital converter 19 (ADC 3) in digital form to the microcontroller 13 (MK). At the same time, thermoEMF was measured and recalculated to a current of 16 A. Then the second electrical installation 8 was turned off.

The thermoEMF measurement results are shown in Table 1, from which it can be seen that when the thermoEMF signal exceeded 0.2 V, microcontroller 13 issued a fire hazard signal to indicator 14.

Consequently, the use of the inventive device makes it possible to detect a faulty contact connection in the electrical network when connecting two electrical installations and prevent a fire.

Table 1.

First contact connection Second contact connection Signal
fire hazard Temperature С° ThermoEMF, mV Recalculated thermoEMF, mV Temperature С° ThermoEMF, mV Recalculated thermoEMF, mV indoor 24±
0.01 42±0.02 The first indicator is no 100±5 120±4 244±9 First indicator - yes indoor 0.125±0.005 34±0.3 Second indicator - no 60±5 0.921±0.3 268±5 Second indicator - yes

Claims (1)

A device for preventing fire due to faulty contact connections in the electrical network, containing an indicator, an input panel to which the electrical installation is connected through the electrical network and the contact resistance, a high-voltage divider, the input of which is connected to the electrical network, and the output is connected to the input of the low-pass filter, the output of which is connected to the first amplifier, the output of the amplifier is connected to the first analog-to-digital converter, the output of which is connected to the microcontroller, which is connected to the first and second indicators, the first electrical installation is connected to the electrical network through the first transition resistance and the first current sensor, the second electrical installation, connected through a second transition resistance and a second current sensor to the electrical network, characterized in that the device contains a second amplifier connected to a second analog-to-digital converter, the output of which is connected to the microcontroller, a third amplifier connected to a third analog-to-digital converter, the output of which is connected to the microcontroller.